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R E V I E W D R A F T C I S C O C O N F I D E N T I A L Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide November 2019 Americas Headquarters Cisco Systems, Inc. 170 West Tasman Drive San Jose, CA 95134-1706 USA http://www.cisco.com Tel: 408 526-4000 800 553-NETS (6387) Fax: 408 527-0883 THE SPECIFICATIONS AND INFORMATION REGARDING THE PRODUCTS IN THIS MANUAL ARE SUBJECT TO CHANGE WITHOUT NOTICE. ALL STATEMENTS, INFORMATION, AND RECOMMENDATIONS IN THIS MANUAL ARE BELIEVED TO BE ACCURATE BUT ARE PRESENTED WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED. USERS MUST TAKE FULL RESPONSIBILITY FOR THEIR APPLICATION OF ANY PRODUCTS. THE SOFTWARE LICENSE AND LIMITED WARRANTY FOR THE ACCOMPANYING PRODUCT ARE SET FORTH IN THE INFORMATION PACKET THAT SHIPPED WITH THE PRODUCT AND ARE INCORPORATED HEREIN BY THIS REFERENCE. IF YOU ARE UNABLE TO LOCATE THE SOFTWARE LICENSE OR LIMITED WARRANTY, CONTACT YOUR CISCO REPRESENTATIVE FOR A COPY. The following information is for FCC compliance of Class A devices: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of the FCC rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio-frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference, in which case users will be required to correct the interference at their own expense. The following information is for FCC compliance of Class B devices: This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of the FCC rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If the equipment causes interference to radio or television reception, which can be determined by turning the equipment off and on, users are encouraged to try to correct the interference by using one or more of the following measures:
Reorient or relocate the receiving antenna. Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. Consult the dealer or an experienced radio/TV technician for help. Modifications to this product not authorized by Cisco could void the FCC approval and negate your authority to operate the product. Increase the separation between the equipment and receiver. The Cisco implementation of TCP header compression is an adaptation of a program developed by the University of California, Berkeley (UCB) as part of UCBs public domain version of the UNIX operating system. All rights reserved. Copyright 1981, Regents of the University of California. NOTWITHSTANDING ANY OTHER WARRANTY HEREIN, ALL DOCUMENT FILES AND SOFTWARE OF THESE SUPPLIERS ARE PROVIDED AS IS WITH ALL FAULTS. CISCO AND THE ABOVE-NAMED SUPPLIERS DISCLAIM ALL WARRANTIES, EXPRESSED OR IMPLIED, INCLUDING, WITHOUT LIMITATION, THOSE OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT OR ARISING FROM A COURSE OF DEALING, USAGE, OR TRADE PRACTICE. IN NO EVENT SHALL CISCO OR ITS SUPPLIERS BE LIABLE FOR ANY INDIRECT, SPECIAL, CONSEQUENTIAL, OR INCIDENTAL DAMAGES, INCLUDING, WITHOUT LIMITATION, LOST PROFITS OR LOSS OR DAMAGE TO DATA ARISING OUT OF THE USE OR INABILITY TO USE THIS MANUAL, EVEN IF CISCO OR ITS SUPPLIERS HAVE BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. CCDE, CCENT, Cisco Eos, Cisco HealthPresence, the Cisco logo, Cisco Lumin, Cisco Nexus, Cisco StadiumVision, Cisco TelePresence, Cisco WebEx, DCE, and Welcome to the Human Network are trademarks; Changing the Way We Work, Live, Play, and Learn and Cisco Store are service marks; and Access Registrar, Aironet, AsyncOS, Bringing the Meeting To You, Catalyst, CCDA, CCDP, CCIE, CCIP, CCNA, CCNP, CCSP, CCVP, Cisco, the Cisco Certified Internetwork Expert logo, Cisco IOS, Cisco Press, Cisco Systems, Cisco Systems Capital, the Cisco Systems logo, Cisco Unity, Collaboration Without Limitation, EtherFast, EtherSwitch, Event Center, Fast Step, Follow Me Browsing, FormShare, GigaDrive, HomeLink, Internet Quotient, IOS, iPhone, iQuick Study, IronPort, the IronPort logo, LightStream, Linksys, MediaTone, MeetingPlace, MeetingPlace Chime Sound, MGX, Networkers, Networking Academy, Network Registrar, PCNow, PIX, PowerPanels, ProConnect, ScriptShare, SenderBase, SMARTnet, Spectrum Expert, StackWise, The Fastest Way to Increase Your Internet Quotient, TransPath, WebEx, and the WebEx logo are registered trademarks of Cisco Systems, Inc. and/or its affiliates in the United States and certain other countries. All other trademarks mentioned in this document or website are the property of their respective owners. The use of the word partner does not imply a partnership relationship between Cisco and any other company. (0812R) Any Internet Protocol (IP) addresses and phone numbers used in this document are not intended to be actual addresses and phone numbers. Any examples, command display output, network topology diagrams, and other figures included in the document are shown for illustrative purposes only. Any use of actual IP addresses or phone numbers in illustrative content is unintentional and coincidental. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2019 Cisco Systems, Inc. All rights reserved. C O N T E N T S Preface 1 Objectives 1 Audience 1 Conventions 1 Related Documents 2 Finding the Product Serial Number 3 C H A P T E R 1 Overview 1-1 About the Access Point 1-1 Hardware Models 1-2 Hardware Features 1-4 Connectors 1-4 IW-6300H Access Point Internal Connectors 1-4 Console Port and Reset Button 1-5 Power Connector 1-5 Antenna Ports 1-7 Power Sources 1-8 Power Injectors 1-8 Ethernet (PoE) Ports 1-9 Fiber Option 1-9 1/2-NPT I/O Ports 1-9 Optional Hardware 1-11 C H A P T E R 2 Before You Begin 2-1 Unpacking the Access Point 2-1 Package Contents 2-1 Tools and Hardware 2-2 Optional Tools and Hardware 2-2 Optional Tools and Hardware That You Supply 2-2 Pole Installation Hardware and Tools 2-3 Warnings 2-3 Safety Information 2-3 FCC Safety Compliance Statement 2-4 Safety Precautions 2-4 Cisco Industrial Wireless 6300 Series Access Point Hardware Installation Guide 1 Contents Avoiding Damage to Radios in a Testing Environment 2-5 Safety Precautions When Installing Antennas 2-6 Installation Guidelines 2-7 Site Surveys 2-7 Before Beginning the Installation 2-8 C H A P T E R 3 Installing the Access Points 3-1 Mounting on a Wall or a Pole 3-1 Installation Option 3-1 Access Point Mounting Orientation 3-2 Mounting the Access Point on a Wall 3-3 Mounting the Access Point on a Pole 3-6 Assembling the Pole Clamp Bracket and the Mounting Bracket 3-6 Pole Mounting 3-8 Working with the Access Cover 3-14 Opening the Access Cover 3-14 Closing the Access Cover 3-15 Installing External Antennas 3-15 Non-Cisco Antennas 3-16 Grounding the Access Point 3-16 Using the Reset Button 3-18 Powering the Access Point 3-18 Connecting a Power Injector 3-19 Connecting an Ethernet Cable to the Access Point 3-20 Connecting AC Power to IW-6300H-AC-X-K9 3-21 Connecting DC Power to IW-6300H-DCW-X-K9 3-22 Connecting DC Power to IW-6300H-DC-X-K9 3-23 Performing Maintenance 3-25 Removing the Access Point from Service 3-25 Conducting Periodic Inspections 3-25 Conducting Periodic Cleaning 3-25 What to Do Next 3-25 C H A P T E R 4 Troubleshooting 4-1 Guidelines for Using the Access Points 4-1 Important Notes 4-2 Convergence Delays 4-2 Bridge Loop 4-2 Cisco Industrial Wireless 6300 Series Access Point Hardware Installation Guide 2 Contents Controller DHCP Server 4-2 MAP Data Traffic 4-3 Controller MAC Filter List 4-3 Accessing the Console Port and the Reset Button 4-3 Resetting the Access Point 4-4 Monitoring the Access Point LEDs 4-4 Verifying Controller Association 4-6 Changing the Bridge Group Name 4-7 A P P E N D I X A Declarations of Conformity and Regulatory Information A-1 Manufacturers Federal Communication Commission Declaration of Conformity Statement A-2 Industry Canada A-3 Canadian Compliance Statement A-3 Declaration of Conformity for RF Exposure A-3 European Community, Switzerland, Norway, Iceland, and Liechtenstein A-4 Declaration of Conformity with regard to the R&TTE Directive 1999/5/EC & Medical Directive 93/42/EEC A-4 Declaration of Conformity for RF Exposure A-5 United States A-5 Canada A-5 European Union A-5 Australia A-5 Guidelines for Operating Cisco Aironet Access Points in Japan A-6 Japanese Translation A-6 English Translation A-6 Japanese Translation A-7 English Translation A-7 VCCI Statement for Japan A-7 Administrative Rules for Cisco Aironet Access Points in Taiwan A-8 Chinese Translation A-8 English Translation A-9 Chinese Translation A-9 English Translation A-9 Taiwan NCC Statement A-10 English Translation A-10 Chinese Translation A-10 English Translation A-10 Chinese Translation A-10 Cisco Industrial Wireless 6300 Series Access Point Hardware Installation Guide 3 Contents EU Declaration of Conformity A-10 A P P E N D I X B Access Point Specifications B-1 A P P E N D I X C Access Point Pinouts C-1 Cisco Industrial Wireless 6300 Series Access Point Hardware Installation Guide 4 R E V I E W D R A F T C I S C O C O N F I D E N T I A L Preface This section describes the objectives, audience, organization, and conventions of the Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide. This publication explains the steps for installing the Cisco Catalyst IW6300 Heavy Duty Series Access Point (called the access point or AP in this document). Objectives Audience This publication is for the person installing and configuring an access point for the first time. The installer should be familiar with network structures, terms, and concepts. For installations in a hazardous locations environment, please refer to Getting Started and Product Document of Compliance for the Cisco Catalyst IW6300 Heavy Duty Series Access Points for additional installation information. Warning Only trained and qualified personnel should be allowed to install, replace, or service this equipment. Statement 1030 Conventions This publication uses the following conventions:
Convention boldface font italic font
[ ]
screen font boldface screen font Description Commands, command options, and keywords are in boldface. Arguments for which you supply values are in italics. Elements in square brackets are optional. Terminal sessions and information the system displays are in screen font. Information you must enter is in boldface screen font. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1 R E V I E W D R A F T C I S C O C O N F I D E N T I A L Convention italic screen font
^
< >
Description Arguments for which you supply values are in italic screen font. The symbol ^ represents the key labeled Control. For example, the key combination ^D in a screen display means hold down the Control key while you press the D key. Nonprinting characters, such as passwords, are in angle brackets. Notes use the following conventions:
Note Means reader take note. Notes contain helpful suggestions or references to materials not contained in this manual. Cautions use the following conventions:
Caution Means reader be careful. In this situation, you might do something that could result in equipment damage or loss of data. Warnings use the following conventions:
Warning IMPORTANT SAFETY INSTRUCTIONS This warning symbol means danger. You are in a situation that could cause bodily injury. Before you work on any equipment, be aware of the hazards involved with electrical circuitry and be familiar with standard practices for preventing accidents. Use the statement number provided at the end of each warning to locate its translation in the translated safety warnings that accompanied this device. Statement 1071 SAVE THESE INSTRUCTIONS Related Documents To view all support information for the Cisco Catalyst IW6300 Heavy Duty Series Access Point, see:
https://www.cisco.com/c/en/us/products/wireless/industrial-wireless/index.html In addition to the documentation available on the support page, you will need to refer to the following guides:
Cisco Wireless LAN Controller Configuration Guide http://www.cisco.com/c/en/us/support/wireless/wireless-lan-controller-software/products-installati on-and-configuration-guides-list.html
Release Notes for Cisco Wireless LAN Controllers and Lightweight Access Points http://www.cisco.com/c/en/us/support/wireless/wireless-lan-controller-software/products-release-n otes-list.html
Cisco Mobility Express Configuration and User Guide Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2 R E V I E W D R A F T C I S C O C O N F I D E N T I A L http://www.cisco.com/c/en/us/support/wireless/mobility-express/products-installation-and-configu ration-guides-list.html
DHCP OPTION 43 for Lightweight Cisco Aironet Access Points Configuration Example http://www.cisco.com/c/en/us/support/docs/wireless-mobility/wireless-lan-wlan/97066-dhcp-optio n-43-00.html Click this link to browse to the Cisco Wireless documentation home page:
http://www.cisco.com/en/US/products/hw/wireless/index.html To browse to the access point documentation, click Cisco Catalyst IW6300 Heavy Duty Series Access Point listed under Outdoor and Industrial Wireless. The documentation can be accessed from the Support box. To browse to the Cisco Wireless LAN Controller documentation, click Standalone Controllers listed under Wireless LAN Controllers. The documentation can be accessed from the Support box. Finding the Product Serial Number The access point serial number is on the side of the access point. The access point serial number label contains the following information:
Serial number, such as WCN0636279B (11 alphanumeric digits).
Access point MAC address, for example 68BDABF54600 (12 hexadecimal digits). It is located under the serial number. You need your product serial number when requesting support from the Cisco Technical Assistance Center. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3 R E V I E W D R A F T C I S C O C O N F I D E N T I A L Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4 R E V I E W D R A F T C I S C O C O N F I D E N T I A L C H A P T E R 1 Overview The Cisco Catalyst IW6300 Heavy Duty Series Access Point (hereafter called the access point or AP) is a wireless outdoor access point which is designed for use in a variety of network configurations. The access point supports wireless client access, bridging, and mesh wireless connectivity. About the Access Point The detailed up-to-date technical specifications for the Cisco Catalyst IW6300 Heavy Duty Series Access Points are available in the Cisco Catalyst IW6300 Heavy Duty Series Access Point Data Sheet at:
https://www.cisco.com/c/en/us/products/collateral/wireless/industrial-wireless-6300-series/datasheet-c 78-742907.html The Cisco Catalyst IW6300 Heavy Duty Series Access Point supports two radios (2.4-GHz and 5-GHz) and provides client access using the unlicensed RF Wi-Fi spectrum. Each model is equiped with four external Antenna ports, four Ethernet ports (one POE-In port, one SFP port, and two PoE-Out ports), and one USB2.0/3.0 port to support add-on module. The 5 GHz radios have 802.11ac Wave 2 capability. The 2.4 GHz or 5 GHz radio can be used for client access or can be used for both client access and backhaul traffic. The IW-6300 access point is a standalone unit that can be wall or pole mounted. The access point can operate as a relay node for other access points not directly connected to a wired network. Intelligent wireless routing is provided by the patented Adaptive Wireless Path Protocol (AWPP). This enables each access point to identify its neighbors and intelligently choose the optimal path to the wired network by calculating the cost of each path in terms of signal strength and the number of hops required to get to a controller. The access point can be configured, monitored, and operated through a Cisco wireless LAN controller
(hereafter called a controller) as described in the Cisco Wireless LAN Controller Configuration Guide. The Cisco Wireless Mesh Access Points, Design and Deployment Guide, describes how to plan and initially configure the Cisco mesh network, which supports wireless point-to-point, point-to-multipoint, and mesh deployments. The controllers use a browser-based management system, a command-line interface (CLI), or the Cisco Prime Infrastructure (PI) network management system to manage the controller and the associated access points. The access point supports hardware-based advanced encryption standard (AES) encryption between wireless nodes to provide end-to-end security. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-1 Hardware Models R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 1 Overview Hardware Models Figure 1-1 IW-6300H Access Points Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-2 Chapter 1 Overview R E V I E W D R A F T C I S C O C O N F I D E N T I A L The model numbers (or part numbers) and configuration for the Cisco Catalyst IW6300 Heavy Duty Series Access Points are described in the following table. Table 1-1 Access Point Model Numbers and Descriptions Hardware Models Model (or part number)1 IW-6300H-AC-X-K9 IW-6300H-DCW-X-K9 IW-6300H-DC-X-K9 Configuration IP66 and IP67 rated, hazardous location certified, AC power version. This model has 4 external antenna ports and contains a 2.4 GHz and 5 GHz radio with an option to configure in centralized, Flexconnect, or mesh mode and supports AC power source. IP66 and IP67 rated, hazardous location certified, DC wide range power version. This model has 4 external antenna ports and contains a 2.4 GHz and 5 GHz radio with an option to configure in centralized, Flexconnect, or mesh mode, and supports 10.8 VDC to 36 VDC power source. Note The marked DC input range is an absolute range. Do not apply tolerances. IP66 and IP67 rated, hazardous location certified, DC power version. This model has 4 external antenna ports and contains a 2.4 GHz and 5 GHz radio with an option to configure in centralized, Flexconnect, or mesh mode and supports 44VDC to 57 VDC power source. Note The marked DC input range is an absolute range. Do not apply tolerances. 1. The -X in the model number represents a regulatory domain for a specific country. A detailed list of components supported by each access point model is shown in the following table. Table 1-2 Components of Each Access Point Model Antenna Ports Product/PID IW-6300H-AC-X-K9 Four Type N Ethernet Ports
One 100/1000Mbps SFP PoE Out Port 1 35.3W Connectors for WAN Customer I/O Ports Four 1/2 NPT Ports IW-6300H-DCW-X-
K9 IW-6300H-DC-X-K9
One 100/1000Mbps RJ45 for WAN (UPoE or PoE+
in)
Two 100/1000Mbps RJ45 for LAN (802.11at or 802.3af out) Power Option UPoE, PoE+, AC
(100V to 240V) UPoE, PoE+, DC
(10.8V to 36V) UPoE, PoE+, DC
(44V to 57V)2 1. When powered with PoE+, the PoE Out power is not available, The PoE-Out port data link can still be active. 2. For DC SKU, if you want to output 802.3at type 2 PoE out power, DC input must >=51V. If you want to output 802.3af (802.3at type 1) PoE out power, DC input must >=45V. For a detailed description of the declarations of conformity and regulatory information for the Cisco Catalyst IW6300 Heavy Duty Series Access Points, see Appendix A, Declarations of Conformity and Regulatory Information. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-3 Hardware Features R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 1 Overview Hardware Features This section describes the hardware features of the IW-6300H series access points. Connectors This section describes the access point connectors. Note The illustrations in this document show all available connections for the access point. Unused connections are capped with a connector plug to ensure the dust/watertight integrity of the access point. See Working with the Access Cover for further details. IW-6300H Access Point Internal Connectors Figure 1-2 IW-6300H Access Point Internal Connectors 1 2 3 4 Power-IN (IW-6300H-DC-X-K9) PoE In port PoE Out port Internal ground 5 USB port 6 SFP port 7 Terminal block location of IW-6300H-AC-X-K9 and IW-6300H-DCW-X-K9 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-4 Chapter 1 Overview R E V I E W D R A F T C I S C O C O N F I D E N T I A L Hardware Features Console Port and Reset Button The console port and reset button are under a covering M25 plug located on the side of the access point, as shown in the following figure. Figure 1-3 IW-6300H Access Point Console Port and Reset Button 1 Console port 2 Reset button Inspect the seal of the plug and properly tighten it at the time of installation, and also every time the plug is removed and replaced. Tighten the plug to 5-6 lb-ft. If you do not tighten the plug properly, it will not meet IP66/67 criteria, and may lead to water leaking into the unit. Power Connector The following figure shows the AC power connector of access point model IW-6300-AC-X-K9. Figure 1-4 AC Power Connector of Access Point Model IW-6300H-AC-XK9 1 AC Power-IN 2 Internal ground Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-5 Hardware Features Chapter 1 Overview R E V I E W D R A F T C I S C O C O N F I D E N T I A L The following figure shows the DC power connector of access point model IW-6300-DCW-X-K9. Figure 1-5 IW-6300H-DCW-XK9 Power Connector 1 DC Power-IN 2 Internal ground The following figure shows the DC power connector of access point model IW-6300-DC-X-K9. Figure 1-6 IW-6300H-DC-XK9 Power Connector 1 DC Power-IN 2 Internal ground Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-6 Chapter 1 Overview Antenna Ports R E V I E W D R A F T C I S C O C O N F I D E N T I A L Hardware Features The access point antenna N-type connectors are located on the top of each model (see the following figure). The supported antennas can be directly attached to the access point or remotely located. When used in a Class 1, Zone 2, Division 2 hazardous location, this equipment must be mounted with proper RF cables (if required) and electrical wiring methods that comply with the governing electrical codes. Note Antenna caps must be installed when an antenna is not in use (maximum torque range: 6.2-9.7 in-lbs). Figure 1-7 Antenna Ports of IW-6300H Access Points 1 Antenna port B - Type N connector Wi-Fi 3 Antenna port D - Type N connector Wi-Fi 5 GHz 2.4/5 GHz TX/RX TX/RX 2 Antenna port C - Type N connector Wi-Fi 5 4 Antenna port A - Type N connector Wi-Fi 2.4/5 GHz TX/RX GHz TX/RX The IW-6300H access point can be configured via software to support dual band or single band antennas. When configured for dual band antennas, antenna ports A and B are used to support multiple input/output (MIMO) operation on both 2.4 and 5 GHz radios. When using Cisco Aironet omnidirectional antennas with Type N male connectors, the antennas can be connected directly to the access point. If the antennas are remotely located, an appropriate low loss RF cable should be used. Note Ensure that the antenna band mode is configured before the access point is installed. When configured for single band antennas, antenna ports A and B support MIMO operation on the 2.4 GHz radio and antenna ports C and D support MIMO operation on the 5 GHz radio. See the Cisco Wireless LAN Controller Configuration Guide for information on the software configuration. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-7 Hardware Features R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 1 Overview Use of four omnidirectional antennas attached directly to the Type N connectors is not recommended. To provide omnidirectional coverage with both 2.4 and 5 GHz radios using directly attached antennas, it is recommended to configure the IW-6300H in dual band mode, connect two dual band antennas such as AIR-ANT2547V-N, AIR-ANT2547V-N-HZ, or AIR-ANT2568VG-N to ports A and B, and cap ports C and D. The 2 GHz b/g/n radio operates in 2.4 GHz ISM band. It supports channels 1-11 in the US, 1-13 in Europe, and 1-13 in Japan. It has 2 transmitters with a maximum total output power of 27 dBm for 802.11b/g/n operation. Output power is configurable for 8 levels in 3 dB steps. It has two receivers that enable maximum-ratio combining (MRC). The 5 GHz a/n radio operates in the UNII-1 band (5.15-5.25 GHz), UNII-2 band (5.25 - 5.35 GHz), UNII-2 Extended/ETSI band (5.47 - 5.725 GHz), and the upper ISM band (5.725 - 5.850 GHz). It has two transmitters with a maximum total output power of 27 dBm depending on the regulatory domain. Tx power settings will change depending on the regulatory domain. Output power is configurable in 3 dB steps. Its two receivers enable maximum-ratio combining (MRC). Power Sources The Cisco Catalyst IW6300 Heavy Duty Series Access Points support the following power options:
1. Power over Ethernet by power injector AIR-PWRINJ-60RGD1= and AIR-PWRINJ-60RGD2=
2. AC or DC power IW-6300H-AC-X-K9 85-264V~ maximum, marked 100-240V~, 50-60Hz, 1.3A IW-6300H-DC-XK9 44 to 57Vdc, 1.2A IW-6300H-DCW-X-K9 10.8 to 36Vdc, 5.9A Note The marked DC input range is an absolute range. Do not apply tolerances. Warning To reduce risk of electric shock, connect the unit only to DC power source that complies with the Safety Extra-Low Voltage (SELV) requirements in IEC 60950 based safety standards or ES1 requirements in IEC 62368 based safety standards. Statement 1033 Power Injectors The IW6300 series access points support the following power injectors:
AIR-PWRINJ-60RGD1=
AIR-PWRINJ-60RGD2=
Caution Power injector AIR-PWRINJ-60RGD is not certified for installation within hazardous locations environments. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-8 Chapter 1 Overview R E V I E W D R A F T C I S C O C O N F I D E N T I A L Hardware Features For more information about installing the AIR-PWRINJ-60RGDx= power injectors, see Cisco Aironet Series Power Injectors AIR-PWRINJ-60RGD1= and AIR-PWRINJ-60RGD2= Installation Instructions. Ethernet (PoE) Ports The access point supports two Ethernet uplink port (one PoE-In port and one SPF fiber port), and two PoE-Out ports. The access point Ethernet uplink port uses an RJ-45 connector (with weatherproofing) to link the access point to the 10BASE-T, 100BASE-T, or 1000BASE-T network. The Ethernet cable is used to send and receive Ethernet data and to optionally supply inline power from the power injector or a suitably powered switch port. Tip The access point senses the Ethernet and power signals and automatically switches internal circuitry to match the cable connections. The Ethernet cable must be a shielded outdoor rated Category 5e (CAT5e) or better cable. The access point senses the Ethernet and power signals and automatically switches internal circuitry to match the cable connections. Fiber Option Warning Class 1 laser product. Statement 1008 The factory-orderable fiber option provides a fiber input and output capability. Fiber data is transmitted and received over a single or dual-strand fiber cable, depending on the SFP, which is connected to the access point using these SFP modules:
1000BASE-LX single-mode rugged SFP (GLC-LX-SM-RGD=)
1000BASE-SX multi-mode rugged SFP (GLC-SX-MM-RGD=)
100BaseBX10-U rugged SFP (GLC-FE-100BX-URGD=)
100BASE-FX rugged SFP (GLC-FE-100FX-RGD=)
100BASE-LX10 rugged SFP (GLC-FE-100LX-RGD=)
1000BASE-T rugged SFP (GLC-T-RGD=) Note SFP modules are not hot-swappable. Plug and unplug the SFP module, the AP will reboot. Client data is passed to the network controller through the fiber connection via a fiber-capable switch or controller. Configuration information can be found in the controller configuration guide of the switch or controller you are using. 1/2 NPT I/O Ports The four 1/2-NPT I/O ports are located at the bottom of the access point. These ports are tapered pipe threads. It is recommended that you use a 3/8 Allen wrench with 13-18" long wrench handle to remove the port plug. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-9 Hardware Features Chapter 1 Overview R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 1-8 1/2-NPT I/O Ports 1 AC or DC input 2 PoE port 3 PoE port 4 Fiber port Loctite 565 Thread Sealant needs to be applied to the threads prior to the installation, as shown in the following figure. Customer should supply certified 1/2 NPT conduit, gland, or adapter for each port used for appropriate installation. (For example, Sealcon provides glands and adapters that are certified. See https://www.sealconex.com/?ex=9wkuir-fln65y-13897wy-drrs7y.) Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-10 Chapter 1 Overview R E V I E W D R A F T C I S C O C O N F I D E N T I A L Hardware Features Optional Hardware Depending on the order configuration, the following optional access point hardware may be part of the shipment:
Cisco Aironet Antennas
Pole mount kits (IOT-ACCPMK)
Band installation tool for pole mount kit (AIR-BAND-INS-TL=)
Power injector (AIR-PWRINJ-60RGDx=)
1000BASE-LX single-mode rugged SFP (GLC-LX-SM-RGD=)
1000BASE-SX multi-mode rugged SFP (GLC-SX-MM-RGD=)
100BaseBX10-U rugged SFP (GLC-FE-100BX-URGD=)
100BASE-FX rugged SFP (GLC-FE-100FX-RGD=)
100BASE-LX10 rugged SFP (GLC-FE-100LX-RGD=)
1000BASE-T rugged SFP (GLC-T-RGD=) Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-11 Hardware Features R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 1 Overview Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 1-12 R E V I E W D R A F T C I S C O C O N F I D E N T I A L C H A P T E R 2 Before You Begin This chapter describes what steps you need to take before beginning the installation of your Access Point and contains the following sections:
Unpacking the Access Point, page 2-1
Tools and Hardware, page 2-2
Warnings, page 2-3
Safety Information, page 2-3
Avoiding Damage to Radios in a Testing Environment, page 2-5
Installation Guidelines, page 2-7 Unpacking the Access Point When you are unpacking the access point, do not remove the foam blocks attached to the antenna connectors. The foam protects the antenna connectors during installation. To unpack the access point, follow these steps:
Step 1 Step 2 Step 3 Open the shipping container and carefully remove the contents. Return all packing materials to the shipping container, and save it. Ensure that all items listed in Package Contents section on page 2-1 are included in the shipment. If any item is damaged or missing, notify your sales representative. Package Contents The typical access point package contains the following items:
Access point IW-6300H-AC-X-K9 (AC power model) IW-6300H-DC-XK9 (DC power model) IW-6300H-DCW-X-K9 (DC wide range power model)
Mount kit (IOT-ACCPMK) Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2-1 Tools and Hardware R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 2 Before You Begin
Ground lug and screws with lock washers
Weatherization tape and anti-seize compound Tools and Hardware The tools and hardware used to install the access point are described in:
Optional Tools and Hardware, page 2-2
Optional Tools and Hardware That You Supply, page 2-2
Pole Installation Hardware and Tools, page 2-3 Optional Tools and Hardware The optional tools and hardware that can be obtained from Cisco are:
Optional power injector (AIR-PWRINJ-60GRDx=)
Antennas, 2.4/5-GHz
Optional banding strap tool (BAND IT) (AIR-BAND-INST-TL=) Optional Tools and Hardware That You Supply Tools and materials that are user-supplied are:
1/2 or 13-mm socket wrench, used to open the Access Cover and to attach the mounting bracket
#2 Phillips or Flat screw driver to clamp wire terminal and ground terminal
3/8 Allen wrench with 13-18" long wrench handle to remove 1/2 NPT port plugs
Loctite 565 Thread Sealant for 1/2 NPT Ports
6-AWG copper ground wire
Ethernet RJ-45 connector and installation tool
Optional ground rod, as required by local regulations
Optional ladder, power lift, rope, or other tools as required
ESD-preventive cord and wrist strap.
Wire-stripping tools for stripping 14- and 18-gauge wires
Crimping tool If installed in a hazardous location, please note the additional items (see Product Document of Compliance for further details)
ATEX certified Armored cable for routing in conduit
Customer supplied ATEX certified 1/2 NPT conduit (rigid or flex), or ATEX certified cable gland or barrier gland for each connection
ATEX-certified AC or DC power cable, based on the AP model ordered Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2-2 Chapter 2 Before You Begin R E V I E W D R A F T C I S C O C O N F I D E N T I A L Warnings Pole Installation Hardware and Tools To install the access point on a vertical or horizontal metal, wood, or fiberglass pole, you need the following additional hardware and tools:
Customer banding strap tool (BAND IT)(AIR-BAND-INST-TL=)
Customer-supplied 13-mm and box-end wrench or socket set Warnings Warning IMPORTANT SAFETY INSTRUCTIONS This warning symbol means danger. You are in a situation that could cause bodily injury. Before you work on any equipment, be aware of the hazards involved with electrical circuitry and be familiar with standard practices for preventing accidents. Use the statement number provided at the end of each warning to locate its translation in the translated safety warnings that accompanied this device. Statement 1071 SAVE THESE INSTRUCTIONS Caution The installer is responsible for obtaining any required local or national safety inspections of the structural integrity of the installation by the local authority/inspection department. Warning This equipment must be externally grounded using a customer-supplied ground wire before power is applied. Contact the appropriate electrical inspection authority or an electrician if you are uncertain that suitable grounding is available. Statement 366 Warning Read the installation instructions before connecting the system to the power source. Statement 1004 Warning Ultimate disposal of this product should be handled according to all national laws and regulations. Statement 1040 Safety Information Follow the guidelines in this section to ensure proper operation and safe use of the access point. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2-3 Safety Information R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 2 Before You Begin FCC Safety Compliance Statement The FCC, with its action in ET Docket 96-8, has adopted a safety standard for human exposure to RF electromagnetic energy emitted by FCC-certified equipment. When used with approved Cisco Aironet antennas, Cisco Aironet products meet the uncontrolled environmental limits found in OET-65 and ANSI C95.1, 1991. Proper operation of this radio device according to the instructions in this publication results in user exposure substantially below the FCC recommended limits. Safety Precautions Warning The AC power supply has double pole/neutral fusing. Statement 188 Warning In order to comply with FCC radio frequency (RF) exposure limits, antennas should be located at a minimum of 7.9 inches (20 cm) or more from the body of all persons. Statement 332 Warning Do not work on the system or connect or disconnect cables during periods of lightning activity. Statement 1001 Warning Read the installation instructions before connecting the system to the power source. Statement 1004 Warning This unit is intended for installation in restricted access areas. A restricted access area can be accessed only through the use of a special tool, lock and key, or other means of security. Statement 1017 Warning This equipment must be grounded. Never defeat the ground conductor or operate the equipment in the absence of a suitably installed ground conductor. Contact the appropriate electrical inspection authority or an electrician if you are uncertain that suitable grounding is available. Statement 1024 Warning Only trained and qualified personnel should be allowed to install, replace, or service this equipment. Statement 1030 Warning Ultimate disposal of this product should be handled according to all national laws and regulations. Statement 1040 Warning When installing or replacing the unit, the ground connection must always be made first and disconnected last. Statement 1046 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2-4 Chapter 2 Before You Begin R E V I E W D R A F T C I S C O C O N F I D E N T I A L Avoiding Damage to Radios in a Testing Environment Warning To prevent the system from overheating, do not operate it in an area that exceeds the maximum recommended ambient temperature of:
75 C (167 F) Statement 1047 Warning Do not locate the antenna near overhead power lines or other electric light or power circuits, or where it can come into contact with such circuits. When installing the antenna, take extreme care not to come into contact with such circuits, because they may cause serious injury or death. For proper installation and grounding of the antenna, please refer to national and local codes (for example, U.S.:NFPA 70, National Electrical Code, Article 810, Canada: Canadian Electrical Code, Section 54). Statement 1052 Warning Installation of the equipment must comply with local and national electrical codes. Statement 1074 For safety and to achieve a good installation, please read and follow these safety precautions:
Select your installation site with safety, as well as performance in mind. Remember: electric power lines and phone lines look alike. For safety, assume that any overhead line can kill.
Call your electric power company. Tell them your plans, and ask them to come look at your proposed installation.
Plan your installation carefully and completely before you begin. Successful raising of a mast or tower is largely a matter of coordination. Each person should be assigned to a specific task and should know what to do and when to do it. One person should be in charge of the operation to issue instructions and watch for signs of trouble.
When installing the access point and antennas, remember:
Do not use a metal ladder. Do not work on a wet or windy day. Do dress properlyshoes with rubber soles and heels, rubber gloves, long sleeved shirt or jacket.
Use a rope to lift the access point. If the assembly starts to drop, get away from it and let it fall.
If any part of the antenna system should come in contact with a power line, do not touch it or try to remove it yourself. Call your local power company. They will remove it safely. If an accident should occur, call for qualified emergency help immediately. Avoiding Damage to Radios in a Testing Environment The radios on outdoor units (bridges) have higher transmit power levels than radios on indoor units
(access points). When you test high-power radios in a link, you must avoid exceeding the maximum receive input level for the receiver. At levels above the normal operating range, packet error rate (PER) performance is degraded. At even higher levels, the receiver can be permanently damaged. To avoid receiver damage and PER degradation, you can use one of the following techniques:
Separate the omnidirectional antennas by at least 2 ft (0.6 m) to avoid receiver damage or by at least 25 ft (7.6 m) to avoid PER degradation. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2-5 Avoiding Damage to Radios in a Testing Environment R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 2 Before You Begin Note These distances assume free space path loss and are conservative estimates. Required separation distances for damage and performance degradation levels in actual deployments are less if conditions are not non-line-of-sight.
Reduce the configured transmit power to the minimum level.
Use directional antennas, and keep them away from each other.
Cable the radios together using a combination of attenuators, combiners, or splitters to achieve a total attenuation of at least 60 dB. For a radiated test bed, the following equation describes the relationships among transmit power, antenna gain, attenuation, and receiver sensitivity:
txpwr + tx gain + rx gain - [attenuation due to antenna spacing] < max rx input level Where:
txpwr = Radio transmit power level tx gain = transmitter antenna gain rx gain = receiver antenna gain For a conducted test bed, the following equation describes the relationships among transmit power, antenna gain, and receiver sensitivity:
txpwr - [attenuation due to coaxial components] < max rx input level Caution Under no circumstances should you connect the antenna port from one access point to the antenna port of another access point without using an RF attenuator. If you connect antenna ports, you must not exceed the maximum survivable receive level of 0 dBm. Never exceed 0 dBm, or damage to the access point can occur. It is recommended to keep the received signal strength at or below -30 dBm to avoid degraded PER. Using attenuators, combiners, and splitters having a total of at least 60 dB of attenuation ensures that the receiver is not damaged and that PER performance is not degraded. Safety Precautions When Installing Antennas Warning Do not locate the antenna near overhead power lines or other electric light or power circuits, or where it can come into contact with such circuits. When installing the antenna, take extreme care not to come into contact with such circuits, as they may cause serious injury or death. For proper installation and grounding of the antenna, please refer to national and local codes (e.g. U.S.: NFPA 70, National Electrical Code, Article 810, Canada: Canadian Electrical Code, Section 54). Statement 280 1. Before you install an antenna, contact your Cisco account representative to explain which mounting method to use for the size and type of antenna that you are about to install. 2. Select your installation site with safety, as well as performance, in mind. Remember that electric power lines and phone lines look alike. For your safety, assume that any overhead line can kill you. 3. Contact your electric power company. Tell them your plans and ask them to come look at your proposed installation. 4. Plan your installation carefully and completely before you begin. Each person involved in an installation should be assigned to a specific task and should know what to do and when to do it. One person should be in charge of the operation to issue instructions and watch for signs of trouble. 5. When installing your antenna, follow these guidelines:
Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2-6 Chapter 2 Before You Begin Installation Guidelines R E V I E W D R A F T C I S C O C O N F I D E N T I A L Do not use a metal ladder. Do not work on a wet or windy day. Do dress properlywear shoes with rubber soles and heels, rubber gloves, and a long-sleeved shirt or jacket. 6. 7. 8. If the assembly starts to drop, move away from it and let it fall. Because the antenna, mast, cable, and metal guy wires are all excellent conductors of electrical current, even the slightest touch of any of these parts to a power line completes an electrical path through the antenna and the installer. If any part of the antenna system should come in contact with a power line, do not touch it or try to remove it yourself. Call your local power company to have it removed safely. If an accident should occur with the power lines, call for qualified emergency help immediately. Installation Guidelines Because the access point is a radio device, it is susceptible to common causes of interference that can reduce throughput and range. Follow these basic guidelines to ensure the best possible performance:
For information on planning and initially configuring your Cisco Mesh network, refer to the Cisco Wireless Mesh Access Points, Design and Deployment Guide.
Review the FCC guidelines for installing and operating outdoor wireless LAN devices.
Perform a site survey before beginning the installation.
Install the access point in an area where structures, trees, or hills do not obstruct radio signals to and from the access point.
The access points can be installed at any height, but best throughput is achieved when all the access points are mounted at the same height. Cisco recommends installing the access points no higher than 40 feet to allow support for wireless clients on the ground. Note To calculate path loss and to determine how far apart to install access points, consult an RF planning expert. Site Surveys Every network application is a unique installation. Before installing multiple access points, you should perform a site survey to determine the optimum use of networking components and to maximize range, coverage, and network performance. Consider the following operating and environmental conditions when performing a site survey:
Data ratesSensitivity and range are inversely proportional to data bit rates. The maximum radio range is achieved at the lowest workable data rate. A decrease in receiver sensitivity occurs as the radio data increases.
Antenna type and placementProper antenna configuration is a critical factor in maximizing radio range. As a general rule, range increases in proportion to antenna height. However, do not place the antenna higher than necessary, because the extra height also increases potential interference from other unlicensed radio systems and decreases the wireless coverage from the ground.
Physical environmentClear or open areas provide better radio range than closed or filled areas. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2-7 Installation Guidelines R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 2 Before You Begin
ObstructionsPhysical obstructions such as buildings, trees, or hills can hinder performance of wireless devices. Avoid locating the devices in a location where there is an obstruction between the sending and receiving antennas.
Applications and type of devices to be used on the WLAN. Before Beginning the Installation Before you begin the installation process:
Ensure that a site survey has been performed.
Ensure that your network infrastructure devices are operational and properly configured.
Ensure that your controllers are connected to switch trunk ports.
Ensure that your switch is configured with untagged access ports for connecting your access points.
Ensure that a DHCP server with Option 43 configured is reachable by your access points, or manually configure the controller information in the access point (for additional information, refer to the software configuration guide).
Become familiar with the access point installation components. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 2-8 R E V I E W D R A F T C I S C O C O N F I D E N T I A L C H A P T E R 3 Installing the Access Points This chapter describes how to install the access point and contains the following sections:
Mounting on a Wall or a Pole, page 3-1
Working with the Access Cover, page 3-14
Installing External Antennas, page 3-15
Grounding the Access Point, page 3-16
Using the Reset Button, page 3-18
Powering the Access Point, page 3-18
Performing Maintenance, page 3-25 Mounting on a Wall or a Pole This section provides instructions for the physical installation of your access points. Personnel installing the access point must understand wireless access points and bridging techniques and grounding methods. Caution All installation methods for mounting an access point on any wall surface is subject to the acceptance of local jurisdiction. Installation Option The Cisco Catalyst IW6300 Heavy Duty Series Access Points are installed using the pole mount installation kit (IOT-ACCPMK), which is used for pole or wall installations. Warning Only trained and qualified personnel should be allowed to install, replace, or service this equipment. Statement 1030 Warning Installation of the equipment must comply with local and national electrical codes. Statement 1074 Refer to these sections for installation details:
Access Point Mounting Orientation, page 3-2 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-1 Mounting on a Wall or a Pole R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 3 Installing the Access Points
Mounting the Access Point on a Wall, page 3-3
Mounting the Access Point on a Pole, page 3-6 Access Point Mounting Orientation When mounting an access point on a horizontal or vertical surface, you must ensure that the access point is oriented with the system LED pointing down. This positioning allows the LEDs to be visible to someone on the ground below the access point. You must also ensure the access point is mounted with the hinged access cover facing out. Note Omnidirectional antennas are vertically polarized and should be mounted vertically. The following figures show the dimension of the access point:
Figure 3-1 Unit Dimension - Front Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-2 Chapter 3 Installing the Access Points Mounting on a Wall or a Pole R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 3-2 Unit Dimension - Side Mounting the Access Point on a Wall The optional pole mount kit contains a mounting bracket for wall mounting. You can use the mounting bracket as a template to mark the positions of the mounting holes for your installation. You then install the mounting plate, and attach the access point when you are ready. The following table lists the material that you will need to provide in addition to the pole mount kit. Table 3-1 Material Needed to Mount Access Point to a Vertical Wall Materials Required Ground lug and screws (provided with access point) Crimping tool for ground lug Four M8 or 5/16 in. (31 mm) screws Four wall anchors (specified for wall material) Drill bit for wall anchors Electric drill and standard screwdriver
#6-AWG ground wire In Kit Yes No No No No No No Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-3 Mounting on a Wall or a Pole Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Table 3-1 Material Needed to Mount Access Point to a Vertical Wall (continued) Materials Required Shielded outdoor-rated Ethernet (CAT5e or better) cable No No Grounding block No Grounding rod 13-mm box-end wrench or socket set No In Kit Caution The mounting surface, attaching screws, and optional wall anchors must be able to support a 50-lb
(22.7 kg) static weight. The mounting bracket can be used as a template to mark the screw hole locations. To mount the access point on a vertical wall, follow these instructions:
Step 1 Use the mounting bracket as a template to mark four screw hole locations on your mounting surface. You can optionally use the individual mounting holes or the mounting slots. Figure 3-3 Mounting Bracket Dimension Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-4 Chapter 3 Installing the Access Points Mounting on a Wall or a Pole R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 3-4 Screw Hole Locations on the Mounting Bracket 1 Mounting slots 2 Mounting holes 3 Hands-free attach point 4 Second support bolt hole Step 2 Use four customer-supplied screws and optional screw anchors to attach the mounting plate to the mounting surface. Note If necessary, use suitable screw anchors and an exterior-grade plywood backboard to mount the access point to stucco, cement, or drywall. Step 3 Step 4 Screw a M8 x16 bolt in the top support bolt hole on each side the access point. Do not screw the bolt all the way in; leave approximately a 0.25 inch (0.635 cm) space. Position the two bolts on the access point onto the hands-free attach points on each side of the mounting bracket. Ensure that the access point cover is facing out. Never leave the access point unattended until fully installed. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-5 Mounting on a Wall or a Pole Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 3-5 Support Bolt Installation 1 Top support M8 x16 bolt 2 Second support M8x16 bolt Step 5 Step 6 Screw a M8 x16 bolt (with flat and lock washers) into the second bolt hole on each side of the access point. Ensure that the front of the access point is vertical, and tighten the four bolts to 13 to 15 ft lbs
(17.6 to 20.3 Nm). Step 7 When using the Cisco Aironet Dual-Band Omnidirectional Antennas, connect them to the access point. Hand-tighten the antennas to the access point. Step 8 Continue with Grounding the Access Point and Powering the Access Point. Mounting the Access Point on a Pole When installing an access point on a vertical pole, you should use the optional Cisco pole mount kit. The kit supports metal, wood, or fiberglass poles from 2 to 16 inches in diameter. Assembling the Pole Clamp Bracket and the Mounting Bracket The pole mount kit contains several parts that you must assemble prior to mounting on a pole. First you need to assemble two strap brackets on the pole clamp bracket that are positioned for the pole diameter you are using to mount the access point. The following figure illustrates the pole diameter indicators and bolt holes on the pole clamp bracket. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-6 Chapter 3 Installing the Access Points Mounting on a Wall or a Pole R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 3-6 Pole Clamp Bracket Adjustment Hole Locations 1 Pole size indicators 2 Bolt holes for pole diameters
(11 to 16 inches (27.94 cm to 40.64 cm) indicated)
2 to 6 inches (5.08 cm to 15.24 cm)
6 to 11 inches (15.24 cm to 27.94 cm)
11 to 16 inches (27.94 cm to 40.64 cm) To assemble the pole clamp bracket, follow these steps:
Step 1 Position the strap brackets on the pole clamp bracket for the pole diameter you are using and secure each strap bracket with two M8 x16 bolts (with lock washers). Tighten the bolts to 13 to 15 ft lbs (17.6 to 20.3 Nm). Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-7 Mounting on a Wall or a Pole Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 3-7 Assembled Pole Clamp Bracket and Strap Brackets 1 3 M8 x1.25x16 bolts (with lock washers) Strap bracket (shown positioned for 11 to 16 inch diameter pole) Pole clamp bracket 2 Step 2 Screw the M8 nut onto the pole clamp bracket support bolt, and tighten just enough to prevent the bolt from falling off. Step 3 Go to Pole Mounting. Pole Mounting To mount your access point on a vertical pole, you need to install two metal bands around the pole to support the access point. This process requires extra tools and material not provided in the pole mount kit (see the following table). Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-8 Chapter 3 Installing the Access Points Mounting on a Wall or a Pole R E V I E W D R A F T C I S C O C O N F I D E N T I A L Table 3-2 Materials Needed to Mount Access Point on a Pole Mounting Method Vertical or streetlight pole Materials Required Two 0.75-in (1.9 cm) stainless steel bands Banding strap tool (BAND IT) (Cisco AIR-BAND-INST-TL=) Ground lug (provided with access point) Crimping tool for ground lug, Panduit CT-720 with CD-720-1 die (http://onlinecatalog.panduit.com)
#6 AWG ground wire In Kit Yes No Yes No No To mount the access point onto a vertical pole, follow these steps:
Step 1 Step 2 Select a mounting location on the pole to mount the access point. You can attach the access point to any pole from 2 to 16 inch (5.1 to 40.6 cm) in diameter. For poles larger than 3.5 inch (8.9 cm), mount the pole clamp bracket assembly to a pole using two metal straps. Following the instructions provided with the banding strap tool (BAND IT)
(AIR-BAND-INST-TL=), loop each metal strap twice through the slots on the strap bracket. Caution Do not place the metal straps in the large open area between the pole clamp bracket and the strap brackets because this does not properly secure the access point. Figure 3-8 Clamp Bracket Assembly Mounted on Poles Larger than 3.5 inch (8.9 cm) 2 3 1 8 1 4 1 3 2 2 3 4 1 2 Pole clamp bracket Strap slot in strap bracket 3 Metal mounting strap 4 Pole Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-9 Mounting on a Wall or a Pole R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 3 Installing the Access Points Step 3 For pole diameters of 3.5 inch (8.9 cm) or less, mount the pole clamp bracket assembly to a pole using two metal straps looped through the space between the pole clamp bracket and the strap brackets to provide maximum holding strength for extreme environments. Following the instructions provided with the banding strap tool (BAND IT) (AIR-BAND-INST-TL=), loop each metal strap twice. Caution Do not place the metal straps in the large open area between the pole clamp bracket and the strap brackets because this does not properly secure the access point. Step 4 Position the pole clamp bracket on the pole as needed before tightening the metal bands. Note When the metal bands are tightened to the full tension, the pole clamp bracket cannot be adjusted unless the metal bands are cut or disassembled. Tighten the metal bands using the banding strap tool (BAND IT) (Cisco AIR-BAND-INST-TL=) by following the operating instructions in the box with the tool. Ensure that the metal bands are as tight as possible. Place the mounting bracket onto the pole clamp bracket support bolt. Install four M8 x16 bolts (with flat and lock washers) into the bolt holes. Hand-tighten the bolts and the nut (do not overtighten). Adjust the top edge of the mounting bracket until it is horizontal and tighten the bolts and the flange nut to 13 to 15 ft lbs (17.6 to 20.3 Nm). Step 5 Step 6 Step 7 Step 8 Step 9 Figure 3-9 Attach the Mount Bracket 1 M8 x 16 bolts 2 Flange nut Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-10 Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Mounting on a Wall or a Pole Step 10 Screw a M8 x16 bolt (without a flat or lock washer) in the top support bolt hole on each side the access point. Do not screw the bolt all the way in. Leave a gap of approximately 0.25 inch (0.635 cm). Step 11 Position the two bolts on the access point onto the hands-free attach point of the mounting bracket. Note The access point should be positioned with the LEDs on the bottom to allow viewing from the ground and with the hinged cover facing out. Figure 3-10 Assembling Access Point to Hands-Free Attach Point with Top Support Bolts 1 2 Top Support M8 x16 bolt hole Second M8 x16 bolt hole 3 Hands-free attach point Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-11 Mounting on a Wall or a Pole R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 3 Installing the Access Points Step 12 Screw a M8 x16 bolt (with flat and lock washers) into the second bolt hole on each side of the access point. Figure 3-11 Second Support Bolt Installation 1 M8 x16 bolt Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-12 Chapter 3 Installing the Access Points Mounting on a Wall or a Pole R E V I E W D R A F T C I S C O C O N F I D E N T I A L Step 13 Ensure that the front of the access point is vertical, and tighten the four bolts to 13 to 15 ft lbs
(17.6 to 20.3 Nm). Figure 3-12 Assembled Access Point Hanging in Mounting Bracket 1 Access point 2 Mount bracket 3 4 Pole (wood, metal, or fiberglass) 2 to 16 in. (5.1 to 40.6 cm) diameter Stainless steel mounting straps Step 14 When using the Cisco Aironet Dual-Band Omnidirectional Antennas, connect them to the access point. Hand-tighten the antennas to the access point. Step 15 Continue with Grounding the Access Point and Powering the Access Point. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-13 Working with the Access Cover R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 3 Installing the Access Points Working with the Access Cover This section details opening and closing the access cover of the access point. Opening the Access Cover Caution The access cover must not be opened unless the area is considered non-hazardous and the AP has been powered off. You need to open the access cover to access the AC or DC terminal block, the Ethernet ports, and when you are installing the fiber-optic SFP module. To open the access cover, follow these steps:
Step 1 Use 0.5-in (13-mm) box-end wrench or socket set to unscrew the two bolts on the front cover of the unit. Only unscrew the bolts about 2 turns until they are easily turned by hand, and the bolts are resting on springs. Figure 3-13 Access Point Front View of Cover 1 M8 bolts Step 2 The cover is hinged on the bottom, and the bolts are designed to be captive. Carefully open the cover and fold the cover back. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-14 Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Installing External Antennas Closing the Access Cover To close the access cover, follow these steps:
Step 1 Ensure that O-ring sealing surface is free of debris and that O-ring is undamaged and fully contained in groove. Step 2 When closing the access cover, be careful not to pinch internal wires. Step 3 Carefully position the cover flush with all sides of the access point, then slowly hand-tighten each bolt. Step 4 When all bolts are hand-tightened, use a 13-mm closed-end wrench or socket to partially tighten the bolts Step 5 in the tightening sequence. Tighten each bolt to 3 to 4 ft lbs (0.34 to 0.45 Nm). Repeat Step 3 using the same tightening sequence to fully tighten each bolt to 6 to 7 ft lbs
(0.68 to 0.79 Nm). Installing External Antennas Note When operating in the 5GHz UNII-1 band, all Omni Directional antennas should be installed vertically, and all directional antennas should be installed with the main beam aimed parallel to or tilted down toward the horizon. The following table shows the external antennas supported by the IW-6300H access point and provides required quantities for each model. Table 3-3 IW-6300H Access Point Supported External Antennas Product ID AIR-ANT2547V-N AIR-ANT2547VG-N AIR-ANT2547V-N-HZ Frequency Band 2.4 / 5 GHz 2.4 / 5 GHz 2.4 / 5 GHz Gain 4 / 7 dBi 4 / 7 dBi 4 / 7 dBi 2.4 / 5 GHz AIR-ANT2568VG-N 2.4 / 5 GHz AIR-ANT2588P3M-N=
2.4 / 5 GHz AIR-ANT2513P4M-N=
AIR-ANT2450V-N=
2.4 GHz AIR-ANT2450V-N-HZ= 2.4 GHz 6 / 8 dBi 8 / 8 dBi 13 / 13 dBi 5 dBi 5 dBi AIR-ANT2450VG-N=
AIR-ANT2450HG-N=
2.4 GHz 2.4 GHz AIR-ANT2480V-N=
AIR-ANT2413P2M-N=
2.4 GHz 2.4 GHz 5 dBi 5 dBi 8 dBi 13 dBi Type Omnidirectional, vertically polarized, white Omnidirectional, vertically polarized, gray Omnidirectional, vertically polarized, white, for Hazardous Locations Omnidirectional, vertically polarized, gray Directional, dual polarized, 3 port Directional, dual polarized, 4 port Omnidirectional, vertically polarized, white Omnidirectional, vertically polarized, white, for Hazardous Locations Omnidirectional, vertically polarized, gray Omnidirectional, horizontally polarized, gray Omnidirectional, vertically polarized Directional, dual polarized, 2 port Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-15 Grounding the Access Point Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Table 3-3 IW-6300H Access Point Supported External Antennas (continued) Product ID AIR-ANT5150VG-N=
AIR-ANT5150HG-N=
Frequency Band 5 GHz 5 GHz AIR-ANT5180V-N=
AIR-ANT5114P2M-N=
5 GHz 5 GHz Gain 5 dBi 5 dBi 8 dBi 13 dBi Type Omnidirectional, vertically polarized, gray Omnidirectional, horizontally polarized, gray Omnidirectional, vertically polarized Directional, dual polarized, 2 port For installation instructions and detailed information on any of these antennas, refer to the following antenna guides:
https://www.cisco.com/c/en/us/td/docs/routers/connectedgrid/antennas/installing-combined/industria l-routers-and-industrial-wireless-antenna-guide.html
http://www.cisco.com/c/en/us/support/wireless/aironet-antennas-accessories/products-installation-gu ides-list.html Follow all safety precautions when installing the antennas. For information on safety, see Safety Precautions When Installing Antennas. Non-Cisco Antennas Cisco does not support any third-party antennas. RF connectivity and compliance of third party antennas is the users responsibility. Cisco does not recommend any third-party antennas, and Cisco Technical Assistance Center will not be able to provide any support for third-party antennas. Ciscos FCC Part 15 compliance is only guaranteed with Cisco antennas or antennas that are of the same design and gain as Cisco antennas. Grounding the Access Point The access point must be grounded before connecting power. In all outdoor installations you must follow these instructions to properly ground the case:
Step 1 Step 2 If using insulated 6-AWG copper ground wire, strip the insulation as required for the grounding lug. Use the appropriate crimping tool to crimp the bare 6-AWG copper ground wire to the supplied grounding lug. Note The grounding lug and hardware used must comply with local and national electrical codes. Step 3 Open the anti-corrosion sealant (supplied), and apply a liberal amount over the metal surface, called the Ground Pad, where the ground strap screw holes are located (see the following figure). Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-16 Chapter 3 Installing the Access Points Grounding the Access Point R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 3-14 Position of the Ground Pad on the Right Side of the AP 5 0 0 0 2 5 1 1 Ground pad, where the ground strap screw holes are located. Step 4 Connect the grounding lug to the access point grounding screw holes using the supplied two Phillips head screws (M4 x10 mm) with lock washers. Tighten the grounding screw to 22 to 24 lb-in (2.49 to 2.71 Nm). Step 5 If necessary, strip the other end of the ground wire and connect it to a reliable earth ground, such as a grounding rod or an appropriate grounding point on a metal streetlight pole that is grounded. 6 0 0 0 2 5 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-17 Using the Reset Button R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 3 Installing the Access Points Using the Reset Button The access point has a reset button located on the right side of the unit (see the following figure). Figure 3-15 IW-6300H Access Point Console Port and Reset Button 1 Console port 2 Reset button The reset button is under a covering M25 plug. Properly tighten it at the time of installation, and also every time it is removed and replaced. Tighten the screw to 5-6 lb-ft. If you do not tighten the plug properly, it will not meet IP67 criteria, and may lead to water leaking into the unit. Powering the Access Point The access point can be powered by one of these methods:
1. PoE power source by power injector 2. AC or DC power:
IW-6300H-AC-X-K9 85-264V~ maximum, marked 100-240V~, 50-60Hz, 1.3A IW-6300H-DC-XK9 44 to 57Vdc, 1.2A IW-6300H-DCW-X-K9 10.8 to 36Vdc, 5.9A Note The marked DC input range is an absolute range. Do not apply tolerances. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-18 Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Powering the Access Point Note In all cases above, the AC branch circuit powering the access point must be limited to no more than 20A from the over-protection device supplied by the user. This branch power protection must meet all local and national electrical codes. The IW6300 access point for hazardous locations can be connected to more than one power source. The access point detects the available power sources and switches to the preferred power source using the following priority:
1. AC or DC power 2. Power over Ethernet Connecting a Power Injector The power injector provides 55 VDC to the access point over the Ethernet cable and supports a total end-to-end Ethernet cable length of 100 m (328 ft) from the switch to the access point. Caution Power injector AIR-PWRINJ-60RGDx= is not certified for installation within hazardous locations environments. Note The PoE Out power is disabled when the access point is powered by the power injector. But the PoE Out data link can still be active when using power injector. When your access point is powered by an optional power injector, follow these steps to complete the installation:
Step 1 Before applying PoE to the access point, ensure that the access point is grounded (see Grounding the Access Point). Step 2 Connect a CAT5e or better Ethernet cable from your wired LAN network to the power injector. Warning To reduce the risk of fire, use only No. 26 AWG or larger telecommunication line cord. Statement 1023 Use only the power injector (AIR-PWRINJ-60RGDx=) for the access point. Note The installer is responsible for ensuring that powering the access point from this type of power injector is allowed by local and/or national safety and telecommunications equipment standards. Tip To forward bridge traffic, add a switch between the power injector and controller. Refer to the latest Cisco Wireless Mesh Access Points, Design and Deployment Guide for more information. Step 3 Ensure that the antennas are connected and that a ground is attached to the access point before you apply power to the access point. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-19 Powering the Access Point R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 3 Installing the Access Points Step 4 Step 5 Step 6 Ensure that the power injector is grounded. See the power injector installation guide for details:
https://www.cisco.com/c/en/us/td/docs/wireless/access_point/power/guide/air_pwrinj_60rgd.html Connect a shielded outdoor-rated Ethernet (CAT5e or better) cable between the power injector and the PoE In connector of the access point. Connect the Ethernet cable to the access point PoE IN port (see Connecting an Ethernet Cable to the Access Point). Note When the access point is powered by PoE+, the PoE Out power is disabled. But the PoE Out data link can still be active. Step 7 Continue with What to Do Next. Connecting an Ethernet Cable to the Access Point The following tools and materials are required:
Shielded outdoor-rated Ethernet (CAT5e or better) cable Note The Ethernet cable from the power injector to the access point must be at least 10 ft
(3.05 m) long.
RJ-45 connector and installation tool
Adjustable wrench
Ex-certified cable gland or conduit To connect the shielded Ethernet cable to the access point, follow these steps:
Step 1 Step 2 Step 3 Step 4 Step 5 Disconnect power to the power injector, and ensure all power sources to the access point are turned off. Ensure a 6 AWG ground wire is connected to the access point (see Grounding the Access Point). Use a 3/8 Allen wrench to remove the 1/2 NPT Ethernet connector plug from the access point. Insert the unterminated end of the Ethernet cable into the conduit, and pull several inches of cable through the conduit. Install an RJ-45 connector on the unterminated end of the Ethernet cable using your Ethernet cable installation tool. Warning To reduce the risk of fire, use only No. 26 AWG or larger telecommunication line cord. Statement 1023 Step 6 Step 7 Step 8 Step 9 Carefully insert the RJ-45 cable connector into the Ethernet port opening on the access point, and connect to the internal Ethernet connector. Ensure that the antennas are connected to the access point before you apply power to the access point. Route your Ethernet cable, and cut off any excess cable. Install an RJ-45 connector on the unterminated cable end, and insert it into the power injector. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-20 Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Powering the Access Point Step 10 Turn on power to the power injector. Connecting AC Power to IW-6300H-AC-X-K9 Note When you install the conduit, be sure to comply with the local electrical codes for your area. To route and connect the ground and AC power cabling to the IW-6300H-AC-X-K9 access point model, follow these steps:
Warning A readily accessible two-poled disconnect device must be incorporated in the fixed wiring. Statement 1022 Warning When installing or replacing the unit, the ground connection must always be made first and disconnected last. Statement 1046 Caution Always install the ground wire before connecting all power leads. Step 1 Step 2 Step 3 Open the access point cover. See Opening the Access Cover for instructions. Ensure a 6 AWG ground wire is connected to the access point (see Grounding the Access Point). Route the AC power cable through the 1/2-NPT port. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-21 Powering the Access Point Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 3-16 Connecting Internal Ground and AC Power Connection for IW-6300H-AC-X-K9 1 2 Customer-supplied harness Customer-supplied cable (ATEX only) 3 Terminal block Step 4 Step 5 Step 6 Step 7 Step 8 Use a wire stripper tool to remove the insulation from each wire. Remove only enough wire to provide a solid connection in the terminal block. The hot wires should have no bare wire exposed after the connection is made. Insert the ground wire into the internal ground. Insert each hot wire into the AC entry terminal block. Use a Phillips screwdriver to tighten the terminal block set screws to secure the wires in the terminal block. Verify that no bare wire is exposed. If wire is exposed, remove it from the terminal block, adjust the length, and reinstall. Step 9 Check your work. Step 10 Close the access point cover. See Closing the Access Cover for details. Connecting DC Power to IW-6300H-DCW-X-K9 Warning This product relies on the buildings installation for short-circuit (overcurrent) protection. Ensure that the protective device is rated not greater than:
10 A. Statement 1005 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-22 Chapter 3 Installing the Access Points R E V I E W D R A F T C I S C O C O N F I D E N T I A L Powering the Access Point Warning A readily accessible two-poled disconnect device must be incorporated in the fixed wiring. Statement 1022 Warning To reduce risk of electric shock, connect the unit only to DC power source that complies with the Safety Extra-Low Voltage (SELV) requirements in IEC 60950 based safety standards or ES1 requirements in IEC 62368 based safety standards. Statement 1033 To route and connect the power cable to the IW-6300H-DCW-XK9 model, follow these steps:
Step 1 Step 2 Step 3 Step 4 Step 5 Step 6 Open the access point cover. See Opening the Access Cover for instructions. Ensure a 6 AWG ground wire is connected to the access point (see Grounding the Access Point). Route the power cable through the 1/2 NPT port. Use a wire stripper tool to remove the insulation from each wire. Remove only enough wire to provide a solid connection in the terminal block. The hot wires should have no bare wire exposed after the connection is made. Insert the ground wire into the internal ground. Insert each hot wire into the terminal block. Figure 3-17 IW-6300H-DCW-X-K9 Internal Ground and Terminal Block Location 1 Terminal block 2 Internal ground Step 7 Use a Phillips screwdriver to tighten the terminal block set screws to secure the wires in the terminal block. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-23 Powering the Access Point R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 3 Installing the Access Points Step 8 Verify that no bare wire is exposed. If wire is exposed, remove it from the terminal block, adjust the length, and reinstall. Step 9 Check your work. Step 10 Close the access point cover. See Closing the Access Cover for details. Connecting DC Power to IW-6300H-DC-X-K9 Warning This product relies on the buildings installation for short-circuit (overcurrent) protection. Ensure that the protective device is rated not greater than:
5 A. Statement 1005 Warning A readily accessible two-poled disconnect device must be incorporated in the fixed wiring. Statement 1022 Warning To reduce risk of electric shock, connect the unit only to DC power source that complies with the Safety Extra-Low Voltage (SELV) requirements in IEC 60950 based safety standards or ES1 requirements in IEC 62368 based safety standards. Statement 1033 To route and connect the power cable to the IW-6300H-DC-XK9 model, follow these steps:
Step 1 Step 2 Step 3 Open the access point cover. See Opening the Access Cover for instructions. Ensure a 6 AWG ground wire is connected to the access point (see Grounding the Access Point). Route the power cable through the 1/2-NPT port. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-24 Chapter 3 Installing the Access Points Performing Maintenance R E V I E W D R A F T C I S C O C O N F I D E N T I A L Figure 3-18 Connecting Internal Ground and DC Power for IW-6300H-DC-X-K9 1 Terminal block 2 Internal ground Step 4 Step 5 Step 6 Step 7 Step 8 Use a wire stripper tool to remove the insulation from each wire. Remove only enough wire to provide adequate crimp on to ring terminals (Cisco supplied). Remove terminal strip screw and square washer. Connect DC line to terminal strip location. Tighten terminal strip screws to secure ring terminal and wire. Secure DC input cord to wire tie anchor adjacent to terminal strip. Check your work. Close the access point cover. See Closing the Access Cover for details. Performing Maintenance The access point requires minimal periodic or preventive maintenance as it has no moving parts, filters, lubricants, or mechanical contact components. However, when installed in a hazardous location, periodic inspections should be conducted in order to ensure that the access point is operating satisfactory. This section provides information about performing maintenance on an access point installed in a hazardous location. Additional maintenance information can be found in Chapter 4, Troubleshooting and the Troubleshooting a Mesh Network Guide. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-25 Performing Maintenance R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 3 Installing the Access Points Removing the Access Point from Service When removing an access point from service, make sure you remove power from the access point before opening the cover and disconnecting the input wiring. When removing the wiring, the ground connection should be the last to be disconnected. Conducting Periodic Inspections The access point should be inspected periodically to ensure normal and airtight operation in the hazardous location environment. Table 3-4 lists the inspection routines and their periodicity. Table 3-4 Periodic Inspection Table Inspection Routine Inspect O-ring seals and exterior electrical connections for aging, corrosion, and low ground resistance. Inspect cover and liquid-tight adapter gaskets for airtightness. Periodicity Every 3 years Every 5 years Conducting Periodic Cleaning The access point is designed to not require periodic cleaning. What to Do Next When you power up a MAP that is not connected to a wired Ethernet, fiber-optic, or cable network to the controller, the access point uses the Cisco Adaptive Wireless Path Protocol (AWPP) to bind to another mesh access point (MAP) with the best path to a root access point (RAP) connected to the wired network to a controller. The access point sends a discovery request when powered up. If you have configured the access point in the controller correctly, the controller sends back a discovery response to the access point. When that happens, the access point sends out a join request to the controller, and the controller responds with a join confirmation response. Then the access point establishes a Control And Provisioning of Wireless Access Points (CAPWAP) connection to the controller and gets the shared secret configured on the controller. Refer to the Cisco Wireless LAN Controller Configuration Guide for more information on configuring, monitoring, and operating your access points. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 3-26 R E V I E W D R A F T C I S C O C O N F I D E N T I A L C H A P T E R 4 Troubleshooting This chapter provides troubleshooting procedures for basic problems with the access point. Sections in this chapter include:
Guidelines for Using the Access Points, page 4-1
Controller MAC Filter List, page 4-3
Accessing the Console Port and the Reset Button, page 4-3
Monitoring the Access Point LEDs, page 4-4
Verifying Controller Association, page 4-6
Changing the Bridge Group Name, page 4-7 Guidelines for Using the Access Points You should keep these guidelines in mind when you use the access points:
The access point can only communicate with controllers and cannot operate independently.
The access point does not support Wireless Domain Services (WDS) and cannot communicate with WDS devices. However, the controller provides functionality equivalent to WDS when the access point associates to it.
The access point only supports Layer 3 CAPWAP communications with the controllers. In Layer 3 operation, the access point and the controller can be on the same or different subnets. The access point communicates with the controller using standard IP packets. A Layer 3 access point on a different subnet than the controller requires a DHCP server on the access point subnet and a route to the controller. The route to the controller must have destination UDP ports 12222 and 12223 open for CAPWAP communications. The route to the primary, secondary, and tertiary controllers must allow IP packet fragments.
Before deploying your access points, ensure that the following has been done:
Your controllers are connected to switch ports that are configured as trunk ports. Your access points are connected to switch ports that are configured as untagged access ports. A DHCP server is reachable by your access points and has been configured with Option 43. Option 43 provides the IP addresses of the management interfaces of your controllers. Typically, a DHCP server can be configured on a Cisco switch. Optionally, a DNS server can be configured to enable CISCO-CAPWAP-CONTROLLER. Use local domain to resolve to the IP address of the management interface of your controller. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4-1 Important Notes Chapter 4 Troubleshooting R E V I E W D R A F T C I S C O C O N F I D E N T I A L Your controllers are configured and reachable by the access points. Your controllers are configured with the access point MAC addresses and the MAC filter list is enabled. If layer 3 functionality is enabled on your switch, make sure that DHCP broadcast and request can be passed.
The access point PoE Out port should be connected only to a single peripheral customer device, such as a camera or sensor gateway. We recommend that the PoE Out port not be connected to a switch or hub.
After the access points are associated to the controller, you should change the bridge group name
(BGN) from the default value. With the default BGN, the mesh access points (MAPs) can potentially try to connect with other mesh networks and slow down the convergence of the network. Important Notes Convergence Delays During deployment, the access points can experience convergence delays due to various causes. The following list identifies some operating conditions that can cause convergence delays:
A root access point (RAP) attempts to connect to a controller using any of the wired ports (cable, fiber-optic, or PoE-In). If the wired ports are operational, the RAP can potentially spend several minutes on each port prior to connecting to a controller.
If a RAP is unable to connect to a controller over the wired ports, it attempts to connect using the wireless network. This results in additional delays when multiple potential wireless paths are available. If a MAP is unable to connect to a RAP using a wireless connection, it then attempts to connect using any available wired port. The access point can potentially spend several minutes for each connection method, before attempting the wireless network again. Bridge Loop The access point supports packet bridging between wired and wireless network connections. The same network must never be connected to multiple wired ports on an access point or on two bridged access points. A bridge loop causes network routing problems. Controller DHCP Server The controller DHCP server only assigns IP addresses to lightweight access points, Ethernet bridging clients on the mesh access points, and wireless clients associated to an access point. It does not assign an IP address to other devices. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4-2 Chapter 4 Troubleshooting R E V I E W D R A F T C I S C O C O N F I D E N T I A L Controller MAC Filter List MAP Data Traffic If the signal on the access point backhaul channel has a high signal-to-noise ratio, it is possible for a MAP to connect to the controller, via parent node, but not be able to pass data traffic, such as pinging the access point. This can occur because the default data rate for backhaul control packets is set to 6 Mb/s, and the backhaul data rate set to auto by the user. Controller MAC Filter List Before activating your access point, you must ensure that the access point MAC address has been added to the controller MAC filter list and that Mac Filter List is enabled. Note The access point MAC address and barcode is located on the bottom of the unit. When two MAC addresses are shown, use the top MAC address. Check if Duplo has two MAC address on labels. To view the MAC addresses added to the controller MAC filter list, you can use the controller CLI or the controller GUI:
Controller CLIUse the show macfilter summary controller CLI command to view the MAC addresses added to the controller filter list.
Controller GUILog into your controller web interface using a web browser, and choose SECURITY > AAA > MAC Filtering to view the MAC addresses added to the controller filter list. Accessing the Console Port and the Reset Button The console port and reset button are under a covering M25 plug located on the side of the access point, as shown in the following figure. Figure 4-1 IW-6300H Access Point Console Port and Reset Button 1 Console port 2 Reset button Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4-3 Monitoring the Access Point LEDs R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 4 Troubleshooting Inspect the seal of the plug and properly tighten it at the time of installation, and also every time the plug is removed and replaced. Tighten the plug to 5-6 lb-ft. If you do not tighten the plug properly, it will not meet IP67 criteria, and may lead to water leaking into the unit. Resetting the Access Point Using the Reset button you can:
Reset the AP to the default factory-shipped configuration.
Clear the AP internal storage, including all configuration files. To use the Reset button, press, and keep pressed, the Reset button on the access point during the AP boot cycle. Wait until the AP status LED changes to Amber. During this, the AP console shows a seconds counter, counting the number of seconds the Reset button is pressed. Then:
To reset the AP to its default factory-shipped configuration, keep the Reset button pressed for less than 20 seconds. The AP configuration files are cleared. This resets all configuration settings to factory defaults, including passwords, WEP keys, the IP address, and the SSID.
To clear the AP internal storage, including all configuration files and the regulatory domain configuration, keep the Reset button pressed for more than 20 seconds, but less than 60 seconds. The AP status LED changes from Amber to Red, and all the files in the AP storage directory are cleared. If you keep the Reset button pressed for more than 60 seconds, the Reset button is assumed faulty and no changes are made. Monitoring the Access Point LEDs If your access point is not working properly, look at the system LED and port LEDs. You can use them to quickly assess the status of the unit. Note It is expected that there will be small variations in LED color intensity and hue from unit to unit. This is within the normal range of the LED manufacturer specifications and is not a defect. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4-4 Chapter 4 Troubleshooting Monitoring the Access Point LEDs R E V I E W D R A F T C I S C O C O N F I D E N T I A L The access point LED signals are listed in the following table. Table 4-1 Access Point System LED Signals LED Message Type Boot loader status sequence Color Blinking Green Association status Chirping (short blips) Green Operating Status Solid Green Blinking Amber Cycling through Green, Red, and Amber Rapidly cycling through Red, Green, Amber, and Off Blinking Red Boot loader warnings Blinking Amber Red Blinking Green Initializing Ethernet Meaning Boot loader status sequence:
DRAM memory test in progress
DRAM memory test OK
Board initialization in progress
Initializing FLASH file system
FLASH memory test OK
Ethernet OK
This status indicates a normal operating condition. The unit is joined to a controller, but no wireless client is associated with it. Normal operating condition with at least one wireless client associated with the unit A software upgrade is in progress Discovery/join process is in progress Starting Cisco IOS Initialization successful This status indicates that the Access Point location command has been invoked. This status indicates that an Ethernet link is not operational Configuration recovery is in progress (the Reset button has been pushed for 2-3 seconds) There is an Ethernet failure or an image recovery (the Reset button has been pushed for 20-30 seconds) An image recovery is in progress (the Reset button has been released) Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4-5 Verifying Controller Association R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 4 Troubleshooting Table 4-1 Access Point System LED Signals LED Message Type Boot loader errors Color Red Blinking Red and Amber Blinking Red and Off AP OS errors Red Cycling through Red, Green, Amber, and Off Meaning There has been a DRAM memory test failure There has been a FLASH file system failure This sequence may indicate any of the following:
Environment variable failure
Bad MAC address
Ethernet failure during image recovery
Boot environment failure
No Cisco image file
Boot failure There has been a software failure; a disconnect then reconnect of the unit power may resolve the issue This is a general warning of insufficient inline power The access point port LED signals are listed in the following table. Table 4-2 Access Point Port LED Signals LED Message Type Port link status Color Green Blinking Green Off Meaning Link on Link activity No link Verifying Controller Association To verify that your access point is associated to the controller, follow these steps:
Step 1 Step 2 Step 3 Log into your controller web interface using a web browser. You can also use the controller CLI show ap summary command from the controller console port. Click Wireless, and verify that your access point MAC address is listed under Ethernet MAC. Log out of the controller, and close your web browser. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4-6 Chapter 4 Troubleshooting R E V I E W D R A F T C I S C O C O N F I D E N T I A L Changing the Bridge Group Name Changing the Bridge Group Name The bridge group name (BGN) controls the association of the access points to a RAP. BGNs can be used to logically group the radios to avoid different networks on the same channel from communicating with each other. This setting is also useful if you have more than one RAP in your network in the same area. If you have two RAPs in your network in the same area (for more capacity), we recommend that you configure the two RAPs with different BGNs and on different channels. The BGN is a string of ten characters maximum. A factory-set bridge group name (NULL VALUE) is assigned during manufacturing. It is not visible to you, but allows new access point radios to join a network of new access points. The BGN can be reconfigured from the Controller CLI and GUI. After configuring the BGN, the access point reboots. After the access points are deployed and associated to the controller, the BGN should be changed from the default value to prevent the MAPs from attempting to associate to other mesh networks. The BGN should be configured very carefully on a live network. You should always start with the most distant access point (last node) from the RAP and move towards the RAP. If you start configuring the BGN in a different location, then the access points beyond this point (farther away) are dropped, as they have a different BGN. MAPS with unconfigured BGNs will periodically join to RAPs with configured BGNs. This prevents the stranding of MAPs. To configure the BGN for the access points using the controller GUI, follow these steps:
Step 1 Step 2 Step 3 Step 4 Step 5 Step 6 Step 7 Log into your controller using a web browser. Click Wireless. When access points associates to the controller, the access point name appears in the AP Name list. Click on an access point name. Find the Mesh Information section, and enter the new BGN in the Bridge Group Name field. Click Apply. Repeat Steps 2 through 5 for each access point. Log out from your controller, and close your web browser. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4-7 Changing the Bridge Group Name R E V I E W D R A F T C I S C O C O N F I D E N T I A L Chapter 4 Troubleshooting Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide 4-8 A P P E N D I X A Declarations of Conformity and Regulatory Information This appendix provides declarations of conformity and regulatory information for the Cisco Catalyst IW6300 Heavy Duty Series Access Point. This appendix contains the following sections:
Manufacturers Federal Communication Commission Declaration of Conformity Statement, page A-2
Industry Canada, page A-3
European Community, Switzerland, Norway, Iceland, and Liechtenstein, page A-4
Declaration of Conformity with regard to the R&TTE Directive 1999/5/EC & Medical Directive 93/42/EEC, page A-4
Declaration of Conformity for RF Exposure, page A-5
Guidelines for Operating Cisco Aironet Access Points in Japan, page A-6
Administrative Rules for Cisco Aironet Access Points in Taiwan, page A-8 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-1 Manufacturers Federal Communication Commission Declaration of Conformity Statement Appendix A Declarations of Conformity and Regulatory Information Manufacturers Federal Communication Commission Declaration of Conformity Statement Tested To Comply With FCC Standards FOR HOME OR OFFICE USE Models:
FCC Certification number:
IW-6300H-AC-X-K9 IW-6300H-DC-XK9 IW-6300H-DCW-X-K9 TBD Manufacturer:
Cisco Systems, Inc. 170 West Tasman Drive San Jose, CA 95134-1706 USA This device complies with Part 15 rules. Operation is subject to the following two conditions:
1. This device may not cause harmful interference, and 2. This device must accept any interference received, including interference that may cause undesired operation. This equipment has been tested and found to comply with the limits of a Class B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a residential environment. This equipment generates, uses, and radiates radio frequency energy, and if not installed and used in accordance with the instructions, may cause harmful interference. However, there is no guarantee that interference will not occur. If this equipment does cause interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to correct the interference by one of the following measures:
Reorient or relocate the receiving antenna.
Increase separation between the equipment and receiver.
Connect the equipment to an outlet on a circuit different from which the receiver is connected.
Consult the dealer or an experienced radio/TV technician. Caution The Part 15 radio device operates on a non-interference basis with other devices operating at this frequency when using Cisco-supplied antennas. Any changes or modification to the product not expressly approved by Cisco could void the users authority to operate this device. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-2 Appendix A Declarations of Conformity and Regulatory Information Industry Canada Caution To meet regulatory restrictions, the access point must be professionally installed. Industry Canada Models:
IC Certification Number:
IW-6300H-AC-X-K9 IW-6300H-DC-XK9 IW-6300H-DCW-X-K9 TBD Canadian Compliance Statement This Class B Digital apparatus meets all the requirements of the Canadian Interference-Causing Equipment Regulations. Cet appareil numerique de la classe B respecte les exigences du Reglement sur le material broilleur du Canada. This device complies with Class B Limits of Industry Canada. Operation is subject to the following two conditions:
1. This device may not cause harmful interference, and 2. This device must accept any interference received, including interference that may cause undesired operation. Cisco Aironet Access Points are certified to the requirements of RSS-210. The use of this device in a system operating either partially or completely outdoors may require the user to obtain a license for the system according to the Canadian regulations. For further information, contact your local Industry Canada office. The IW6300 device has been designed to operate with antennas having a maximum gain of 4 dBi for 2.4 GHz and 7 dBi for 5 GHz. Antennas having a gain greater are strictly prohibited for use with this device. The required antenna impedance is 50 ohms. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (EIRP) is not more than necessary for successful communication. Declaration of Conformity for RF Exposure This access point product has been found to be compliant to the requirements set forth in CFR 47 Section 1.1307 addressing RF Exposure from radio frequency devices as defined in Evaluating Compliance with FCC Guidelines for Human Exposure to Radio Frequency Electromagnetic Fields.T he antennas should be positioned more than 7.9 in (20 cm) from the body of all persons. This access point is also compliant to EN 50835 for RF exposure. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-3 European Community, Switzerland, Norway, Iceland, and Liechtenstein Appendix A Declarations of Conformity and Regulatory Information European Community, Switzerland, Norway, Iceland, and Liechtenstein Access Point Models:
IW-6300H-AC-X-K9 IW-6300H-DC-XK9 IW-6300H-DCW-X-K9 Declaration of Conformity with regard to the R&TTE Directive 1999/5/EC & Medical Directive 93/42/EEC This declaration is only valid for configurations (combinations of software, firmware, and hardware) provided and supported by Cisco Systems. The use of software or firmware not provided and supported by Cisco Systems may result in the equipment no longer being compliant with the regulatory requirements. The equipment is in compliance with the essential requirements and other relevant provisions of Directive 1999/5/EC. The following standards were applied:
EMCEN 301.489-1 v1.8.1; EN 301.489-17 v2.1.1 Health & SafetyEN60950-1: 2005; EN 50385: 2002 RadioEN 300 328 v 1.7.1; EN 301.893 v 1.5.1 The conformity assessment procedure referred to in Article 10.4 and Annex III of Directive 1999/5/EC has been followed. This device also conforms to the EMC requirements of the Medical Devices Directive 93/42/EEC. Note This equipment is intended to be used in all EU and EFTA countries. Outdoor use may be restricted to certain frequencies and/or may require a license for operation. For more details, contact Cisco Corporate Compliance. The product carries the CE Mark:
Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-4 Appendix A Declarations of Conformity and Regulatory Information Declaration of Conformity for RF Exposure Declaration of Conformity for RF Exposure The following is the declaration of conformity for RF exposure for the United States, Canada, European Union and Australia. United States Canada This system has been evaluated for RF exposure for Humans in reference to ANSI C 95.1 (American National Standards Institute) limits. The evaluation was based on ANSI C 95.1 and FCC OET Bulletin 65C rev 01.01. The minimum separation distance from the antenna to general bystander is 7.9 inches
(20cm) to maintain compliance. This system has been evaluated for RF exposure for Humans in reference to ANSI C 95.1 (American National Standards Institute) limits. The evaluation was based on RSS-102 Rev 2. The minimum separation distance from the antenna to general bystander is 7.9 inches (20cm) to maintain compliance. European Union This system has been evaluated for RF exposure for Humans in reference to the ICNIRP (International Commission on Non-Ionizing Radiation Protection) limits. The evaluation was based on the EN 50385 Product Standard to Demonstrate Compliance of Radio Base stations and Fixed Terminals for Wireless Telecommunications Systems with basic restrictions or reference levels related to Human Exposure to Radio Frequency Electromagnetic Fields from 300 MHz to 40 GHz. The minimum separation distance from the antenna to general bystander is 20cm (7.9 inches).Dual antennas used for diversity operation are not considered co-located. Australia This system has been evaluated for RF exposure for Humans as referenced in the Australian Radiation Protection standard and has been evaluated to the ICNIRP (International Commission on Non-Ionizing Radiation Protection) limits. The minimum separation distance from the antenna to general bystander is 20cm (7.9 inches). Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-5 Guidelines for Operating Cisco Aironet Access Points in Japan Appendix A Declarations of Conformity and Regulatory Information Guidelines for Operating Cisco Aironet Access Points in Japan This section provides guidelines for avoiding interference when operating Cisco Aironet access points in Japan. These guidelines are provided in both Japanese and English. Lightweight Access Point Model:
IW-6300H-AC-X-K9 IW-6300H-DC-XK9 IW-6300H-DCW-X-K9 Japanese Translation 03-6434-6500 8 6 7 3 4 English Translation This equipment operates in the same frequency bandwidth as industrial, scientific, and medical devices such as microwave ovens and mobile object identification (RF-ID) systems (licensed premises radio stations and unlicensed specified low-power radio stations) used in factory production lines. 1. Before using this equipment, make sure that no premises radio stations or specified low-power radio stations of RF-ID are used in the vicinity. 2. 3. If this equipment causes RF interference to a premises radio station of RF-ID, promptly change the frequency or stop using the device; contact the number below and ask for recommendations on avoiding radio interference, such as setting partitions. If this equipment causes RF interference to a specified low-power radio station of RF-ID, contact the number below. Contact Number: 03-6434-6500 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-6 Appendix A Declarations of Conformity and Regulatory Information Guidelines for Operating Cisco Aironet Access Points in Japan Japanese Translation English Translation Specific notes on Japan explosion-proof certification are as follows. 1. Use a heat-resistant cable of 65 degree or higher for various cables connected to the equipment. 2. This model uses the following cable gland / blind plug for the input / output port of this unit.
(TIIS Certified parts as of Jan/2017) For Cable ground of Fiber Port and PoE port Cable Grand: Ceftec Electric Co., Ltd. SFGU 10-M-ES Blind plug: Ceftec Electric Co., Ltd. PXN10-M20 3. Do not attach / detach the antenna in an explosive atmosphere or in a dangerous place. VCCI Statement for Japan Warning This is a Class B product based on the standard of the VCCI Council. If this equipment is used near a radio or television receiver in a domestic environment, it may cause radio interference. Install and use the equipment according to the instruction manual. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-7 Administrative Rules for Cisco Aironet Access Points in Taiwan Appendix A Declarations of Conformity and Regulatory Information Administrative Rules for Cisco Aironet Access Points in Taiwan This section provides administrative rules for operating Cisco Aironet Access Points in Taiwan. The rules are provided in both Chinese and English. Chinese Translation Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-8 Appendix A Declarations of Conformity and Regulatory Information Administrative Rules for Cisco Aironet Access Points in Taiwan English Translation Administrative Rules for Low-power Radio-Frequency Devices Article 12 For those low-power radio-frequency devices that have already received a type-approval, companies, business units or users should not change its frequencies, increase its power or change its original features and functions. Article 14 The operation of the low-power radio-frequency devices is subject to the conditions that no harmful interference is caused to aviation safety and authorized radio station; and if interference is caused, the user must stop operating the device immediately and can't re-operate it until the harmful interference is clear. The authorized radio station means a radio-communication service operating in accordance with the Communication Act. The operation of the low-power radio-frequency devices is subject to the interference caused by the operation of an authorized radio station, by another intentional or unintentional radiator, by industrial, scientific and medical (ISM) equipment, or by an incidental radiator. Chinese Translation English Translation Low-power Radio-frequency Devices Technical Specifications 4.7 Unlicensed National Information Infrastructure 4.7.6 The U-NII devices shall accept any interference from legal communications and shall not interfere the legal communications. If interference is caused, the user must stop operating the device immediately and can't re-operate it until the harmful interference is clear. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-9 Administrative Rules for Cisco Aironet Access Points in Taiwan Appendix A Declarations of Conformity and Regulatory Information 4.7.7 Manufacturers of U-NII devices are responsible for ensuring frequency stability such that an emission is maintained within the band of operation under all conditions of normal operation as specified in the user manual. Taiwan NCC Statement English Translation This product cannot be used unless installed and setup by professional staff, and may not be sold directly to the general consumer. Chinese Translation English Translation MPE standard value is 1mW / CM2, the assessment result is 0.19mW/CM2. Chinese Translation EU Declaration of Conformity All the Declaration of Conformity statements related to this product can be found at the following location:
http://www.ciscofax.com Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide A-10 A P P E N D I X B Access Point Specifications The following table lists the technical specifications for the Cisco Catalyst IW6300 Heavy Duty Series Access Points. For detailed specifications, refer to the Cisco Catalyst IW6300 Heavy Duty Series Access Point data sheet at:
https://www.cisco.com/c/en/us/products/collateral/wireless/industrial-wireless-6300-series/datasheet-c 78-742907.html Table B-1 Access Point Specifications Category Size Weight Antenna connectors Power sources Ethernet connectors IW-6300H-DC-XK9 9.7 in. x 11 in. x 3.8 in. (24.2 cm x 28 cm x 9.65 cm) 9.8 lbs (4.45 kg) IW-6300H-AC-X-K9 9.7 in. x 11 in. x 5.6 in. (24.7 cm x 28 cm x 14.2 cm) 13.3 lbs (6.03 kg) Four Type N antenna connectors for 2.4 GHz radio and 5 GHz 802.11ac radio (depends on configuration) 100 to 240 VAC, 1.3A,5060 Hz
One 100/1000M SFP for WAN IW-6300H-DCW-X-K9 9.7 in. x 11 in. x 5.6 in. (24.7 cm x 28 cm x 14.2 cm) 12.7 lbs (5.76 kg) 10.8 to 36Vdc, 5.9A 44 to 57VDC, 1.2A
One 10/100/1000M RJ45 for WAN (UPoE or PoE+ in) Operating temperature Storage temperature Humidity Environmental ratings UL 50E (type 4X)
Two 10/100/1000M RJ45 for LAN (802.11at or 802.3af out)
-50 to 75C (-58 to 167F) without solar loading, still air, and cold start limited to -40C
-40 to 85C (-40 to 185F) 10 to 90% noncondensing Wind resistance EN/IEC 60529 (IP66 and IP67) UL/CSA/IEC 60950-22 outdoor rating Wind resistance:
Up to 100 MPH sustained winds
Up to 165 MPH wind gusts Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide B-1 Appendix B Access Point Specifications Table B-1 Access Point Specifications (continued) Category WW EMC-Emissions:
IW-6300H-AC-X-K9 FCC 47 CFR Part 15B CLASS: A ICES-003 Issue 6: 2016 CISPR 22 EN 55022 CISPR32 Edition 2 EN 55032:2015 IW-6300H-DC-XK9 IW-6300H-DCW-X-K9 EN 61000-3-2: 2014 (Applicable to IW-6300H-AC-X-K9 only) EN 61000-3-3:2013 (Applicable to IW-6300H-AC-X-K9 only) WW EMC-Immunity Radio (Wi-Fi) VCCI CLASS A AS/NZ CISPR32 CISPR24: 2010 + A1: 2015 EN 55024: 2010 + A1: 2015 CISPR35, EN 55035 EN 300386 V1.6.1 FCC Part 15.247, 15.407 FCC 2.1091 RSS - 247 RSS-102 AS/NZS 4268 2017 MIC Article 2 paragraph 1 item (19)-2,3,3-2 KCC Notice No. 2013-1 EN 300 328 v2.1.1, v1.9.1, v1.8.1 EN 301 893 v2.1.1, v1.8.1, v1.7.1 EN 62311 LP0002: 2018 Regulatory Domain Support:
FCC (Americas Middle East, Africa, and parts of Asia) ETSI (Europe, Middle East, Africa, and parts of Asia) Radio EMC TELEC (Japan) KCC (Korea) EN 301 489 17 KN 301 489 17 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide B-2 Appendix B Access Point Specifications Table B-1 Access Point Specifications (continued) Category Safety Ingress (water and dust) Protection IW-6300H-AC-X-K9 UL/CSA/EN/IEC 60950-1:2016 +A1:2010 +A11:2009 +A12:2011 +A2:2013 IW-6300H-DC-XK9 IW-6300H-DCW-X-K9 IEC 60950-1 UL/CSA/EN/IEC 62368-1 UL 50E (type 4X) EN/IEC 60529 (IP66 and IP67) UL/CSA/IEC 60950-22 Outdoor rating The following table lists the power distribution budget for the IW-6300H access point configurations. Table B-2 Power Consumption Budget for the IW-6300H Access Point Configurations Power Options Ambient Temperature AC Power input
(85V-264V) 80 5G UP: 0.01M DC Power input
(44V-57V) 80 5G UP: 0.01M DCW Power input
(10.8-36V) 80 5G UP: 0.01M UPOE Power input on AC Hazloc SKU 80 5G UP: 0.01M 5G DOWN: 500M 5G DOWN: 500M 5G DOWN: 500M 5G DOWN: 500M 2.4G DOWN: 50M 2.4G DOWN: 50M 2.4G DOWN: 50M 2.4G DOWN: 50M 2.4G UP: 0.001M 2.4G UP: 0.01M 2.4G UP: 0.01M 2.4G UP: 0.01M Traffic Configuration 4.5W USB Load POE load (W) Input Voltage (V) Input Current (A) Input Power Consumption (W) LAN: 4x1M Yes 0+29.9 85VAC 1.347 63.546 No 0+29.9 85VAC 1.254 57.854 LAN: 4x1M Yes 24.7+0 44VDC 1.140 50.142 No 24.7+0 44VDC 1.056 46.477 LAN: 4x1M Yes 0+30.6 12VDC 5.350 64.205 No 0+30.7 12VDC 4.822 57.865 No OFF LAN: 4x1M Yes OFF 55.29VDC 55.48VDC 0.531 29.371 0.450 24.938 Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide B-3 Appendix B Access Point Specifications Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide B-4 A P P E N D I X C Access Point Pinouts This appendix describes the pin signals of the access point Ethernet connectors, and the power injector input and output connectors. The following table describes the pin signals of the access point PoE Out connector. Table C-1 Access Point PoE Out Ethernet Connector Pinouts Pin Number 1 2 3 6 4 5 7 8 Shield Signal Name Ethernet signal pair (10/100/1000BASE-T) and VDC return Ethernet signal pair (10/100/1000BASE-T) and VDC (+) Ethernet signal pair (10/100/1000BASE-T) Ethernet signal pair (10/100/1000BASE-T) Chassis ground The following table describes the pin signals for the access point PoE In Ethernet connector. Table C-2 Access Point PoE In Ethernet Connector Pinouts Pin Number 1 2 3 6 4 5 7 8 Shield Signal Name Ethernet signal pair (10/100/1000BASE-T) and VDC return Ethernet signal pair (10/100/1000BASE-T) and VDC (+) Ethernet signal pair (1000BASE-T) and VDC (+) Ethernet signal pair (1000BASE-T) and VDC return Chassis ground Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide C-1 Appendix C Access Point Pinouts The following table describes the pin signals for the power injector input connector (To Switch). Table C-3 Power Injector AIR-PWRINJ-60RGD1= and AIR-PWRINJ-60RGD2= Input Connector (To Switch) Pinouts Pin Number 1 2 3 6 4 5 7 8 Shield Signal Name Ethernet signal pair (10/100/1000BASE-T) Ethernet signal pair 10/100/1000BASE-T) Ethernet signal pair (1000BASE-T) Ethernet signal pair (1000BASE-T) Chassis ground The following table describes the RJ-45 pin signals for the power injector output connector (To AP). Table C-4 Power Injector AIR-PWRINJ-60RGD1= and AIR-PWRINJ-60RGD2= Output Connector
(To AP) Pinouts Pin Number 1 2 3 6 4 5 7 8 Shield Signal Name Ethernet signal pair (10/100/1000BASE-T) and 55 VDC return Ethernet signal pair (10/100/1000BASE-T) and 55 VDC (+) Ethernet signal pair (1000BASE-T) and 55 VDC (+) Ethernet signal pair (1000BASE-T) and 55 VDC return Chassis ground Note The power injector output connector (To AP) only supplies 55 VDC power when the Ethernet cable is connected to the IW6300 PoE IN connector. Cisco Catalyst IW6300 Heavy Duty Series Access Point Hardware Installation Guide C-2
1 2 3 4 5 6 | Int Photos | Internal Photos | 1.38 MiB | September 12 2019 |
Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 Internal view with first cover removed. This is the radio board top side. Radio board removed from casing showing top side. Radio board removed from casing showing bottom side. Second casing top cover removed to expose module motherboard top side. Motherboard removed from the bottom casing showing top side. Motherboard removed from casing showing bottom side view. END
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Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 External Top View External Left Side View External Right Side View External Top Side View External Bottom View END
1 2 3 4 5 6 | Host Integration | External Photos | 1.71 MiB | September 12 2019 |
Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 Dec 3, 2019 Subject: LDKESW6300 Limited Modular Approval, Internal and External Product photos Dear Regulatory Authority, This document covers the internal and external photos of the product that the LDKESW6300 module is incorporated into. Sincerely yours,
-----------------------------------
Adam Walb / Manager, Compliance Cisco Systems Inc Tel: 408-526-4124 E-mail: awalb@cisco.com Product External Top View Product bottom side view Shows external access ports Product right side view Product top side view (shows location of antenna ports) Note that antenna ports are labeled B, C, D, A Product left side view Product bottom side view Product top view with access hatch removed Product top cover removed to expose the LDKESW6300 LMA module Closer view of the LDKESW6300 module in the product LDKESW6300 removed from the product showing only the bottom inside casing. Product bottom casing next to the LDKESW6300 module END
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Radio Test Report No: EDCS 18429929 Test Report IW-6300H Series Access Point Cisco Industrial Wireless Hazardous Location Access Point FCC ID: LDKESW6300 IC ID: 2461D-ESW6300 5470-5725 MHz Outside Antennas, 13dBi Gain Against the following Specifications:
CFR47 Part 15.407 RSS-247 Cisco Systems 170 West Tasman Drive San Jose, CA 95134 Approved By: Adam Walb Title: MGR. IoT Compliance Revision: 1.0 Author: Julian Land Tested By: Julian Land This report replaces any previously entered test report under EDCS 18429929.This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. Test Report Template EDCS# 11644124. Page No: 1 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. SECTION 1: OVERVIEW ......................................................................................................................................... 3 SECTION2: ASSESSMENT INFORMATION ........................................................................................................ 4 2.1 GENERAL ............................................................................................................................................................. 4 2.2 DATE OF TESTING................................................................................................................................................. 6 2.3 REPORT ISSUE DATE ............................................................................................................................................ 6 2.4 TESTING FACILITIES ............................................................................................................................................. 6 2.5 EQUIPMENT ASSESSED (EUT) .............................................................................................................................. 6 2.6 EUT DESCRIPTION ............................................................................................................................................... 7 SECTION 3: RESULT SUMMARY ........................................................................................................................ 10 3.1 RESULTS SUMMARY TABLE ............................................................................................................................... 10 SECTION 4: SAMPLE DETAILS ........................................................................................................................... 11 4.1 SAMPLE DETAILS ............................................................................................................................................... 11 4.2 SYSTEM DETAILS ............................................................................................................................................... 11 4.3 MODE OF OPERATION DETAILS .......................................................................................................................... 11 APPENDIX A: EMISSION TEST RESULTS ........................................................................................................ 12 CONDUCTED TEST SETUP DIAGRAM ........................................................................................................................ 12 TARGET MAXIMUM CHANNEL POWER .................................................................................................................... 12 A.1 DUTY CYCLE .................................................................................................................................................... 14 A.2 99% AND 26DB BANDWIDTH ............................................................................................................................ 17 A.3 MAXIMUM CONDUCTED OUTPUT POWER ......................................................................................................... 21 A.4 POWER SPECTRAL DENSITY .............................................................................................................................. 29 A.5 CONDUCTED SPURIOUS EMISSIONS ................................................................................................................... 36 A.6 CONDUCTED BANDEDGE ................................................................................................................................... 47 APPENDIX B:
LIST OF TEST EQUIPMENT USED TO PERFORM THE TEST .................................... 54 APPENDIX C: ABBREVIATION KEY AND DEFINITIONS ............................................................................. 55 APPENDIX D:
PHOTOGRAPHS OF TEST SETUPS ................................................................................... 56 APPENDIX E:
SOFTWARE USED TO PERFORM TESTING ................................................................... 59 APPENDIX F:
TEST PROCEDURES ............................................................................................................. 60 APPENDIX G: SCOPE OF ACCREDITATION (A2LA CERTIFICATE NUMBER 1178-01) ........................ 61 Page No: 2 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Section 1: Overview The samples were assessed against the tests detailed in section 3 under the requirements of the following specifications:
Specifications:
CFR47 Part 15.407 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 3 of 61 b) c) d) e) Radio Test Report No: EDCS 18429929 Section2: Assessment Information 2.1 General This report contains an assessment of an apparatus against Electromagnetic Compatibility Standards based upon tests carried out on the samples submitted. The testing was performed by and for the use of Cisco systems Inc:
With regard to this assessment, the following points should be noted:
a) The results contained in this report relate only to the items tested and were obtained in the period between the date of the initial assessment and the date of issue of the report. Manufactured products will not necessarily give identical results due to production and measurement tolerances. The apparatus was set up and exercised using the configuration and modes of operation defined in this report only. Where relevant, the apparatus was only assessed using the susceptibility criteria defined in this report and the Test Assessment Plan (TAP). All testing was performed under the following environmental conditions:
Temperature 15C to 35C (54F to 95F) Atmospheric Pressure 860mbar to 1060mbar (25.4" to 31.3") Humidity 10% to 75*%
All AC testing was performed at one or more of the following supply voltages:
110V 60 Hz (+/-20%) Units of Measurement The units of measurements defined in the appendices are reported in specific terms, which are test dependent. Where radiated measurements are concerned these are defined at a particular distance. Basic voltage measurements are defined in units of [dBuV]
As an example, the basic calculation for all measurements is as follows:
The combinations of correction factors are dependent upon the exact test configurations [see test equipment lists for further details] and may include:-
Emission level [dBuV] = Indicated voltage level [dBuV] + Cable Loss [dB] + Other correction factors [dB]
Antenna Factors, Pre Amplifier Gain, LISN Loss, Pulse Limiter Loss and Filter Insertion Loss Note: to convert the results from dBuV/m to uV/m use the following formula:-
Level in uV/m = Common Antilogarithm [(X dBuV/m)/20] = Y uV/m This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 4 of 61 Radio Test Report No: EDCS 18429929 Measurement Uncertainty Values voltage and power measurements 2 dB conducted EIRP measurements 1.4 dB radiated measurements 3.2 dB frequency measurements 2.4 10-7 temperature measurements humidity measurements 0.54 2.3%
DC and low frequency measurements 2.5%
Where relevant measurement uncertainty levels have been estimated for tests performed on the apparatus. This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2. Radiated emissions (expanded uncertainty, confidence interval 95%) 30 MHz - 300 MHz 300 MHz - 1000 MHz 1 GHz - 10 GHz 10 GHz - 18GHz 18GHz - 26.5GHz 26.5GHz - 40GHz
+/- 3.8 dB
+/- 4.3 dB
+/- 4.0 dB
+/- 8.2 dB
+/- 4.1 dB
+/- 3.9 dB Conducted emissions (expanded uncertainty, confidence interval 95%) A product is considered to comply with a requirement if the nominal measured value is below the limit line. The product is considered to not be in compliance in case the nominal measured value is above the limit line. 30 MHz 40GHz
+/- 0.38 dB This report must not be reproduced except in full, without written approval of Cisco Systems. Page No: 5 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 2.2 Date of testing 20-Nov-19 - 21-Nov-19 2.3 Report Issue Date 9/23/2019 Cisco uses an electronic system to issue, store and control the revision of test reports. This system is called the Engineering Document Control System (EDCS). The actual report issue date is embedded into the original file on EDCS. Any copies of this report, either electronic or paper, that are not on EDCS must be considered uncontrolled. 2.4 Testing facilities This assessment was performed by:
Testing Laboratory Cisco Systems, Inc. 125 West Tasman Drive (Building P) San Jose, CA 95134 USA Headquarters Cisco Systems, Inc., 170 West Tasman Drive San Jose, CA 95134, USA Registration Numbers for Industry Canada Cisco System Site Address Building P, 10m Chamber Building P, 5m Chamber Building I, 5m Chamber 125 West Tasman Dr San Jose, CA 95134 125 West Tasman Dr San Jose, CA 95134 285 W. Tasman Drive San Jose, California 95134 Site Identifier Company #: 2461N-2 Company #: 2461N-1 Company #: 2461M-1 Building 7, 5m Chamber 425 E. Tasman Drive Company #: 2461N-3 San Jose, California 95134 Test Engineers Julian Land 2.5 Equipment Assessed (EUT) IW 6300H Page No: 6 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 2.6 EUT Description The radio supports the following modes of operation. The modes are further defined in the radio Theory of Operation. The modes included in this report represent the worst case data for all modes. 802.11a - Non HT20, Two Antennas, 6 to 54 Mbps, 1ss 802.11a - Non HT20 Beam Forming, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT20, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT40, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT40, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT40, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT80, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT80, Two Antennas, 6 to 54 Mbps, 1ss 802.11ac - VHT80, One Antenna, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 1ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 STBC, Two Antennas, M0 to M9 2ss 802.11a - Non HT20, One Antenna, 6 to 54 Mbps, 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 7 of 61 Radio Test Report No: EDCS 18429929 Model / PID Differences IW-6300H-AC-x-K9, IW-6300H-DC-x-K9, IW-6300-DCW-x-K9 and ESW-6300-CON-x-K9, all have the same identical components, electronics circuitries, PCB layout and enclosure. The only differences are listed as below:
IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300-DCW-x-K9 ESW-6300-CON-x-K9 Where x can be replaced with another letter to indicate country domain. Domain letters: A, B, C, D, E, F, H, I, L, M, N, Q, R, S, T, Z Where AC is Alternating Current (AC power supply) Where DC is Direct Current (DC power supply), 54V native input Where DCW is Direct Current; wide range 10-36VDC Where K9 is encryption software. This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 8 of 61 Radio Test Report No: EDCS 18429929 The following antennas are supported by this product series. The data included in this report represent the worst case data for all antennas. Frequency Part Number AIR-ANT2450V-N Antenna Type Single Band Omni AIR-ANT2450V-N-HZ Single Band Omni, Hazloc 2.4 GHz AIR-ANT2480V-N AIR-ANT2450HG-N AIR-ANT2450VG-N AIR-ANT2413P2M-N Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni Single Band, Dual Polarized Directional Patch 5 GHz 2.4/5 GHz Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni AIR-ANT5180V-N AIR-ANT5150HG-N AIR-ANT5150VG-N AIR-ANT5114P2M-N AIR-ANT2547V-N=
AIR-ANT2547VG-N= Dual-band Omni, Gray AIR-ANT2547V-N-HZ= Dual-band Omni, Hazloc Dual-band Omni Single Band, Dual Polarized Directional Patch AIR-ANT2568VG-N AIR-ANT2588P3M-N= Dual-band/Dual Polarized Directional, Patch AIR-ANT2513P4M-N Dual-band Polarization Diverse Patch Array Dual-band Omni
>30 degree 5 GHz Antenna Gain
(dBi) NA NA NA NA NA NA
-3
-5
-6 5
-6
-6
-6 3 1
-5 Antenna Gain
(dBi) 5 5 8 5 5 13 8 5 5 13 4 / 7 4 / 7 4 / 7 6 / 8 8 / 8 13 / 13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 9 of 61 Radio Test Report No: EDCS 18429929 Section 3: Result Summary 3.1 Results Summary Table Conducted emissions Basic Standard FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.209 FCC 15.205 Technical Requirements / Details 99% & 26 dB Bandwidth:
The 99% occupied bandwidth is the frequency bandwidth such that, below its lower and above its upper frequency limits, the mean powers are each equal to 0.5% of the total mean power of the given emission. There is no limit for 99% OBW. The 26 dB emission is the width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 26 dB relative to the maximum level measured in the fundamental emission. Output Power:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Power Spectral Density:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bandsthe maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Conducted Spurious Emissions / Band-Edge:
15.407 (3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz. Restricted band:
Unwanted emissions falling within the restricted bands, as defined in FCC 15.205 (a) must also comply with the radiated emission limits specified in FCC 15.209 (a). Result Pass Pass Pass Pass Pass Radiated Emissions (General requirements) Basic Standard FCC 15.209 FCC 15.205 FCC 15.207 Technical Requirements / Details TX Spurious Emissions:
Except as provided elsewhere in this subpart, the emissions from an intentional radiator shall not exceed the field strength levels specified in the filed strength limits table in this section. AC conducted Emissions:
Except when the requirements applicable to a given device state otherwise, for any radio apparatus equipped to operate from the public utility AC power supply, either directly or indirectly (such as with a battery charger), the radio frequency voltage of emissions conducted back onto the AC power lines in the frequency range of 0.15 MHz to 30 MHz shall not exceed the limits shown in the table in these sections. The more stringent limit applies at the frequency range boundaries. Result Pass Pass Page No: 10 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Section 4: Sample Details Note: Each sample was evaluated to ensure that its condition was suitable to be used as a test sample prior to the commencement of testing. 4.1 Sample Details Sample No. S01 S02 Equipment Details Manufacturer Hardware Rev. Firmware Rev. Software Rev. Serial Number IW-6300H-DC-B-K9 FSP150-AWAN3 Cisco Systems, Inc. FSP Group Inc. 11
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9.1.8.1 9.0.5.5-W8964 FOC23241G16
-
-
H00000063 4.2 System Details System #
1 EUT and Power Supply 4.3 Mode of Operation Details Mode#
Description Description Samples S01, S02 Comments 1 Continuous Transmitting Continuous Transmitting 98% duty cycle All measurements were made in accordance with ANSI C63.10:2013 KDB 789033 D02 General UNII Test Procedures New Rules v01r03 KDB 662911 D01 Multiple Transmitter Output v02r01 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 11 of 61 Radio Test Report No: EDCS 18429929 Appendix A: Emission Test Results Conducted Test Setup Diagram Target Maximum Channel Power The following table details the maximum supported Total Channel Power for all operating modes. Operating Mode Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M15 HT/VHT20 Beam Forming, M0 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 HT/VHT40 Beam Forming, M0 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss VHT80 Beam Forming, M0 to M9, M0 to M9 1-2ss Maximum Channel Power
(dBm) Frequency (MHz) 5500 14 14 14 14 14 5510 14 13 13 13 5530 11 13 13 5560 14 14 14 14 14 5550 15 15 14 14 5610 15 16 16 5700 15 15 15 15 15 5710 17 17 16 16 5690 15 17 17 Page No: 12 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 VHT80 STBC, M0 to M9 1ss 13 16 17 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 13 of 61 Radio Test Report No: EDCS 18429929 A.1 Duty Cycle Duty Cycle Test Requirement From KDB 789033 D02 General UNII Test Procedures New Rules v02r01 B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level 1. All measurements are to be performed with the EUT transmitting at 100 percent duty cycle at its maximum power control level; however, if 100 percent duty cycle cannot be achieved, measurements of duty cycle, x, and maximum-power transmission duration, T, are required for each tested mode of operation. Duty Cycle Test Method From KDB 789033 D02 General UNII Test Procedures New Rules v02r01:
B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level The zero-span mode on a spectrum analyzer or EMI receiver, if the response time and spacing between bins on the sweep are sufficient to permit accurate measurements of the on and off times of the transmitted signal. Set the center frequency of the instrument to the center frequency of the transmission. Set RBW EBW if possible; otherwise, set RBW to the largest available value. Set VBW RBW. Set detector = peak or average. The zero-span measurement method shall not be used unless both RBW and VBW are > 50/T, where T is defined in section II.B.1.a), and the number of sweep points across duration T exceeds 100. (For example, if VBW and/or RBW are limited to 3 MHz, then the zero-span method of measuring duty cycle shall not be used if T 16.7 microseconds.) Duty Cycle Test Information Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix C for list of test equipment Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Date of testing:
20-Nov-19 - 21-Nov-19 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 14 of 61 Radio Test Report No: EDCS 18429929 Duty Cycle Data Table Duty Cycle table and screen captures are shown below for power/psd modes. Frequency Mode Data Rate 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 Duty Cycle correction
(dB) 0.0 0.0 0.0 0.1 0.0 0.2 0.0 0.1 0.0 0.0 0.0 0.2 0.0 0.2 0.0 0.0 0.0 0.1 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 15 of 61 Radio Test Report No: EDCS 18429929 Duty Cycle, 5530 MHz, VHT80, M0 to M9, M0 to M9 1-2ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 16 of 61 Radio Test Report No: EDCS 18429929 A.2 99% and 26dB Bandwidth 99% and 26dB Bandwidth Test Requirement There is no requirement for the value of bandwidth. However, the 26dB BW (EBW) is used to calculate the power limits in 15.407 (a) (2). Power measurements are made using the 99% Bandwidth as the integration bandwidth. Band-crossing emissions: For an emission that crosses the boundary between two adjacent U-NII bands, the boundary frequency between the bands serves as one edge for defining the portion of the EBW that falls within a particular U-NII band. However, the -26 dB points are measured relative to the highest point on the contiguous segmentregardless of which band contains that highest point (Figure4). 99% and 26dB Bandwidth Test Procedure Ref. KDB 789033 Section D. 99 Percent Occupied Bandwidth ANSI C63.10: 2013 Section 6.9.3 KDB 662911 99% BW Test Parameters 1. Set center frequency to the nominal EUT channel center frequency. 2. Set span = 1.5 times to 5.0 times the OBW. 3. Set RBW = 1 % to 5 % of the OBW 4. Set VBW 3 RBW 5. Video averaging is not permitted. Where practical, a sample detection and single sweep mode shall be used. Otherwise, peak detection and max hold mode (until the trace stabilizes) shall be used. 6. Use the 99 % power bandwidth function of the instrument (if available). Ref KDB 789033 in Section C. Measurement Bandwidth, Section 1 26 BW Test parameters X dB BW = -26dB (using the OBW function of the spectrum analyzer) Emission Bandwidth (EBW) a) Set RBW = approximately 1% of the emission bandwidth. b) Set the VBW > RBW. c) Detector = Peak. d) Trace mode = max hold. e) Measure the maximum width of the emission that is 26 dB down from the maximum of the emission. Page No: 17 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Compare this with the RBW setting of the analyzer. Readjust RBW and repeat measurement as needed until the RBW/EBW ratio is approximately 1%. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
Start Date to Finish Date here Page No: 18 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 99% and 26dB Bandwidth Table Frequency
(MHz) 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Mode Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Data Rate 26dB BW 99% BW
(Mbps)
(MHz) 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 19.7 20.3 42.7 40.7 82.5 82.5 41.1 40.7 19.8 20.2 82.8 82.5 82.1 83.2 19.7 20.5 42.2 40.9 14.9 15.2
(MHz) 16.610 17.646 36.375 36.258 76.371 76.393 36.414 36.224 16.609 17.643 76.392 76.490 76.361 76.377 16.610 17.640 36.394 36.194 13.293 13.800 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 19 of 61 Radio Test Report No: EDCS 18429929 26dB / 99% Bandwidth, 5720 MHz, Non HT20, 6 to 54 Mbps This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 20 of 61 Radio Test Report No: EDCS 18429929 A.3 Maximum Conducted Output Power Maximum Conducted Output Power Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Maximum Conducted Output Power Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 ANSI C63.10: 2013 Maximum Conducted Output Power Test Procedure 1. Set the radio in the continuous transmitting mode at full power 2. Compute power by integrating the spectrum across the EBW (or alternatively entire 99% OBW) of the signal using the instruments band power measurement function. The integration shall be performed using the spectrum analyzer band-power measurement function with band limits set equal to the EBW or the Page No: 21 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 OBW band edges. 3. Capture graphs and record pertinent measurement data. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Measurement using a Spectrum Analyzer or EMI Receiver (SA), (d) Method SA-2 Maximum Conducted Output Power Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 System under Support test equipment Date of testing:
Start Date to Finish Date here Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 22 of 61 Radio Test Report No: EDCS 18429929 Maximum Output Power
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n g r a M i Non HT20, 6 to 54 Mbps 1 13 13.7 0.0 13.7 Non HT20, 6 to 54 Mbps 2 13 11.7 10.6 0.0 14.2 Non HT20 Beam Forming, 6 to 54 Mbps 2 13 11.7 10.6 0.0 14.2 HT/VHT20, M0 to M7 1 13 13.8 0.0 13.8 HT/VHT20, M0 to M7 2 13 11.8 10.8 0.0 14.4 HT/VHT20, M8 to M15 2 13 11.8 10.8 0.0 14.4 HT/VHT20 Beam Forming, M0 to M7 2 13 11.8 10.8 0.0 14.4 HT/VHT20 Beam Forming, M8 to M15 2 13 11.8 10.8 0.0 14.4 HT/VHT20 STBC, M0 to M7 2 13 11.8 10.8 0.0 14.4 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 Non HT40, 6 to 54 Mbps 1 13 13.5 0.0 13.5 Non HT40, 6 to 54 Mbps 2 13 9.5 8.5 0.0 12.1 HT/VHT40, M0 to M7 1 13 12.3 0.1 12.4 HT/VHT40, M0 to M7 2 13 10.0 9.2 0.1 12.7 HT/VHT40, M8 to M15 2 13 10.0 9.2 0.1 12.7 HT/VHT40 Beam Forming, M0 to M7 2 13 10.0 9.2 0.1 12.7 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 Page No: 23 of 61 0 1 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 3.27 2.77 2.77 3.16 2.62 2.62 2.62 2.62 2.62 3.47 4.93 4.65 4.32 4.32 4.32 Radio Test Report No: EDCS 18429929 0 3 5 5 HT/VHT40 Beam Forming, M8 to M15 2 13 10.0 9.2 0.1 12.7 HT/VHT40 STBC, M0 to M7 2 13 10.0 9.2 0.1 12.7 17. 0 17. 0 4.32 4.32 Non HT80, 6 to 54 Mbps 1 13 11.3 0.0 11.3 Non HT80, 6 to 54 Mbps 2 13 5.5 4.7 0.0 8.2 VHT80, M0 to M9 1ss 1 13 11.8 0.2 12.0 VHT80, M0 to M9 1ss 2 13 9.7 9.0 0.2 12.6 VHT80, M0 to M9 2ss 2 13 9.7 9.0 0.2 12.6 VHT80 Beam Forming, M0 to M9 1ss 2 13 9.7 9.0 0.2 12.6 VHT80 Beam Forming, M0 to M9 2ss 2 13 9.7 9.0 0.2 12.6 VHT80 STBC, M0 to M9 1ss 2 13 9.7 9.0 0.2 12.6 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 Non HT40, 6 to 54 Mbps 1 13 15.1 0.0 15.1 Non HT40, 6 to 54 Mbps 2 13 9.2 9.0 0.0 12.1 HT/VHT40, M0 to M7 1 13 15.2 0.1 15.3 HT/VHT40, M0 to M7 2 13 11.0 10.9 0.1 14.0 0 5 5 5 HT/VHT40, M8 to M15 2 13 11.0 10.9 0.1 14.0 HT/VHT40 Beam Forming, M0 to M7 2 13 11.0 10.9 0.1 14.0 HT/VHT40 Beam Forming, M8 to M15 2 13 11.0 10.9 0.1 14.0 5.67 8.84 5.01 4.44 4.44 4.44 4.44 4.44 1.87 4.86 1.75 2.99 2.99 2.99 2.99 2.99 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 HT/VHT40 STBC, M0 to M7 5 5 6 0 Non HT20, 6 to 54 Mbps 2 1 13 11.0 10.9 0.1 14.0 13 13.6 0.0 13.6 17. 3.37 Page No: 24 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Non HT20, 6 to 54 Mbps 2 13 10.6 10.9 0.0 13.8 Non HT20 Beam Forming, 6 to 54 Mbps 2 13 10.6 10.9 0.0 13.8 HT/VHT20, M0 to M7 1 13 13.7 0.0 13.7 HT/VHT20, M0 to M7 2 13 10.8 11.1 0.0 14.0 HT/VHT20, M8 to M15 2 13 10.8 11.1 0.0 14.0 HT/VHT20 Beam Forming, M0 to M7 2 13 10.8 11.1 0.0 14.0 HT/VHT20 Beam Forming, M8 to M15 2 13 10.8 11.1 0.0 14.0 HT/VHT20 STBC, M0 to M7 2 13 10.8 11.1 0.0 14.0 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 Non HT80, 6 to 54 Mbps 1 13 11.6 0.0 11.6 Non HT80, 6 to 54 Mbps 2 13 11.6 11.7 0.0 14.7 VHT80, M0 to M9 1ss 1 13 16.3 0.2 16.5 VHT80, M0 to M9 1ss 2 13 13.1 13.0 0.2 16.3 0 1 6 5 VHT80, M0 to M9 2ss 2 13 13.1 13.0 0.2 16.3 VHT80 Beam Forming, M0 to M9 1ss 2 13 13.1 13.0 0.2 16.3 VHT80 Beam Forming, M0 to M9 2ss 2 13 13.1 13.0 0.2 16.3 VHT80 STBC, M0 to M9 1ss 2 13 13.1 13.0 0.2 16.3 Non HT80, 6 to 54 Mbps 1 13 14.1 0.0 14.1 Non HT80, 6 to 54 Mbps 2 13 11.7 11.2 0.0 14.5 0 9 6 5 VHT80, M0 to M9 1ss 1 13 15.9 0.2 16.1 VHT80, M0 to M9 1ss 2 13 13.9 13.6 0.2 17.0 VHT80, M0 to M9 2ss 2 13 13.9 13.6 0.2 17.0 17. 0 17. 0 17. 0 17. 0 17. 0 This document is uncontrolled. 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Company Confidential Page No: 25 of 61 3.20 3.20 3.26 2.99 2.99 2.99 2.99 2.99 5.37 2.31 0.51 0.75 0.75 0.75 0.75 0.75 2.87 2.50 0.91 0.05 0.05 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 Radio Test Report No: EDCS 18429929 VHT80 Beam Forming, M0 to M9 1ss 2 13 13.9 13.6 0.2 17.0 VHT80 Beam Forming, M0 to M9 2ss 2 13 13.9 13.6 0.2 17.0 VHT80 STBC, M0 to M9 1ss 2 13 13.9 13.6 0.2 17.0 17. 0 17. 0 17. 0 Non HT20, 6 to 54 Mbps 1 13 14.1 0.0 14.1 Non HT20, 6 to 54 Mbps 2 13 10.9 12.0 0.0 14.5 Non HT20 Beam Forming, 6 to 54 Mbps 2 13 10.9 12.0 0.0 14.5 HT/VHT20, M0 to M7 1 13 14.3 0.0 14.3 0 0 7 5 HT/VHT20, M0 to M7 2 13 11.0 12.2 0.0 14.7 HT/VHT20, M8 to M15 2 13 11.0 12.2 0.0 14.7 HT/VHT20 Beam Forming, M0 to M7 2 13 11.0 12.2 0.0 14.7 HT/VHT20 Beam Forming, M8 to M15 2 13 11.0 12.2 0.0 14.7 HT/VHT20 STBC, M0 to M7 2 13 11.0 12.2 0.0 14.7 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 Non HT40, 6 to 54 Mbps 1 13 16.7 0.0 16.7 Non HT40, 6 to 54 Mbps 2 13 12.8 13.2 0.0 16.0 HT/VHT40, M0 to M7 1 13 16.6 0.1 16.7 HT/VHT40, M0 to M7 2 13 12.8 13.1 0.1 16.0 0 1 7 5 HT/VHT40, M8 to M15 2 13 12.8 13.1 0.1 16.0 HT/VHT40 Beam Forming, M0 to M7 2 13 12.8 13.1 0.1 16.0 HT/VHT40 Beam Forming, M8 to M15 2 13 12.8 13.1 0.1 16.0 HT/VHT40 STBC, M0 to M7 2 13 12.8 13.1 0.1 16.0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 0.05 0.05 0.05 2.87 2.47 2.47 2.66 2.31 2.31 2.31 2.31 2.31 0.27 0.96 0.35 0.99 0.99 0.99 0.99 0.99 57 20 Non HT20, 6 to 54 Mbps 1 13 13.7 0.0 13.7 17. 0 3.27 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 26 of 61 Radio Test Report No: EDCS 18429929 Non HT20, 6 to 54 Mbps 2 13 9.5 10.5 0.0 13.1 Non HT20 Beam Forming, 6 to 54 Mbps 2 13 9.5 10.5 0.0 13.1 HT/VHT20, M0 to M7 1 13 12.9 0.0 12.9 HT/VHT20, M0 to M7 2 13 9.5 10.6 0.0 13.1 HT/VHT20, M8 to M15 2 13 9.5 10.6 0.0 13.1 HT/VHT20 Beam Forming, M0 to M7 2 13 9.5 10.6 0.0 13.1 HT/VHT20 Beam Forming, M8 to M15 2 13 9.5 10.6 0.0 13.1 HT/VHT20 STBC, M0 to M7 2 13 9.5 10.6 0.0 13.1 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 17. 0 3.93 3.93 4.06 3.86 3.86 3.86 3.86 3.86 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 27 of 61 Radio Test Report No: EDCS 18429929 Maximum Transmit Output Power, 5690 MHz, VHT80, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 28 of 61 Radio Test Report No: EDCS 18429929 A.4 Power Spectral Density Power Spectral Density Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Power Spectral Density Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test Procedure The rules requires maximum power spectral density measurements where the intent is to measure the maximum value of the time average of the power spectral density measured during a period of continuous transmission. 1. Create an average power spectrum for the EUT operating mode being tested by following the instructions in section II.E.2. for measuring maximum conducted output power using a spectrum analyzer or EMI receiver: select the Page No: 29 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 appropriate test method (SA-1, SA-2, SA-3, or alternatives to each) and apply it up to, but not including, the step labeled, Compute power. (This procedure is required even if the maximum conducted output power measurement was performed using a power meter, method PM.) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. b) If Method SA-3 Alternative was used and the linear mode was used in step II.E.2.g)(viii), add 1 dB to the final result to compensate for the difference between linear averaging and power averaging. 4. The result is the Maximum PSD over 1 MHz reference bandwidth. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) F. Maximum Power Spectral Density (PSD) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 30 of 61 Radio Test Report No: EDCS 18429929 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment Date of testing:
Start Date to Finish Date here Page No: 31 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Power Spectral Density
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n g r a M i 0.77 0.37 0.37 1.06 0.56 0.56 0.56 0.56 0.56 4.07 5.20 5.35 5.17 5.17 5.17 5.17 5.17 9.37 12.58 9.51 8.60 8.60 8.60 8.60 8.60 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13 1.7
-4.4 1.2
-2.9
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-1.5 1.3 0.3 0.3 0.3 0.3 0.3 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13 13 3.0
-0.1
-0.1 3.1
-0.1
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-0.1 0.5 0.5 0.1 0.1 0.1 0.1 0.1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 3.0 3.3 3.3 3.1 3.1 3.1 3.1 3.1 3.1 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13
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-0.1 1.4 1.4 1.4 1.4 0.0 0.0 0.0 0.0 0.0 0.0 3.5 3.9 3.9 3.3 3.8 3.8 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 2.27 5.46 2.75 3.69 3.69 3.69 3.69 3.69 0.97 0.75 0.75 0.86 0.95 0.95 0.95 0.95 0.95 8.97 6.10 4.91 5.15 5.15 5.15 5.15 5.15 7.07 6.54 5.31 4.40 4.40 4.40 4.40 4.40 0.47 0.12 0.12 0.66 0.23 0.23 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 33 of 61 0 0 7 5 Radio Test Report No: EDCS 18429929 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 13 13 13
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-0.3 0.7 0.7 0.8 0.8 0.8 0.8 0.8 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 3.9 3.3 3.3 3.1 3.3 3.3 3.3 3.3 3.3 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 4.0 0.23 0.23 0.23 0.77 1.61 0.95 1.69 1.69 1.69 1.69 1.69 0.07 0.68 0.68 0.86 0.66 0.66 0.66 0.66 0.66 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 34 of 61 Radio Test Report No: EDCS 18429929 Power Spectral Density, 5720 MHz, Non HT20, 6 to 54 Mbps Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 35 of 61 Radio Test Report No: EDCS 18429929 A.5 Conducted Spurious Emissions Conducted Spurious Emissions Test Requirement 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Spurious Emissions Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 36 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Add the max antenna gain + ground reflection factor (4.7 dB for frequencies between 30 MHz and 1000 MHz, and 0 dB for frequencies > 1000 MHz). Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
20-Nov-19 - 21-Nov-19 Page No: 37 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Conducted Spurs Average Upper Conducted Spurs Peak Upper This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 38 of 61 Radio Test Report No: EDCS 18429929 Conducted Spurious Average Table
) i
) m B d
(
r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
-55.6
-60.3
-60.6
-60.3
-60.6
-55.5
-59.9
-60.5
-59.9
-60.5
-59.9
-60.5
-59.9
-60.5
-59.9
-60.5
) B d
(
n o i t c e r r o C e l c y C y t u D 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
(
r u p S d e t c u d n o C l a t o T
) m B d
(
t i m L i
) B d
(
n g r a M i
-42.6
-41.25 1.32
-44.4
-41.25 3.15
-44.4
-41.25 3.15
-42.5
-41.25 1.21
-44.1
-41.25 2.89
-44.1
-41.25 2.89
-44.1
-41.25 2.89
-44.1
-41.25 2.89
-44.1
-41.25 2.89
-55.3
-60.6
-62.1
-55.6
-60.5
-61.7
-60.5
-61.7
-60.5
-61.7
-60.5
-61.7
-60.5
-61.7 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-42.3
-41.25 1.02
-45.2
-41.25 4.00
-42.5
-41.25 1.30
-45.0
-41.25 3.75
-45.0
-41.25 3.75
-45.0
-41.25 3.75
-45.0
-41.25 3.75
-45.0
-41.25 3.75
-55.4
-61.5
-63.4
-59.9
-60.5
-62.2
-60.5
-62.2
-60.5
-62.2
-60.5
-62.2
-60.5
-62.2 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-42.4
-41.25 1.12
-46.3
-41.25 5.05
-46.7
-41.25 5.46
-45.1
-41.25 3.82
-45.1
-41.25 3.82
-45.1
-41.25 3.82
-45.1
-41.25 3.82
-45.1
-41.25 3.82 B d
(
i n a G a n n e t n A d e t a l e r r o C 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
) z H M
(
y c n e u q e r F 0 0 5 5 Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Page No: 39 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 0 5 5 5 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13
-54.6
-60.5
-62.2
-54.5
-59.7
-61.3
-59.7
-61.3
-59.7
-61.3
-59.7
-61.3
-59.7
-61.3 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-41.6
-41.25 0.32
-45.2
-41.25 3.98
-41.4
-41.25 0.20
-44.4
-41.25 3.12
-44.4
-41.25 3.12
-44.4
-41.25 3.12
-44.4
-41.25 3.12
-44.4
-41.25 3.12
-55.4
-60.1
-61.3
-60.1
-61.3
-55.1
-60.0
-61.3
-60.0
-61.3
-60.0
-61.3
-60.0
-61.3
-60.0
-61.3 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-42.4
-41.25 1.12
-44.6
-41.25 3.37
-44.6
-41.25 3.37
-42.1
-41.25 0.81
-44.5
-41.25 3.30
-44.5
-41.25 3.30
-44.5
-41.25 3.30
-44.5
-41.25 3.30
-44.5
-41.25 3.30
-57.6
-57.6
-59.6
-55.9
-57.2
-59.1
-57.2
-59.1
-57.2
-59.1
-57.2
-59.1
-57.2
-59.1 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-44.6
-41.25 3.32
-42.4
-41.25 1.19
-42.7
-41.25 1.46
-41.8
-41.25 0.60
-41.8
-41.25 0.60
-41.8
-41.25 0.60
-41.8
-41.25 0.60
-41.8
-41.25 0.60
-54.6
-58.5
-59.1
-56.5
-57.6
-59.1
-57.6
-59.1
-57.6
-59.1
-57.6
-59.1
-57.6
-59.1 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-41.6
-41.25 0.32
-42.7
-41.25 1.50
-43.3
-41.25 2.06
-42.1
-41.25 0.84
-42.1
-41.25 0.84
-42.1
-41.25 0.84
-42.1
-41.25 0.84
-42.1
-41.25 0.84
-57.6
-61.8
-61.8
-61.8
-61.8
-57.4
-61.6
-61.7
-61.6
-61.7 0.0 0.0 0.0 0.0 0.0 0.0
-44.6
-41.25 3.32
-45.8
-41.25 4.51
-45.8
-41.25 4.51
-44.4
-41.25 3.11
-45.6
-41.25 4.35
-45.6
-41.25 4.35 Page No: 40 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13
-61.6
-61.7
-61.6
-61.7
-61.6
-61.7 0.0 0.0 0.0
-45.6
-41.25 4.35
-45.6
-41.25 4.35
-45.6
-41.25 4.35
-56.1
-58.3
-58.6
-56.1
-58.0
-59.0
-58.0
-59.0
-58.0
-59.0
-58.0
-59.0
-58.0
-59.0 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-43.1
-41.25 1.82
-42.4
-41.25 1.16
-43.0
-41.25 1.80
-42.4
-41.25 1.16
-42.4
-41.25 1.16
-42.4
-41.25 1.16
-42.4
-41.25 1.16
-42.4
-41.25 1.16
-57.3
-62.3
-62.0
-62.3
-62.0
-57.7
-62.0
-61.6
-62.0
-61.6
-62.0
-61.6
-62.0
-61.6
-62.0
-61.6 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-44.3
-41.25 3.02
-46.1
-41.25 4.85
-46.1
-41.25 4.85
-44.7
-41.25 3.41
-45.7
-41.25 4.49
-45.7
-41.25 4.49
-45.7
-41.25 4.49
-45.7
-41.25 4.49
-45.7
-41.25 4.49 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 41 of 61 Radio Test Report No: EDCS 18429929 Conducted Spurs Average, 5550 MHz, HT/VHT40, M0 to M7 Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 42 of 61 Radio Test Report No: EDCS 18429929 Conducted Spurious Emissions Peak Table
) i
) z H M
(
y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss B d
(
i n a G a n n e t n A d e t a s h t a P x T l e r r o C 13 13 13 13 13 13 13 13 13 1 2 2 1 2 2 2 2 2
) m B d
(
r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
-46.3
-50.6
-48.5
-50.6
-48.5
-47.3
-50.6
-49.9
-50.6
-49.9
-50.6
-49.9
-50.6
-49.9
-50.6
-49.9
) m B d
(
r e w o P r u p S 3 x T 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
(
r u p S d e t c u d n o C l a t o T
) m B d
(
t i m L i
) B d
(
n g r a M i
-33.3
-21.25 12.02
-33.4
-21.25 12.13
-33.4
-21.25 12.13
-34.3
-21.25 13.01
-34.2
-21.25 12.93
-34.2
-21.25 12.93
-34.2
-21.25 12.93
-34.2
-21.25 12.93
-34.2
-21.25 12.93 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13
-46.7
-51.7
-51.0
-47.3
-51.1
-51.2
-51.1
-51.2
-51.1
-51.2
-51.1
-51.2
-51.1
-51.2 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-33.7
-21.25 12.42
-35.3
-21.25 14.05
-34.2
-21.25 13.00
-35.1
-21.25 13.84
-35.1
-21.25 13.84
-35.1
-21.25 13.84
-35.1
-21.25 13.84
-35.1
-21.25 13.84 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13
-47.8
-53.5
-53.0
-50.4
-52.1
-51.5
-52.1
-51.5
-52.1
-51.5
-52.1
-51.5
-52.1
-51.5 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-34.8
-21.25 13.52
-37.2
-21.25 15.95
-37.2
-21.25 15.96
-35.6
-21.25 14.34
-35.6
-21.25 14.34
-35.6
-21.25 14.34
-35.6
-21.25 14.34
-35.6
-21.25 14.34 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 43 of 61 Radio Test Report No: EDCS 18429929 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13
-46.1
-52.1
-50.2
-46.9
-49.7
-50.6
-49.7
-50.6
-49.7
-50.6
-49.7
-50.6
-49.7
-50.6 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-33.1
-21.25 11.82
-35.0
-21.25 13.76
-33.8
-21.25 12.60
-34.1
-21.25 12.82
-34.1
-21.25 12.82
-34.1
-21.25 12.82
-34.1
-21.25 12.82
-34.1
-21.25 12.82 1 2 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13 13
-47.4
-51.0
-50.5
-51.0
-50.5
-47.5
-50.5
-50.0
-50.5
-50.0
-50.5
-50.0
-50.5
-50.0
-50.5
-50.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-34.4
-21.25 13.12
-34.7
-21.25 13.45
-34.7
-21.25 13.45
-34.5
-21.25 13.21
-34.2
-21.25 12.94
-34.2
-21.25 12.94
-34.2
-21.25 12.94
-34.2
-21.25 12.94
-34.2
-21.25 12.94 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13
-49.2
-49.2
-49.1
-47.3
-48.8
-49.2
-48.8
-49.2
-48.8
-49.2
-48.8
-49.2
-48.8
-49.2 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-36.2
-21.25 14.92
-33.1
-21.25 11.86
-34.1
-21.25 12.86
-32.8
-21.25 11.55
-32.8
-21.25 11.55
-32.8
-21.25 11.55
-32.8
-21.25 11.55
-32.8
-21.25 11.55 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13
-47.3
-50.1
-49.9
-49.3
-49.0
-49.6
-49.0
-49.6
-49.0
-49.6
-49.0
-49.6
-49.0
-49.6 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-34.3
-21.25 13.02
-34.0
-21.25 12.71
-36.1
-21.25 14.86
-33.1
-21.25 11.84
-33.1
-21.25 11.84
-33.1
-21.25 11.84
-33.1
-21.25 11.84
-33.1
-21.25 11.84 1 2 2 1 2 2 13 13 13 13 13 13
-49.9
-52.0
-52.0
-52.0
-52.0
-49.3
-53.1
-52.1
-53.1
-52.1 0.0 0.0 0.0 0.0 0.0 0.0
-36.9
-21.25 15.62
-36.0
-21.25 14.71
-36.0
-21.25 14.71
-36.3
-21.25 15.01
-36.5
-21.25 15.27
-36.5
-21.25 15.27 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 44 of 61 Radio Test Report No: EDCS 18429929 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 13 13 13
-53.1
-52.1
-53.1
-52.1
-53.1
-52.1 0.0 0.0 0.0
-36.5
-21.25 15.27
-36.5
-21.25 15.27
-36.5
-21.25 15.27 13 13 13 13 13 13 13 13
-48.0
-50.0
-49.7
-47.9
-49.5
-49.0
-49.5
-49.0
-49.5
-49.0
-49.5
-49.0
-49.5
-49.0 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-35.0
-21.25 13.72
-33.8
-21.25 12.56
-34.8
-21.25 13.60
-33.2
-21.25 11.93
-33.2
-21.25 11.93
-33.2
-21.25 11.93
-33.2
-21.25 11.93
-33.2
-21.25 11.93 13 13 13 13 13 13 13 13 13
-48.6
-53.6
-52.7
-53.6
-52.7
-49.9
-53.5
-52.0
-53.5
-52.0
-53.5
-52.0
-53.5
-52.0
-53.5
-52.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-35.6
-21.25 14.32
-37.1
-21.25 15.83
-37.1
-21.25 15.83
-36.9
-21.25 15.61
-36.6
-21.25 15.38
-36.6
-21.25 15.38
-36.6
-21.25 15.38
-36.6
-21.25 15.38
-36.6
-21.25 15.38 Page No: 45 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Conducted Spurs Peak, 5610 MHz, VHT80, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 46 of 61 Radio Test Report No: EDCS 18429929 A.6 Conducted Bandedge 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Band Edge Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI Page No: 47 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 C63.10:2013 section 14.3.2.2) 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging System under Support test equipment Date of testing:
20-Nov-19 - 21-Nov-19 Page No: 48 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Conducted Bandedge Average Table
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y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss i B d
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n a G a n n e t n A d e t a s h t a P x T l e r r o C 13 13 13 13 13 13 13 13 13 1 2 2 1 2 2 2 2 2
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-57.5
-61.3
-62.8
-61.3
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-58.4
-61.0
-63.5
-61.0
-63.5
-61.0
-63.5
-61.0
-63.5
-61.0
-63.5 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-44.5
-41.25 3.22
-45.9
-41.25 4.69
-45.9
-41.25 4.69
-45.4
-41.25 4.11
-46.0
-41.25 4.77
-46.0
-41.25 4.77
-46.0
-41.25 4.77
-46.0
-41.25 4.77
-46.0
-41.25 4.77 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13
-54.6
-60.7
-61.8
-56.9
-61.5
-63.1
-61.5
-63.1
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-63.1
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-63.1
-61.5
-63.1 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-41.6
-41.25 0.32
-45.2
-41.25 3.93
-43.8
-41.25 2.60
-46.2
-41.25 4.92
-46.2
-41.25 4.92
-46.2
-41.25 4.92
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-41.25 4.92
-46.2
-41.25 4.92 1 2 1 2 2 2 2 2 13 13 13 13 13 13 13 13
-56.8
-60.7
-61.2
-54.7
-57.5
-59.1
-57.5
-59.1
-57.5
-59.1
-57.5
-59.1
-57.5
-59.1 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-43.8
-41.25 2.52
-44.9
-41.25 3.65
-41.5
-41.25 0.26
-42.0
-41.25 0.78
-42.0
-41.25 0.78
-42.0
-41.25 0.78
-42.0
-41.25 0.78
-42.0
-41.25 0.78 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 49 of 61 Radio Test Report No: EDCS 18429929 Conducted Bandedge Average, 5530 MHz, VHT80, M0 to M9 1ss Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 50 of 61 Radio Test Report No: EDCS 18429929 Conducted Bandedge Peak Table
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-45.0
-32.0
-21.25 10.72
-46.1
-47.0
-30.5
-21.25 9.23
-46.1
-47.0
-30.5
-21.25 9.23
-41.6
-28.6
-21.25 7.31
-43.7
-48.1
-29.3
-21.25 8.06
-43.7
-48.1
-29.3
-21.25 8.06
-43.7
-48.1
-29.3
-21.25 8.06
-43.7
-48.1
-29.3
-21.25 8.06
-43.7
-48.1
-29.3
-21.25 8.06
-35.7
-22.7
-21.25 1.42
-41.8
-37.4
-23.0
-21.25 1.78
-40.1
-27.0
-21.25 5.80
-42.8
-45.0
-27.7
-21.25 6.45
-42.8
-45.0
-27.7
-21.25 6.45
-42.8
-45.0
-27.7
-21.25 6.45
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-45.0
-27.7
-21.25 6.45
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-45.0
-27.7
-21.25 6.45
-44.4
-31.4
-21.25 10.12
-46.8
-52.0
-32.6
-21.25 11.37
-35.6
-22.4
-21.25 1.16
-44.9
-42.4
-27.3
-21.25 6.02
-44.9
-42.4
-27.3
-21.25 6.02
-44.9
-42.4
-27.3
-21.25 6.02
-44.9
-42.4
-27.3
-21.25 6.02
-44.9
-42.4
-27.3
-21.25 6.02 i B d
(
n a G a n n e t n A d e t a l e r r o C 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 Page No: 51 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 13 13 13 13 13 13 13 13 13 1 2 2 1 2 2 2 2 2
-43.5
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-47.7
-47.9
-31.8
-21.25 10.51
-47.7
-47.9
-31.8
-21.25 10.51
-41.5
-28.5
-21.25 7.21
-48.1
-44.3
-29.7
-21.25 8.49
-48.1
-44.3
-29.7
-21.25 8.49
-48.1
-44.3
-29.7
-21.25 8.49
-48.1
-44.3
-29.7
-21.25 8.49
-48.1
-44.3
-29.7
-21.25 8.49 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 52 of 61 Radio Test Report No: EDCS 18429929 Conducted Bandedge Peak, 5530 MHz, VHT80, M0 to M9 1ss Antenna A Conducted Bandedge Peak, 5700 MHz, HT/VHT20, M0 to M7 Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 53 of 61 Radio Test Report No: EDCS 18429929 Appendix B: List of Test Equipment Used to perform the test Equip#
Manufacturer/ Model Description Last Cal Next Due RF Conducted at output antenna port 7329 OMEGA/CT485B Chart Recorder 18 Feb. 2019 18 Feb. 2020 49516 Keysight (Agilent/HP) / N9030A PXA Signal Analyzer, 3Hz to 50GHz 29 Nov. 2019 29 Nov. 2019 55097 Nattional Instruments / PXI-1042 Chassis PXI Cal Not Required Cal Not Required 56089 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 56328 Pasternack / PE5019-1 Torque Wrench 13 Feb. 2019 13 Feb. 2020 57233 Nattional Instruments / PXI-8115 Embedded Controller Cal Not Required Cal Not Required 57253 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 57254 National Instruments / PXI-2799 Switch 1x1 Verify Before Use Verify Before Use 57479 CISCO / ATIL Automation Test Insertion Loss System Verify Before Use Verify Before Use This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 54 of 61 Radio Test Report No: EDCS 18429929 Appendix C: Abbreviation Key and Definitions The following table defines abbreviations used within this test report. Abbreviation Description Abbreviation Description F C Temp Electro Magnetic Compatibility Electro Magnetic Interference Equipment Under Test Information Technology Equipment S/N Qty Test Assessment Schedule emf Electro Static Discharge Electric Fast Transient RMS Qp Engineering Document Control System Configuration Cisco Number (unique identification number for Cisco test equipment) Calibration Av Pk kHz MHz GHz H V dB V kV V A A mS S European Norm International Electro technical Commission International Special Committee on Radio Interference Coupling/Decoupling Network Line Impedance Stabilization Network Protective Earth Ground Line 1 Line2 Line 3 Direct Current Uncorrected measurement value, as indicated by the measuring device Radio Frequency Signal Line Conducted Emissions Measurement distance Not Applicable Power Line Neutral Line Supply EMC EMI EUT ITE TAP ESD EFT EDCS Config CIS#
Cal EN IEC CISPR CDN LISN PE GND L1 L2 L3 DC RAW RF SLCE Meas dist N/A or NA P N S Degrees Fahrenheit Degrees Celsius Temperature Serial Number Quantity Electromotive force Root mean square Quasi Peak Average Peak Kilohertz (1x103) MegaHertz (1x106) Gigahertz (1x109) Horizontal Vertical decibel Volt Kilovolt (1x103) Microvolt (1x10-6) Amp Micro Amp (1x10-6) Milli Second (1x10-3) Micro Second (1x10-6) S m Spec dist SL L R AC Micro Second (1x10-6) Meter Specification distance Signal Line (or Telecom Line) Live Line Return Alternating Current This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 55 of 61 Radio Test Report No: EDCS 18429929 Appendix D: Photographs of Test Setups Title: EUT Pictures Page No: 56 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 57 of 61 Radio Test Report No: EDCS 18429929 Title: Radio Conducted Test Setup Page No: 58 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Appendix E: Software Used to Perform Testing EMIsoft Vasona, version 6.024 Page No: 59 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Appendix F: Test Procedures Measurements were made in accordance with KDB 789033 - D02 General UNII Test Procedures New Rules v02r01 KDB 662911 - MIMO ANSI C63.4 2014 Unintentional Radiators ANSI C63.10 2013 Intentional Radiators Test procedures are summarized below:
FCC 5GHz Test Procedures FCC 5GHz RSE Test Procedures EDCS # 1445048 EDCS # 1511600 Page No: 60 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429929 Appendix G: Scope of Accreditation (A2LA certificate number 1178-01) The scope of accreditation of Cisco Systems, Inc. can be found on the A2LA web page at:
http://www.a2la.org/scopepdf/1178-01.pdf End This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 61 of 61
1 2 3 4 5 6 | UNI IIC EXT 7B | External Photos | 2.74 MiB | September 12 2019 |
Radio Test Report No: EDCS (EDCS) Test Report IW-6300H Series Access Point Cisco Industrial Wireless Hazardous Location Access Point FCC ID: LDKESW6300 IC ID: 2461D-ESW6300 5470-5725 MHz Outside Antennas, 5dBi Gain Against the following Specifications:
CFR47 Part 15.407 RSS-247 Cisco Systems 170 West Tasman Drive San Jose, CA 95134 Approved By: Adam Walb Title: MGR. IoT Compliance Revision: 1.0 Author: Julian Land Tested By: Julian Land This report replaces any previously entered test report under EDCS (EDCS).This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. Test Report Template EDCS#
11644124. Page No: 1 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. SECTION 1: OVERVIEW ......................................................................................................................................... 3 SECTION2: ASSESSMENT INFORMATION ........................................................................................................ 4 2.1 GENERAL ............................................................................................................................................................. 4 2.2 DATE OF TESTING................................................................................................................................................. 6 2.3 REPORT ISSUE DATE ............................................................................................................................................ 6 2.4 TESTING FACILITIES ............................................................................................................................................. 6 2.5 EQUIPMENT ASSESSED (EUT) .............................................................................................................................. 6 2.6 EUT DESCRIPTION ............................................................................................................................................... 7 SECTION 3: RESULT SUMMARY ........................................................................................................................ 10 3.1 RESULTS SUMMARY TABLE ............................................................................................................................... 10 SECTION 4: SAMPLE DETAILS ........................................................................................................................... 11 4.1 SAMPLE DETAILS ............................................................................................................................................... 11 4.2 SYSTEM DETAILS ............................................................................................................................................... 11 4.3 MODE OF OPERATION DETAILS .......................................................................................................................... 11 APPENDIX A: EMISSION TEST RESULTS ........................................................................................................ 12 CONDUCTED TEST SETUP DIAGRAM ........................................................................................................................ 12 TARGET MAXIMUM CHANNEL POWER .................................................................................................................... 12 A.1 DUTY CYCLE .................................................................................................................................................... 14 A.2 99% AND 26DB BANDWIDTH ............................................................................................................................ 17 A.3 MAXIMUM CONDUCTED OUTPUT POWER ......................................................................................................... 21 A.4 POWER SPECTRAL DENSITY .............................................................................................................................. 29 A.5 CONDUCTED SPURIOUS EMISSIONS ................................................................................................................... 36 A.6 CONDUCTED BANDEDGE ................................................................................................................................... 47 APPENDIX B:
LIST OF TEST EQUIPMENT USED TO PERFORM THE TEST .................................... 55 APPENDIX C: ABBREVIATION KEY AND DEFINITIONS ............................................................................. 56 APPENDIX D:
PHOTOGRAPHS OF TEST SETUPS ................................................................................... 57 APPENDIX E:
SOFTWARE USED TO PERFORM TESTING ................................................................... 60 APPENDIX F:
TEST PROCEDURES ............................................................................................................. 61 APPENDIX G: SCOPE OF ACCREDITATION (A2LA CERTIFICATE NUMBER 1178-01) ........................ 62 Page No: 2 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Section 1: Overview The samples were assessed against the tests detailed in section 3 under the requirements of the following specifications:
Specifications:
CFR47 Part 15.407 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 3 of 62 b) c) d) e) Radio Test Report No: EDCS (EDCS) Section2: Assessment Information 2.1 General This report contains an assessment of an apparatus against Electromagnetic Compatibility Standards based upon tests carried out on the samples submitted. The testing was performed by and for the use of Cisco systems Inc:
With regard to this assessment, the following points should be noted:
a) The results contained in this report relate only to the items tested and were obtained in the period between the date of the initial assessment and the date of issue of the report. Manufactured products will not necessarily give identical results due to production and measurement tolerances. The apparatus was set up and exercised using the configuration and modes of operation defined in this report only. Where relevant, the apparatus was only assessed using the susceptibility criteria defined in this report and the Test Assessment Plan (TAP). All testing was performed under the following environmental conditions:
Temperature 15C to 35C (54F to 95F) Atmospheric Pressure 860mbar to 1060mbar (25.4" to 31.3") Humidity 10% to 75*%
All AC testing was performed at one or more of the following supply voltages:
110V 60 Hz (+/-20%) Units of Measurement The units of measurements defined in the appendices are reported in specific terms, which are test dependent. Where radiated measurements are concerned these are defined at a particular distance. Basic voltage measurements are defined in units of [dBuV]
As an example, the basic calculation for all measurements is as follows:
The combinations of correction factors are dependent upon the exact test configurations [see test equipment lists for further details] and may include:-
Emission level [dBuV] = Indicated voltage level [dBuV] + Cable Loss [dB] + Other correction factors [dB]
Antenna Factors, Pre Amplifier Gain, LISN Loss, Pulse Limiter Loss and Filter Insertion Loss Note: to convert the results from dBuV/m to uV/m use the following formula:-
Level in uV/m = Common Antilogarithm [(X dBuV/m)/20] = Y uV/m This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 4 of 62 Radio Test Report No: EDCS (EDCS) Measurement Uncertainty Values voltage and power measurements 2 dB conducted EIRP measurements 1.4 dB radiated measurements 3.2 dB frequency measurements 2.4 10-7 temperature measurements humidity measurements 0.54 2.3%
DC and low frequency measurements 2.5%
Where relevant measurement uncertainty levels have been estimated for tests performed on the apparatus. This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2. Radiated emissions (expanded uncertainty, confidence interval 95%) 30 MHz - 300 MHz 300 MHz - 1000 MHz 1 GHz - 10 GHz 10 GHz - 18GHz 18GHz - 26.5GHz 26.5GHz - 40GHz
+/- 3.8 dB
+/- 4.3 dB
+/- 4.0 dB
+/- 8.2 dB
+/- 4.1 dB
+/- 3.9 dB Conducted emissions (expanded uncertainty, confidence interval 95%) A product is considered to comply with a requirement if the nominal measured value is below the limit line. The product is considered to not be in compliance in case the nominal measured value is above the limit line. 30 MHz 40GHz
+/- 0.38 dB This report must not be reproduced except in full, without written approval of Cisco Systems. Page No: 5 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 2.2 Date of testing 20-Nov-19 - 21-Nov-19 2.3 Report Issue Date 9/23/2019 Cisco uses an electronic system to issue, store and control the revision of test reports. This system is called the Engineering Document Control System (EDCS). The actual report issue date is embedded into the original file on EDCS. Any copies of this report, either electronic or paper, that are not on EDCS must be considered uncontrolled. 2.4 Testing facilities This assessment was performed by:
Testing Laboratory Cisco Systems, Inc. 125 West Tasman Drive (Building P) San Jose, CA 95134 USA Headquarters Cisco Systems, Inc., 170 West Tasman Drive San Jose, CA 95134, USA Registration Numbers for Industry Canada Cisco System Site Address Building P, 10m Chamber Building P, 5m Chamber Building I, 5m Chamber 125 West Tasman Dr San Jose, CA 95134 125 West Tasman Dr San Jose, CA 95134 285 W. Tasman Drive San Jose, California 95134 Site Identifier Company #: 2461N-2 Company #: 2461N-1 Company #: 2461M-1 Building 7, 5m Chamber 425 E. Tasman Drive Company #: 2461N-3 San Jose, California 95134 Test Engineers Julian Land 2.5 Equipment Assessed (EUT) IW 6300H Page No: 6 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 2.6 EUT Description The radio supports the following modes of operation. The modes are further defined in the radio Theory of Operation. The modes included in this report represent the worst case data for all modes. 802.11a - Non HT20, Two Antennas, 6 to 54 Mbps, 1ss 802.11a - Non HT20 Beam Forming, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT20, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT40, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT40, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT40, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT80, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT80, Two Antennas, 6 to 54 Mbps, 1ss 802.11ac - VHT80, One Antenna, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 1ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 STBC, Two Antennas, M0 to M9 2ss 802.11a - Non HT20, One Antenna, 6 to 54 Mbps, 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 7 of 62 Radio Test Report No: EDCS (EDCS) Model / PID Differences IW-6300H-AC-x-K9, IW-6300H-DC-x-K9, IW-6300-DCW-x-K9 and ESW-6300-CON-x-K9, all have the same identical components, electronics circuitries, PCB layout and enclosure. The only differences are listed as below:
IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300-DCW-x-K9 ESW-6300-CON-x-K9 Where x can be replaced with another letter to indicate country domain. Domain letters: A, B, C, D, E, F, H, I, L, M, N, Q, R, S, T, Z Where AC is Alternating Current (AC power supply) Where DC is Direct Current (DC power supply), 54V native input Where DCW is Direct Current; wide range 10-36VDC Where K9 is encryption software. Page No: 8 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) The following antennas are supported by this product series. The data included in this report represent the worst case data for all antennas. Frequency Part Number AIR-ANT2450V-N Antenna Type Single Band Omni AIR-ANT2450V-N-HZ Single Band Omni, Hazloc 2.4 GHz AIR-ANT2480V-N AIR-ANT2450HG-N AIR-ANT2450VG-N AIR-ANT2413P2M-N Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni Single Band, Dual Polarized Directional Patch 5 GHz 2.4/5 GHz Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni AIR-ANT5180V-N AIR-ANT5150HG-N AIR-ANT5150VG-N AIR-ANT5114P2M-N AIR-ANT2547V-N=
AIR-ANT2547VG-N= Dual-band Omni, Gray AIR-ANT2547V-N-HZ= Dual-band Omni, Hazloc Dual-band Omni Single Band, Dual Polarized Directional Patch AIR-ANT2568VG-N AIR-ANT2588P3M-N= Dual-band/Dual Polarized Directional, Patch AIR-ANT2513P4M-N Dual-band Polarization Diverse Patch Array Dual-band Omni
>30 degree 5 GHz Antenna Gain
(dBi) NA NA NA NA NA NA
-3
-5
-6 5
-6
-6
-6 3 1
-5 Antenna Gain
(dBi) 5 5 8 5 5 13 8 5 5 13 4 / 7 4 / 7 4 / 7 6 / 8 8 / 8 13 / 13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 9 of 62 Radio Test Report No: EDCS (EDCS) Section 3: Result Summary 3.1 Results Summary Table Conducted emissions Basic Standard FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.209 FCC 15.205 Technical Requirements / Details 99% & 26 dB Bandwidth:
The 99% occupied bandwidth is the frequency bandwidth such that, below its lower and above its upper frequency limits, the mean powers are each equal to 0.5% of the total mean power of the given emission. There is no limit for 99% OBW. The 26 dB emission is the width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 26 dB relative to the maximum level measured in the fundamental emission. Output Power:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Power Spectral Density:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bandsthe maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Conducted Spurious Emissions / Band-Edge:
15.407 (3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz. Restricted band:
Unwanted emissions falling within the restricted bands, as defined in FCC 15.205 (a) must also comply with the radiated emission limits specified in FCC 15.209 (a). Result Pass Pass Pass Pass Pass Radiated Emissions (General requirements) Basic Standard FCC 15.209 FCC 15.205 FCC 15.207 Technical Requirements / Details TX Spurious Emissions:
Except as provided elsewhere in this subpart, the emissions from an intentional radiator shall not exceed the field strength levels specified in the filed strength limits table in this section. AC conducted Emissions:
Except when the requirements applicable to a given device state otherwise, for any radio apparatus equipped to operate from the public utility AC power supply, either directly or indirectly (such as with a battery charger), the radio frequency voltage of emissions conducted back onto the AC power lines in the frequency range of 0.15 MHz to 30 MHz shall not exceed the limits shown in the table in these sections. The more stringent limit applies at the frequency range boundaries. Result Pass Pass Page No: 10 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Section 4: Sample Details Note: Each sample was evaluated to ensure that its condition was suitable to be used as a test sample prior to the commencement of testing. 4.1 Sample Details Sample No. S01 S02 Equipment Details Manufacturer Hardware Rev. Firmware Rev. Software Rev. Serial Number IW-6300H-DC-B-K9 FSP150-AWAN3 Cisco Systems, Inc. FSP Group Inc. 11
-
9.1.8.1 9.0.5.5-W8964 FOC23241G16
-
-
H00000063 4.2 System Details System #
1 EUT and Power Supply 4.3 Mode of Operation Details Mode#
Description Description Samples S01, S02 Comments 1 Continuous Transmitting Continuous Transmitting 98% duty cycle All measurements were made in accordance with ANSI C63.10:2013 KDB 789033 D02 General UNII Test Procedures New Rules v01r03 KDB 662911 D01 Multiple Transmitter Output v02r01 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 11 of 62 Radio Test Report No: EDCS (EDCS) Appendix A: Emission Test Results Conducted Test Setup Diagram Target Maximum Channel Power The following table details the maximum supported Total Channel Power for all operating modes. Operating Mode Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M15 HT/VHT20 Beam Forming, M0 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 HT/VHT40 Beam Forming, M0 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss VHT80 Beam Forming, M0 to M9, M0 to M9 1-2ss Maximum Channel Power
(dBm) Frequency (MHz) 5500 20 17 21 21 21 5510 18 18 18 18 5530 15 17 17 5560 20 17 21 21 21 5550 20 21 20 20 5610 19 23 23 5700 20 17 20 20 20 5710 23 23 23 23 5690 22 23 23 Page No: 12 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) VHT80 STBC, M0 to M9 1ss 17 23 23 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 13 of 62 Radio Test Report No: EDCS (EDCS) A.1 Duty Cycle Duty Cycle Test Requirement From KDB 789033 D02 General UNII Test Procedures New Rules v02r01 B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level 1. All measurements are to be performed with the EUT transmitting at 100 percent duty cycle at its maximum power control level; however, if 100 percent duty cycle cannot be achieved, measurements of duty cycle, x, and maximum-power transmission duration, T, are required for each tested mode of operation. Duty Cycle Test Method From KDB 789033 D02 General UNII Test Procedures New Rules v02r01:
B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level The zero-span mode on a spectrum analyzer or EMI receiver, if the response time and spacing between bins on the sweep are sufficient to permit accurate measurements of the on and off times of the transmitted signal. Set the center frequency of the instrument to the center frequency of the transmission. Set RBW EBW if possible; otherwise, set RBW to the largest available value. Set VBW RBW. Set detector = peak or average. The zero-span measurement method shall not be used unless both RBW and VBW are > 50/T, where T is defined in section II.B.1.a), and the number of sweep points across duration T exceeds 100. (For example, if VBW and/or RBW are limited to 3 MHz, then the zero-span method of measuring duty cycle shall not be used if T 16.7 microseconds.) Duty Cycle Test Information Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Date of testing:
20-Nov-19 - 21-Nov-19 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 14 of 62 Radio Test Report No: EDCS (EDCS) Duty Cycle Data Table Duty Cycle table and screen captures are shown below for power/psd modes. Frequency Mode Data Rate 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 Duty Cycle correction
(dB) 0.0 0.0 0.0 0.1 0.0 0.2 0.0 0.1 0.0 0.0 0.0 0.2 0.0 0.2 0.0 0.0 0.0 0.1 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 15 of 62 Radio Test Report No: EDCS (EDCS) Duty Cycle, 5530 MHz, VHT80, M0 to M9, M0 to M9 1-2ss Page No: 16 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) A.2 99% and 26dB Bandwidth 99% and 26dB Bandwidth Test Requirement There is no requirement for the value of bandwidth. However, the 26dB BW (EBW) is used to calculate the power limits in 15.407 (a) (2). Power measurements are made using the 99% Bandwidth as the integration bandwidth. Band-crossing emissions: For an emission that crosses the boundary between two adjacent U-NII bands, the boundary frequency between the bands serves as one edge for defining the portion of the EBW that falls within a particular U-NII band. However, the -26 dB points are measured relative to the highest point on the contiguous segmentregardless of which band contains that highest point (Figure4). 99% and 26dB Bandwidth Test Procedure Ref. KDB 789033 Section D. 99 Percent Occupied Bandwidth ANSI C63.10: 2013 Section 6.9.3 KDB 662911 99% BW Test Parameters 1. Set center frequency to the nominal EUT channel center frequency. 2. Set span = 1.5 times to 5.0 times the OBW. 3. Set RBW = 1 % to 5 % of the OBW 4. Set VBW 3 RBW 5. Video averaging is not permitted. Where practical, a sample detection and single sweep mode shall be used. Otherwise, peak detection and max hold mode (until the trace stabilizes) shall be used. 6. Use the 99 % power bandwidth function of the instrument (if available). Ref KDB 789033 in Section C. Measurement Bandwidth, Section 1 26 BW Test parameters X dB BW = -26dB (using the OBW function of the spectrum analyzer) Emission Bandwidth (EBW) a) Set RBW = approximately 1% of the emission bandwidth. b) Set the VBW > RBW. c) Detector = Peak. d) Trace mode = max hold. e) Measure the maximum width of the emission that is 26 dB down from the maximum of the emission. Page No: 17 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Compare this with the RBW setting of the analyzer. Readjust RBW and repeat measurement as needed until the RBW/EBW ratio is approximately 1%. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
Start Date to Finish Date here Page No: 18 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 99% and 26dB Bandwidth Table Frequency
(MHz) 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Mode Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Data Rate 26dB BW 99% BW
(Mbps)
(MHz) 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 19.7 20.1 41.6 40.6 82.8 82.5 41.0 41.0 19.7 20.2 82.6 82.3 83.4 82.3 19.9 20.2 41.5 40.7 15.0 15.1
(MHz) 16.614 17.646 36.366 36.211 76.386 76.393 36.400 36.209 16.607 17.643 76.532 76.443 76.498 76.516 16.627 17.645 36.393 36.215 13.305 13.802 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 19 of 62 Radio Test Report No: EDCS (EDCS) 26dB / 99% Bandwidth, 5720 MHz, Non HT20, 6 to 54 Mbps This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 20 of 62 Radio Test Report No: EDCS (EDCS) A.3 Maximum Conducted Output Power Maximum Conducted Output Power Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Maximum Conducted Output Power Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 ANSI C63.10: 2013 Maximum Conducted Output Power Test Procedure 1. Set the radio in the continuous transmitting mode at full power 2. Compute power by integrating the spectrum across the EBW (or alternatively entire 99% OBW) of the signal using the instruments band power measurement function. The integration shall be performed using Page No: 21 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) the spectrum analyzer band-power measurement function with band limits set equal to the EBW or the OBW band edges. 3. Capture graphs and record pertinent measurement data. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Measurement using a Spectrum Analyzer or EMI Receiver (SA), (d) Method SA-2 Maximum Conducted Output Power Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 System under Support test equipment Date of testing:
Start Date to Finish Date here Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 22 of 62 Radio Test Report No: EDCS (EDCS) Maximum Output Power
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n g r a M i Non HT20, 6 to 54 Mbps 1 7 19.9 0.0 19.9 Non HT20, 6 to 54 Mbps 2 7 14.7 13.4 0.0 17.1 Non HT20 Beam Forming, 6 to 54 Mbps 2 10 14.7 13.4 0.0 17.1 HT/VHT20, M0 to M7 1 7 21.0 0.0 21.0 HT/VHT20, M0 to M7 2 7 14.9 13.6 0.0 17.4 HT/VHT20, M8 to M15 2 7 18.1 16.8 0.0 20.6 HT/VHT20 Beam Forming, M0 to M7 2 10 14.9 13.6 0.0 17.4 HT/VHT20 Beam Forming, M8 to M15 2 7 18.1 16.8 0.0 20.6 HT/VHT20 STBC, M0 to M7 2 7 18.1 16.8 0.0 20.6 Non HT40, 6 to 54 Mbps 1 7 15.5 0.0 15.5 Non HT40, 6 to 54 Mbps 2 7 15.4 14.4 0.0 18.0 HT/VHT40, M0 to M7 1 7 15.4 0.1 15.5 HT/VHT40, M0 to M7 2 7 15.4 14.5 0.1 18.0 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 2 2 7 10 15.4 13.4 14.5 12.5 0.1 0.1 18.0 16.0 23. 0 23. 0 23. 0 23. 0 23. 0 20. Page No: 23 of 62 0 1 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 3.07 5.86 2.86 1.96 5.65 2.45 2.65 2.45 2.45 7.47 5.03 7.55 4.97 4.97 3.97 Radio Test Report No: EDCS (EDCS) 0 3 5 5 HT/VHT40 Beam Forming, M8 to M15 2 7 15.4 14.5 0.1 18.0 HT/VHT40 STBC, M0 to M7 2 7 15.4 14.5 0.1 18.0 Non HT80, 6 to 54 Mbps 1 7 14.7 0.0 14.7 Non HT80, 6 to 54 Mbps 2 7 12.1 11.4 0.0 14.8 VHT80, M0 to M9 1ss 1 7 14.9 0.2 15.1 VHT80, M0 to M9 1ss 2 7 13.7 13.1 0.2 16.6 VHT80, M0 to M9 2ss 2 7 13.7 13.1 0.2 16.6 VHT80 Beam Forming, M0 to M9 1ss 2 10 11.8 11.2 0.2 14.7 VHT80 Beam Forming, M0 to M9 2ss 2 7 13.7 13.1 0.2 16.6 VHT80 STBC, M0 to M9 1ss 2 7 13.7 13.1 0.2 16.6 Non HT40, 6 to 54 Mbps 1 7 20.1 0.0 20.1 Non HT40, 6 to 54 Mbps 2 7 16.7 16.5 0.0 19.6 HT/VHT40, M0 to M7 1 7 21.2 0.1 21.3 HT/VHT40, M0 to M7 2 7 17.1 17.0 0.1 20.1 0 5 5 5 HT/VHT40, M8 to M15 2 7 17.1 17.0 0.1 20.1 HT/VHT40 Beam Forming, M0 to M7 2 10 16.7 16.5 0.1 19.7 HT/VHT40 Beam Forming, M8 to M15 2 7 17.1 17.0 0.1 20.1 HT/VHT40 STBC, M0 to M7 2 7 17.1 17.0 0.1 20.1 Non HT20, 6 to 54 Mbps 1 7 19.6 0.0 19.6 Non HT20, 6 to 54 Mbps 2 7 13.6 13.7 0.0 16.7 Non HT20 Beam Forming, 6 to 54 Mbps 2 10 13.6 13.7 0.0 16.7 23. 0 23. 0 20. 0 Page No: 24 of 62 0 6 5 5 This document is uncontrolled. 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Company Confidential 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 4.97 4.97 8.27 8.18 7.91 6.38 6.38 5.29 6.38 6.38 2.87 3.36 1.75 2.89 2.89 0.34 2.89 2.89 3.37 6.31 3.31 Radio Test Report No: EDCS (EDCS) HT/VHT20, M0 to M7 1 7 19.8 0.0 19.8 HT/VHT20, M0 to M7 2 7 13.7 13.9 0.0 16.9 HT/VHT20, M8 to M15 2 7 17.5 18.1 0.0 20.9 HT/VHT20 Beam Forming, M0 to M7 2 10 13.7 13.9 0.0 16.9 HT/VHT20 Beam Forming, M8 to M15 2 7 17.5 18.1 0.0 20.9 HT/VHT20 STBC, M0 to M7 2 7 17.5 18.1 0.0 20.9 Non HT80, 6 to 54 Mbps 1 7 15.9 0.0 15.9 Non HT80, 6 to 54 Mbps 2 7 15.9 15.4 0.0 18.7 VHT80, M0 to M9 1ss 1 7 21.1 0.2 21.3 VHT80, M0 to M9 1ss 2 7 19.8 19.7 0.2 23.0 0 1 6 5 VHT80, M0 to M9 2ss 2 7 19.8 19.7 0.2 23.0 VHT80 Beam Forming, M0 to M9 1ss 2 10 16.3 16.1 0.2 19.4 VHT80 Beam Forming, M0 to M9 2ss 2 7 19.8 19.7 0.2 23.0 VHT80 STBC, M0 to M9 1ss 2 7 19.8 19.7 0.2 23.0 Non HT80, 6 to 54 Mbps 1 7 21.7 0.0 21.7 Non HT80, 6 to 54 Mbps 2 7 15.7 14.9 0.0 18.4 VHT80, M0 to M9 1ss 1 7 21.9 0.2 22.1 0 9 6 5 VHT80, M0 to M9 1ss 2 7 19.8 19.0 0.2 22.6 VHT80, M0 to M9 2ss 2 7 19.8 19.0 0.2 22.6 VHT80 Beam Forming, M0 to M9 1ss 2 10 15.9 15.6 0.2 19.0 VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 2 2 7 7 19.8 19.8 19.0 19.0 0.2 0.2 22.6 22.6 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 25 of 62 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 3.16 6.15 2.14 3.15 2.14 2.14 7.07 4.30 1.71 0.05 0.05 0.60 0.05 0.05 1.27 4.64 0.91 0.38 0.38 1.05 0.38 0.38 Radio Test Report No: EDCS (EDCS) 0 0 7 5 Non HT20, 6 to 54 Mbps 1 7 19.7 0.0 19.7 Non HT20, 6 to 54 Mbps 2 7 13.2 14.1 0.0 16.7 Non HT20 Beam Forming, 6 to 54 Mbps 2 10 13.2 14.1 0.0 16.7 HT/VHT20, M0 to M7 1 7 19.9 0.0 19.9 HT/VHT20, M0 to M7 2 7 14.3 15.2 0.0 17.8 HT/VHT20, M8 to M15 2 7 16.2 17.2 0.0 19.8 HT/VHT20 Beam Forming, M0 to M7 2 10 14.3 15.2 0.0 17.8 HT/VHT20 Beam Forming, M8 to M15 2 7 16.2 17.2 0.0 19.8 HT/VHT20 STBC, M0 to M7 2 7 16.2 17.2 0.0 19.8 Non HT40, 6 to 54 Mbps 1 7 22.6 0.0 22.6 Non HT40, 6 to 54 Mbps 2 7 16.5 16.8 0.0 19.7 HT/VHT40, M0 to M7 1 7 22.5 0.1 22.6 HT/VHT40, M0 to M7 2 7 16.6 16.9 0.1 19.8 0 1 7 5 HT/VHT40, M8 to M15 2 7 19.5 19.8 0.1 22.7 HT/VHT40 Beam Forming, M0 to M7 2 10 16.6 16.9 0.1 19.8 HT/VHT40 Beam Forming, M8 to M15 2 7 19.5 19.8 0.1 22.7 HT/VHT40 STBC, M0 to M7 57 20 Non HT20, 6 to 54 Mbps 2 7 19.5 19.8 0.1 22.7 1 7 19.3 0.0 19.3 Non HT20, 6 to 54 Mbps 2 7 12.7 13.5 0.0 16.2 Non HT20 Beam Forming, 6 to 54 Mbps 2 10 12.7 13.5 0.0 16.2 HT/VHT20, M0 to M7 1 7 19.4 0.0 19.4 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 26 of 62 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 3.27 6.28 3.28 3.06 5.17 3.22 2.17 3.22 3.22 0.37 3.31 0.45 3.19 0.29 0.19 0.29 0.29 3.67 6.84 3.84 3.56 Radio Test Report No: EDCS (EDCS) HT/VHT20, M0 to M7 2 7 12.9 13.6 0.0 16.3 HT/VHT20, M8 to M15 2 7 15.6 16.5 0.0 19.1 HT/VHT20 Beam Forming, M0 to M7 2 10 12.9 13.6 0.0 16.3 HT/VHT20 Beam Forming, M8 to M15 2 7 15.6 16.5 0.0 19.1 HT/VHT20 STBC, M0 to M7 2 7 15.6 16.5 0.0 19.1 23. 0 23. 0 20. 0 23. 0 23. 0 6.68 3.87 3.68 3.87 3.87 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 27 of 62 Radio Test Report No: EDCS (EDCS) Maximum Transmit Output Power, 5610 MHz, VHT80, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 28 of 62 Radio Test Report No: EDCS (EDCS) A.4 Power Spectral Density Power Spectral Density Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Power Spectral Density Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test Procedure The rules requires maximum power spectral density measurements where the intent is to measure the maximum value of the time average of the power spectral density measured during a period of continuous transmission. 1. Create an average power spectrum for the EUT operating mode being tested by following the instructions in section II.E.2. for measuring maximum conducted output power using a spectrum analyzer or EMI receiver: select the Page No: 29 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) appropriate test method (SA-1, SA-2, SA-3, or alternatives to each) and apply it up to, but not including, the step labeled, Compute power. (This procedure is required even if the maximum conducted output power measurement was performed using a power meter, method PM.) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. b) If Method SA-3 Alternative was used and the linear mode was used in step II.E.2.g)(viii), add 1 dB to the final result to compensate for the difference between linear averaging and power averaging. 4. The result is the Maximum PSD over 1 MHz reference bandwidth. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) F. Maximum Power Spectral Density (PSD) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 30 of 62 Radio Test Report No: EDCS (EDCS) Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment Date of testing:
Start Date to Finish Date here Page No: 31 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Power Spectral Density
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-0.6 10.0 11.87 7.0 9.09 10.0 12.51 7.0 7.63 10.0 10.63 7.0 10.0 10.0 9.70 10.63 10.63 Page No: 32 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 1 2 1 2 2 2 2 2 7 10 7 10 7 10 7 7 6.6 3.2 7.4 3.0 3.0 2.8 3.0 3.0 3.0 3.1 3.1 2.7 3.1 3.1 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 6.6 6.1 7.5 6.1 6.1 5.8 6.1 6.1 10.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 7 10 10 7 10 7 10 7 7 8.9 3.0 3.0 9.4 3.1 6.4 3.1 6.4 6.4 3.1 3.1 2.9 7.3 2.9 7.3 7.3 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 8.9 6.1 6.1 9.4 6.1 9.9 6.1 9.9 9.9 10.0 7.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 3.37 0.86 2.55 0.89 3.89 1.19 3.89 3.89 1.07 0.91 0.91 0.56 0.95 0.07 0.95 0.07 0.07
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-1.9 2.4 2.4 1.5 1.5 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2 4.7 1.4 4.6 5.2 5.2 1.5 5.2 5.2 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 1 2 2 1 2 2 7 10 10 7 10 7 8.9 2.6 2.6 9.4 3.3 5.1 3.6 3.6 4.3 6.5 0.0 0.0 0.0 0.0 0.0 0.0 8.9 6.2 6.2 9.4 6.9 8.9 7.0 10.0 7.0 10.0 7.0 10.0 10.0 10.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 10.0 7.0 7.0 10.0 7.0 10.0 5.05 6.11 1.65 4.65 5.05 4.65 4.65 5.27 5.56 5.41 1.83 4.83 5.50 4.83 4.83 1.07 0.83 0.83 0.56 0.12 1.09 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 33 of 62 0 0 7 5 Radio Test Report No: EDCS (EDCS) HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 10 7 7 3.3 5.1 5.1 4.3 6.5 6.5 0.0 0.0 0.0 6.9 8.9 8.9 7 10 7 10 7 10 7 7 9.0 3.1 8.8 3.0 5.6 3.0 5.6 5.6 3.5 3.1 5.9 3.1 5.9 5.9 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 9.0 6.3 8.9 6.1 8.8 6.1 8.8 8.8 7 10 10 7 10 7 10 7 7 9.6 2.9 2.9 9.6 3.1 6.2 3.1 6.2 6.2 4.2 4.2 3.9 6.9 3.9 6.9 6.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 9.6 6.6 6.6 9.6 6.6 9.6 6.6 9.6 9.6 7.0 10.0 10.0 10.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 10.0 7.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 0.12 1.09 1.09 0.97 0.66 1.15 0.89 1.19 0.89 1.19 1.19 0.37 0.36 0.36 0.36 0.43 0.38 0.43 0.38 0.38 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 34 of 62 Radio Test Report No: EDCS (EDCS) Power Spectral Density, 5560 MHz, HT/VHT20, M8 to M15 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 35 of 62 Radio Test Report No: EDCS (EDCS) A.5 Conducted Spurious Emissions Conducted Spurious Emissions Test Requirement 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Spurious Emissions Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 36 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Add the max antenna gain + ground reflection factor (4.7 dB for frequencies between 30 MHz and 1000 MHz, and 0 dB for frequencies > 1000 MHz). Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
20-Nov-19 - 21-Nov-19 Page No: 37 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Conducted Spurs Average Upper Conducted Spurs Peak Upper This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 38 of 62 Radio Test Report No: EDCS (EDCS) Conducted Spurious Average Table
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y c n e u q e r F 0 0 5 5 Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss B d
(
i n a G a n n e t n A d e t a l e r r o C 7 7
) m B d
(
r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
-50.6
-55.3
-56.6 10
-55.3
-56.6 7 7 7
-50.3
-55.3
-56.6
-51.3
-51.8 10
-55.3
-56.6
-51.3
-51.8
-51.3
-51.8
) B d
(
n o i t c e r r o C e l c y C y t u D 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
(
r u p S d e t c u d n o C l a t o T
) m B d
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t i m L i
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n g r a M i
-43.6
-41.25 2.32
-45.9
-41.25 4.61
-42.9
-41.25 1.61
-43.3
-41.25 2.01
-45.8
-41.25 4.60
-41.5
-41.25 0.24
-42.8
-41.25 1.60
-41.5
-41.25 0.24
-41.5
-41.25 0.24
-51.1
-54.7
-56.1
-54.9
-54.9
-56.1
-54.9
-56.1 10
-55.2
-56.9
-54.9
-56.1
-54.9
-56.1 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-44.1
-41.25 2.82
-45.3
-41.25 4.05
-47.8
-41.25 6.60
-45.4
-41.25 4.15
-45.4
-41.25 4.15
-42.9
-41.25 1.66
-45.4
-41.25 4.15
-45.4
-41.25 4.15
-51.0
-51.3
-53.1
-54.8
-55.2
-57.1
-55.2
-57.1 10
-59.9
-61.1 7 7
-55.2
-57.1
-55.2
-57.1 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-44.0
-41.25 2.72
-42.1
-41.25 0.81
-47.6
-41.25 6.36
-45.8
-41.25 4.59
-45.8
-41.25 4.59
-47.3
-41.25 6.01
-45.8
-41.25 4.59
-45.8
-41.25 4.59 7 7 7 7 7 7 7 7 7 7 7 7 7 7 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 Page No: 39 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 0 5 5 5 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 7 7 7 7 7
-49.9
-50.6
-52.5
-49.4
-50.6
-52.3
-50.6
-52.3 10
-53.8
-55.7
-50.6
-52.3
-50.6
-52.3 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-42.9
-41.25 1.62
-41.4
-41.25 0.16
-42.3
-41.25 1.10
-41.3
-41.25 0.06
-41.3
-41.25 0.06
-41.6
-41.25 0.34
-41.3
-41.25 0.06
-41.3
-41.25 0.06
-50.1
-55.4
-57.1 10
-55.4
-57.1 7 7 7
-50.2
-55.1
-57.2
-50.9
-52.3 10
-55.1
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-50.9
-52.3
-50.9
-52.3 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-43.1
-41.25 1.82
-46.1
-41.25 4.87
-43.1
-41.25 1.87
-43.2
-41.25 1.91
-46.0
-41.25 4.72
-41.5
-41.25 0.24
-43.0
-41.25 1.72
-41.5
-41.25 0.24
-41.5
-41.25 0.24
-52.7
-52.7
-54.5
-51.0
-51.7
-53.2
-51.7
-53.2 10
-55.9
-57.8
-51.7
-53.2
-51.7
-53.2 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-45.7
-41.25 4.42
-43.5
-41.25 2.21
-43.8
-41.25 2.56
-42.2
-41.25 0.94
-42.2
-41.25 0.94
-43.5
-41.25 2.30
-42.2
-41.25 0.94
-42.2
-41.25 0.94
-48.5
-54.2
-54.9
-51.4
-52.3
-53.8
-52.3
-53.8 10
-56.5
-57.9
-52.3
-53.8
-52.3
-53.8 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-41.5
-41.25 0.22
-44.5
-41.25 3.24
-44.2
-41.25 2.96
-42.8
-41.25 1.54
-42.8
-41.25 1.54
-43.9
-41.25 2.69
-42.8
-41.25 1.54
-42.8
-41.25 1.54
-52.5
-58.0
-58.8 10
-58.0
-58.8 7 7 7
-52.4
-57.4
-58.0
-56.4
-56.5 0.0 0.0 0.0 0.0 0.0 0.0
-45.5
-41.25 4.22
-48.3
-41.25 7.09
-45.3
-41.25 4.09
-45.4
-41.25 4.11
-47.6
-41.25 6.39
-46.4
-41.25 5.15 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 Page No: 40 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 10
-57.4
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-46.4
-41.25 5.15
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-41.25 5.15 Radio Test Report No: EDCS (EDCS) HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 7 7 7 7 7 7 7 7 7 7 7
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-56.1
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-41.25 0.22
-44.3
-41.25 3.09
-44.1
-41.25 2.90
-46.3
-41.25 5.08
-42.8
-41.25 1.54
-43.3
-41.25 2.08
-42.8
-41.25 1.54
-42.8
-41.25 1.54 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
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-41.25 4.42
-48.0
-41.25 6.70
-45.0
-41.25 3.70
-45.5
-41.25 4.21
-47.8
-41.25 6.54
-46.0
-41.25 4.74
-44.8
-41.25 3.54
-46.0
-41.25 4.74
-46.0
-41.25 4.74 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 41 of 62 Radio Test Report No: EDCS (EDCS) Conducted Spurs Average, 5550 MHz, HT/VHT40, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 42 of 62 Radio Test Report No: EDCS (EDCS) Conducted Spurious Emissions Peak Table
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y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 0 5 5 5 B d
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-40.9
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-46.3
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r u p S d e t c u d n o C l a t o T
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-21.25 12.82
-36.3
-21.25 15.01
-33.3
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-33.9
-21.25 12.61
-36.5
-21.25 15.29
-31.3
-21.25 10.05
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-31.3
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r e w o P r u p S 3 x T 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
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-45.9
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-47.5
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-46.0
-45.9
-46.0
-45.9 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-35.9
-21.25 14.62
-34.9
-21.25 13.65
-38.9
-21.25 17.70
-35.9
-21.25 14.64
-35.9
-21.25 14.64
-34.1
-21.25 12.83
-35.9
-21.25 14.64
-35.9
-21.25 14.64
-43.7
-44.7
-43.8
-46.2
-48.1
-47.5
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-47.5 10
-50.4
-50.3 7 7 7 7 7 7
-48.1
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-48.1
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-41.5
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-43.2 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2 0.0 0.0 0.1 0.1
-36.7
-21.25 15.42
-34.2
-21.25 12.93
-39.0
-21.25 17.76
-37.6
-21.25 16.33
-37.6
-21.25 16.33
-37.1
-21.25 15.90
-37.6
-21.25 16.33
-37.6
-21.25 16.33
-34.5
-21.25 13.22
-32.5
-21.25 11.25
-34.2
-21.25 13.00
-33.4
-21.25 12.18 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 7 7 7 7 7 7 7 7 7 7 7 7 7 7 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 43 of 62 Radio Test Report No: EDCS (EDCS) HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7
-43.8
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-46.0
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-33.4
-21.25 12.18
-32.4
-21.25 11.16
-33.4
-21.25 12.18
-33.4
-21.25 12.18
-43.1
-47.4
-47.5 10
-47.4
-47.5 7 7 7
-42.1
-47.5
-46.5
-43.7
-42.1 10
-47.5
-46.5
-43.7
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-43.7
-42.1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-36.1
-21.25 14.82
-37.4
-21.25 16.16
-34.4
-21.25 13.16
-35.1
-21.25 13.81
-36.9
-21.25 15.67
-32.8
-21.25 11.52
-33.9
-21.25 12.67
-32.8
-21.25 11.52
-32.8
-21.25 11.52
-45.8
-45.8
-46.2
-44.1
-44.7
-43.8
-44.7
-43.8 10
-47.3
-48.4
-44.7
-43.8
-44.7
-43.8 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-38.8
-21.25 17.52
-36.0
-21.25 14.70
-36.9
-21.25 15.66
-34.0
-21.25 12.78
-34.0
-21.25 12.78
-34.6
-21.25 13.36
-34.0
-21.25 12.78
-34.0
-21.25 12.78
-41.6
-46.7
-47.0
-45.2
-46.2
-45.9
-46.2
-45.9 10
-49.3
-49.3
-46.2
-45.9
-46.2
-45.9
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-49.5
-49.7 10
-49.5
-49.7 7 7 7
-46.1
-49.3
-48.7
-49.7
-48.9 10
-49.3
-48.7 7 7
-49.7
-48.9
-49.7
-48.9 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-34.6
-21.25 13.32
-36.8
-21.25 15.55
-38.0
-21.25 16.76
-35.8
-21.25 14.60
-35.8
-21.25 14.60
-36.1
-21.25 14.85
-35.8
-21.25 14.60
-35.8
-21.25 14.60 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-39.2
-21.25 17.92
-39.6
-21.25 18.31
-36.6
-21.25 15.31
-39.1
-21.25 17.81
-38.9
-21.25 17.69
-39.2
-21.25 17.98
-35.9
-21.25 14.69
-39.2
-21.25 17.98
-39.2
-21.25 17.98 Page No: 44 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 7 7 7 7 7 7 7 7 7
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-45.7 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-33.4
-21.25 12.12
-36.8
-21.25 15.56
-38.3
-21.25 17.10
-38.0
-21.25 16.78
-36.2
-21.25 14.95
-35.0
-21.25 13.78
-36.2
-21.25 14.95
-36.2
-21.25 14.95
-46.3
-48.8
-49.2 10
-48.8
-49.2 7 7 7
-45.8
-49.9
-49.6
-49.3
-48.3 10
-49.9
-49.6 7 7
-49.3
-48.3
-49.3
-48.3 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-39.3
-21.25 18.02
-39.0
-21.25 17.70
-36.0
-21.25 14.70
-38.8
-21.25 17.51
-39.7
-21.25 18.44
-38.7
-21.25 17.47
-36.7
-21.25 15.44
-38.7
-21.25 17.47
-38.7
-21.25 17.47 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 45 of 62 Radio Test Report No: EDCS (EDCS) Conducted Spurs Peak, 5500 MHz, HT/VHT20, M8 to M15 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 46 of 62 Radio Test Report No: EDCS (EDCS) A.6 Conducted Bandedge 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Band Edge Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 47 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging System under Support test equipment Date of testing:
20-Nov-19 - 21-Nov-19 Page No: 48 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Conducted Bandedge Average Table
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y c n e u q e r F Mode s h t a P x T Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 i B d
(
n a G a n n e t n A d e t a l e r r o C
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(
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n o i t c e r r o C e l c y C y t u D
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l e v e L e g d e d n a B x T l a t o T
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n g r a M i 7 7
-51.7
-57.0
-58.8 10
-57.0
-58.8 7 7 7
-50.9
-57.2
-58.4
-53.2
-54.1 10
-57.2
-58.4
-53.2
-54.1
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-54.1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-44.7
-41.25 3.42
-47.8
-41.25 6.51
-44.8
-41.25 3.51
-43.9
-41.25 2.61
-47.7
-41.25 6.45
-43.6
-41.25 2.32
-44.7
-41.25 3.45
-43.6
-41.25 2.32
-43.6
-41.25 2.32
-49.6
-52.1
-54.3
-51.3
-51.3
-53.1
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-55.0
-57.0
-51.3
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-42.6
-41.25 1.32
-43.0
-41.25 1.77
-44.2
-41.25 3.00
-42.0
-41.25 0.80
-42.0
-41.25 0.80
-42.8
-41.25 1.58
-42.0
-41.25 0.80
-42.0
-41.25 0.80
-48.8
-53.4
-50.7
-49.4
-51.5
-52.9
-51.5
-52.9 10
-54.7
-56.2 7 7
-51.5
-52.9
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-41.8
-41.25 0.52
-41.8
-41.25 0.54
-42.2
-41.25 0.96
-41.9
-41.25 0.69
-41.9
-41.25 0.69
-42.2
-41.25 0.94
-41.9
-41.25 0.69
-41.9
-41.25 0.69 7 7 7 7 7 7 7 7 7 7 7 7 7 7 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 49 of 62 Radio Test Report No: EDCS (EDCS) Conducted Bandedge Average, 5530 MHz, Non HT80, 6 to 54 Mbps Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 50 of 62 Radio Test Report No: EDCS (EDCS) Conducted Bandedge Peak Table
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-37.5
-30.5
-21.25 9.22
-43.8
-45.4
-34.5
-21.25 13.23 10
-43.8
-45.4
-31.5
-21.25 10.23 7 7 7
-36.9
-29.9
-21.25 8.61
-43.7
-45.5
-34.5
-21.25 13.20
-40.4
-42.1
-31.1
-21.25 9.86 10
-43.7
-45.5
-31.5
-21.25 10.20 7 7 7 7 7 7 7
-40.4
-42.1
-31.1
-21.25 9.86
-40.4
-42.1
-31.1
-21.25 9.86
-29.7
-22.7
-21.25 1.42
-32.7
-31.0
-21.7
-21.25 0.47
-38.9
-31.8
-21.25 10.60
-38.9
-34.5
-26.1
-21.25 4.85
-38.9
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-26.1
-21.25 4.85 10
-34.3
-38.2
-22.8
-21.25 1.52 7 7 7 7 7 7 7
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-26.1
-21.25 4.85
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-34.5
-26.1
-21.25 4.85
-34.2
-27.2
-21.25 5.92
-37.4
-43.8
-29.5
-21.25 8.21
-39.2
-32.0
-21.25 10.76
-39.6
-41.3
-30.2
-21.25 8.91
-39.6
-41.3
-30.2
-21.25 8.91 10
-35.6
-41.5
-24.4
-21.25 3.17 7 7
-39.6
-41.3
-30.2
-21.25 8.91
-39.6
-41.3
-30.2
-21.25 8.91 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 51 of 62 Radio Test Report No: EDCS (EDCS) Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 7 7
-30.8
-23.8
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-44.9
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-33.4
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-44.9
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-30.4
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-29.8
-22.8
-21.25 1.51
-41.5
-39.3
-30.2
-21.25 8.96
-37.6
-38.3
-27.9
-21.25 6.63 10
-41.5
-39.3
-27.2
-21.25 5.96 7 7
-37.6
-38.3
-27.9
-21.25 6.63
-37.6
-38.3
-27.9
-21.25 6.63 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 52 of 62 Radio Test Report No: EDCS (EDCS) Conducted Bandedge Peak, 5510 MHz, Non HT40, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 53 of 62 Radio Test Report No: EDCS (EDCS) Conducted Bandedge Peak, 5700 MHz, HT/VHT20, M0 to M7 Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 54 of 62 Radio Test Report No: EDCS (EDCS) Appendix B: List of Test Equipment Used to perform the test Equip#
Manufacturer/ Model Description Last Cal Next Due RF Conducted at output antenna port 7329 OMEGA/CT485B Chart Recorder 18 Feb. 2019 18 Feb. 2020 49516 Keysight (Agilent/HP) / N9030A PXA Signal Analyzer, 3Hz to 50GHz 29 Nov. 2019 29 Nov. 2019 55097 Nattional Instruments / PXI-1042 Chassis PXI Cal Not Required Cal Not Required 56089 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 56328 Pasternack / PE5019-1 Torque Wrench 13 Feb. 2019 13 Feb. 2020 57233 Nattional Instruments / PXI-8115 Embedded Controller Cal Not Required Cal Not Required 57253 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 57254 National Instruments / PXI-2799 Switch 1x1 Verify Before Use Verify Before Use 57479 CISCO / ATIL Automation Test Insertion Loss System Verify Before Use Verify Before Use This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 55 of 62 Radio Test Report No: EDCS (EDCS) Appendix C: Abbreviation Key and Definitions The following table defines abbreviations used within this test report. Abbreviation Description Abbreviation Description F C Temp Electro Magnetic Compatibility Electro Magnetic Interference Equipment Under Test Information Technology Equipment S/N Qty Test Assessment Schedule emf Electro Static Discharge Electric Fast Transient RMS Qp Engineering Document Control System Configuration Cisco Number (unique identification number for Cisco test equipment) Calibration Av Pk kHz MHz GHz H V dB V kV V A A mS S European Norm International Electro technical Commission International Special Committee on Radio Interference Coupling/Decoupling Network Line Impedance Stabilization Network Protective Earth Ground Line 1 Line2 Line 3 Direct Current Uncorrected measurement value, as indicated by the measuring device Radio Frequency Signal Line Conducted Emissions Measurement distance Not Applicable Power Line Neutral Line Supply EMC EMI EUT ITE TAP ESD EFT EDCS Config CIS#
Cal EN IEC CISPR CDN LISN PE GND L1 L2 L3 DC RAW RF SLCE Meas dist N/A or NA P N S Degrees Fahrenheit Degrees Celsius Temperature Serial Number Quantity Electromotive force Root mean square Quasi Peak Average Peak Kilohertz (1x103) MegaHertz (1x106) Gigahertz (1x109) Horizontal Vertical decibel Volt Kilovolt (1x103) Microvolt (1x10-6) Amp Micro Amp (1x10-6) Milli Second (1x10-3) Micro Second (1x10-6) S m Spec dist SL L R AC Micro Second (1x10-6) Meter Specification distance Signal Line (or Telecom Line) Live Line Return Alternating Current This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 56 of 62 Radio Test Report No: EDCS (EDCS) Appendix D: Photographs of Test Setups Title: EUT Pictures Page No: 57 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 58 of 62 Radio Test Report No: EDCS (EDCS) Title: Radio Conducted Test Setup Page No: 59 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Appendix E: Software Used to Perform Testing EMIsoft Vasona, version 6.024 Page No: 60 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Appendix F: Test Procedures Measurements were made in accordance with KDB 789033 - D02 General UNII Test Procedures New Rules v02r01 KDB 662911 - MIMO ANSI C63.4 2014 Unintentional Radiators ANSI C63.10 2013 Intentional Radiators Test procedures are summarized below:
FCC 5GHz Test Procedures FCC 5GHz RSE Test Procedures EDCS # 1445048 EDCS # 1511600 Page No: 61 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Appendix G: Scope of Accreditation (A2LA certificate number 1178-01) The scope of accreditation of Cisco Systems, Inc. can be found on the A2LA web page at:
http://www.a2la.org/scopepdf/1178-01.pdf End This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 62 of 62
1 2 3 4 5 6 | UNI IIC EXT 8B | External Photos | 2.54 MiB | September 12 2019 |
Radio Test Report No: EDCS 18429928 Test Report IW-6300H Series Access Point Cisco Industrial Wireless Hazardous Location Access Point FCC ID: LDKESW6300 IC ID: 2461D-ESW6300 5470-5725 MHz Outside Antennas, 5dBi Gain Against the following Specifications:
CFR47 Part 15.407 RSS-247 Cisco Systems 170 West Tasman Drive San Jose, CA 95134 Approved By: Adam Walb Title: MGR. IoT Compliance Revision: 1.0 Author: Julian Land Tested By: Julian Land This report replaces any previously entered test report under EDCS 18429928.This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. Test Report Template EDCS# 11644124. Page No: 1 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. SECTION 1: OVERVIEW ......................................................................................................................................... 3 SECTION2: ASSESSMENT INFORMATION ........................................................................................................ 4 2.1 GENERAL ............................................................................................................................................................. 4 2.2 DATE OF TESTING................................................................................................................................................. 6 2.3 REPORT ISSUE DATE ............................................................................................................................................ 6 2.4 TESTING FACILITIES ............................................................................................................................................. 6 2.5 EQUIPMENT ASSESSED (EUT) .............................................................................................................................. 6 2.6 EUT DESCRIPTION ............................................................................................................................................... 7 SECTION 3: RESULT SUMMARY ........................................................................................................................ 10 3.1 RESULTS SUMMARY TABLE ............................................................................................................................... 10 SECTION 4: SAMPLE DETAILS ........................................................................................................................... 11 4.1 SAMPLE DETAILS ............................................................................................................................................... 11 4.2 SYSTEM DETAILS ............................................................................................................................................... 11 4.3 MODE OF OPERATION DETAILS .......................................................................................................................... 11 APPENDIX A: EMISSION TEST RESULTS ........................................................................................................ 12 CONDUCTED TEST SETUP DIAGRAM ........................................................................................................................ 12 TARGET MAXIMUM CHANNEL POWER .................................................................................................................... 12 A.1 DUTY CYCLE .................................................................................................................................................... 14 A.2 99% AND 26DB BANDWIDTH ............................................................................................................................ 17 A.3 MAXIMUM CONDUCTED OUTPUT POWER ......................................................................................................... 21 A.4 POWER SPECTRAL DENSITY .............................................................................................................................. 29 A.5 CONDUCTED SPURIOUS EMISSIONS ................................................................................................................... 36 A.6 CONDUCTED BANDEDGE ................................................................................................................................... 47 APPENDIX B:
LIST OF TEST EQUIPMENT USED TO PERFORM THE TEST .................................... 54 APPENDIX C: ABBREVIATION KEY AND DEFINITIONS ............................................................................. 55 APPENDIX D:
PHOTOGRAPHS OF TEST SETUPS ................................................................................... 56 APPENDIX E:
SOFTWARE USED TO PERFORM TESTING ................................................................... 59 APPENDIX F:
TEST PROCEDURES ............................................................................................................. 60 APPENDIX G: SCOPE OF ACCREDITATION (A2LA CERTIFICATE NUMBER 1178-01) ........................ 61 Page No: 2 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Section 1: Overview The samples were assessed against the tests detailed in section 3 under the requirements of the following specifications:
Specifications:
CFR47 Part 15.407 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 3 of 61 b) c) d) e) Radio Test Report No: EDCS 18429928 Section2: Assessment Information 2.1 General This report contains an assessment of an apparatus against Electromagnetic Compatibility Standards based upon tests carried out on the samples submitted. The testing was performed by and for the use of Cisco systems Inc:
With regard to this assessment, the following points should be noted:
a) The results contained in this report relate only to the items tested and were obtained in the period between the date of the initial assessment and the date of issue of the report. Manufactured products will not necessarily give identical results due to production and measurement tolerances. The apparatus was set up and exercised using the configuration and modes of operation defined in this report only. Where relevant, the apparatus was only assessed using the susceptibility criteria defined in this report and the Test Assessment Plan (TAP). All testing was performed under the following environmental conditions:
Temperature 15C to 35C (54F to 95F) Atmospheric Pressure 860mbar to 1060mbar (25.4" to 31.3") Humidity 10% to 75*%
All AC testing was performed at one or more of the following supply voltages:
110V 60 Hz (+/-20%) Units of Measurement The units of measurements defined in the appendices are reported in specific terms, which are test dependent. Where radiated measurements are concerned these are defined at a particular distance. Basic voltage measurements are defined in units of [dBuV]
As an example, the basic calculation for all measurements is as follows:
The combinations of correction factors are dependent upon the exact test configurations [see test equipment lists for further details] and may include:-
Emission level [dBuV] = Indicated voltage level [dBuV] + Cable Loss [dB] + Other correction factors [dB]
Antenna Factors, Pre Amplifier Gain, LISN Loss, Pulse Limiter Loss and Filter Insertion Loss Note: to convert the results from dBuV/m to uV/m use the following formula:-
Level in uV/m = Common Antilogarithm [(X dBuV/m)/20] = Y uV/m This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 4 of 61 Radio Test Report No: EDCS 18429928 Measurement Uncertainty Values voltage and power measurements 2 dB conducted EIRP measurements 1.4 dB radiated measurements 3.2 dB frequency measurements 2.4 10-7 temperature measurements humidity measurements 0.54 2.3%
DC and low frequency measurements 2.5%
Where relevant measurement uncertainty levels have been estimated for tests performed on the apparatus. This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2. Radiated emissions (expanded uncertainty, confidence interval 95%) 30 MHz - 300 MHz 300 MHz - 1000 MHz 1 GHz - 10 GHz 10 GHz - 18GHz 18GHz - 26.5GHz 26.5GHz - 40GHz
+/- 3.8 dB
+/- 4.3 dB
+/- 4.0 dB
+/- 8.2 dB
+/- 4.1 dB
+/- 3.9 dB Conducted emissions (expanded uncertainty, confidence interval 95%) A product is considered to comply with a requirement if the nominal measured value is below the limit line. The product is considered to not be in compliance in case the nominal measured value is above the limit line. 30 MHz 40GHz
+/- 0.38 dB This report must not be reproduced except in full, without written approval of Cisco Systems. Page No: 5 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 2.2 Date of testing 20-Nov-19 - 21-Nov-19 2.3 Report Issue Date 9/23/2019 Cisco uses an electronic system to issue, store and control the revision of test reports. This system is called the Engineering Document Control System (EDCS). The actual report issue date is embedded into the original file on EDCS. Any copies of this report, either electronic or paper, that are not on EDCS must be considered uncontrolled. 2.4 Testing facilities This assessment was performed by:
Testing Laboratory Cisco Systems, Inc. 125 West Tasman Drive (Building P) San Jose, CA 95134 USA Headquarters Cisco Systems, Inc., 170 West Tasman Drive San Jose, CA 95134, USA Registration Numbers for Industry Canada Cisco System Site Address Building P, 10m Chamber Building P, 5m Chamber Building I, 5m Chamber 125 West Tasman Dr San Jose, CA 95134 125 West Tasman Dr San Jose, CA 95134 285 W. Tasman Drive San Jose, California 95134 Site Identifier Company #: 2461N-2 Company #: 2461N-1 Company #: 2461M-1 Building 7, 5m Chamber 425 E. Tasman Drive Company #: 2461N-3 San Jose, California 95134 Test Engineers Julian Land 2.5 Equipment Assessed (EUT) IW 6300H Page No: 6 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 2.6 EUT Description The radio supports the following modes of operation. The modes are further defined in the radio Theory of Operation. The modes included in this report represent the worst case data for all modes. 802.11a - Non HT20, Two Antennas, 6 to 54 Mbps, 1ss 802.11a - Non HT20 Beam Forming, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT20, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT40, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT40, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT40, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT80, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT80, Two Antennas, 6 to 54 Mbps, 1ss 802.11ac - VHT80, One Antenna, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 1ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 STBC, Two Antennas, M0 to M9 2ss 802.11a - Non HT20, One Antenna, 6 to 54 Mbps, 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 7 of 61 Radio Test Report No: EDCS 18429928 Model / PID Differences IW-6300H-AC-x-K9, IW-6300H-DC-x-K9, IW-6300-DCW-x-K9 and ESW-6300-CON-x-K9, all have the same identical components, electronics circuitries, PCB layout and enclosure. The only differences are listed as below:
IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300-DCW-x-K9 ESW-6300-CON-x-K9 Where x can be replaced with another letter to indicate country domain. Domain letters: A, B, C, D, E, F, H, I, L, M, N, Q, R, S, T, Z Where AC is Alternating Current (AC power supply) Where DC is Direct Current (DC power supply), 54V native input Where DCW is Direct Current; wide range 10-36VDC Where K9 is encryption software. Page No: 8 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 The following antennas are supported by this product series. The data included in this report represent the worst case data for all antennas. Frequency Part Number AIR-ANT2450V-N Antenna Type Single Band Omni AIR-ANT2450V-N-HZ Single Band Omni, Hazloc 2.4 GHz AIR-ANT2480V-N AIR-ANT2450HG-N AIR-ANT2450VG-N AIR-ANT2413P2M-N Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni Single Band, Dual Polarized Directional Patch 5 GHz 2.4/5 GHz Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni AIR-ANT5180V-N AIR-ANT5150HG-N AIR-ANT5150VG-N AIR-ANT5114P2M-N AIR-ANT2547V-N=
AIR-ANT2547VG-N= Dual-band Omni, Gray AIR-ANT2547V-N-HZ= Dual-band Omni, Hazloc Dual-band Omni Single Band, Dual Polarized Directional Patch AIR-ANT2568VG-N AIR-ANT2588P3M-N= Dual-band/Dual Polarized Directional, Patch AIR-ANT2513P4M-N Dual-band Polarization Diverse Patch Array Dual-band Omni
>30 degree 5 GHz Antenna Gain
(dBi) NA NA NA NA NA NA
-3
-5
-6 5
-6
-6
-6 3 1
-5 Antenna Gain
(dBi) 5 5 8 5 5 13 8 5 5 13 4 / 7 4 / 7 4 / 7 6 / 8 8 / 8 13 / 13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 9 of 61 Radio Test Report No: EDCS 18429928 Section 3: Result Summary 3.1 Results Summary Table Conducted emissions Basic Standard FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.209 FCC 15.205 Technical Requirements / Details 99% & 26 dB Bandwidth:
The 99% occupied bandwidth is the frequency bandwidth such that, below its lower and above its upper frequency limits, the mean powers are each equal to 0.5% of the total mean power of the given emission. There is no limit for 99% OBW. The 26 dB emission is the width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 26 dB relative to the maximum level measured in the fundamental emission. Output Power:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Power Spectral Density:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bandsthe maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Conducted Spurious Emissions / Band-Edge:
15.407 (3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz. Restricted band:
Unwanted emissions falling within the restricted bands, as defined in FCC 15.205 (a) must also comply with the radiated emission limits specified in FCC 15.209 (a). Result Pass Pass Pass Pass Pass Radiated Emissions (General requirements) Basic Standard FCC 15.209 FCC 15.205 FCC 15.207 Technical Requirements / Details TX Spurious Emissions:
Except as provided elsewhere in this subpart, the emissions from an intentional radiator shall not exceed the field strength levels specified in the filed strength limits table in this section. AC conducted Emissions:
Except when the requirements applicable to a given device state otherwise, for any radio apparatus equipped to operate from the public utility AC power supply, either directly or indirectly (such as with a battery charger), the radio frequency voltage of emissions conducted back onto the AC power lines in the frequency range of 0.15 MHz to 30 MHz shall not exceed the limits shown in the table in these sections. The more stringent limit applies at the frequency range boundaries. Result Pass Pass Page No: 10 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Section 4: Sample Details Note: Each sample was evaluated to ensure that its condition was suitable to be used as a test sample prior to the commencement of testing. 4.1 Sample Details Sample No. S01 S02 Equipment Details Manufacturer Hardware Rev. Firmware Rev. Software Rev. Serial Number IW-6300H-DC-B-K9 FSP150-AWAN3 Cisco Systems, Inc. FSP Group Inc. 11
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9.1.8.1 9.0.5.5-W8964 FOC23241G16
-
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H00000063 4.2 System Details System #
1 EUT and Power Supply 4.3 Mode of Operation Details Mode#
Description Description Samples S01, S02 Comments 1 Continuous Transmitting Continuous Transmitting 98% duty cycle All measurements were made in accordance with ANSI C63.10:2013 KDB 789033 D02 General UNII Test Procedures New Rules v01r03 KDB 662911 D01 Multiple Transmitter Output v02r01 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 11 of 61 Radio Test Report No: EDCS 18429928 Appendix A: Emission Test Results Conducted Test Setup Diagram Target Maximum Channel Power The following table details the maximum supported Total Channel Power for all operating modes. Operating Mode Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M15 HT/VHT20 Beam Forming, M0 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 HT/VHT40 Beam Forming, M0 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss VHT80 Beam Forming, M0 to M9, M0 to M9 1-2ss Maximum Channel Power
(dBm) Frequency (MHz) 5500 19 16 19 18 18 5510 16 17 17 17 5530 14 16 16 5560 20 16 19 19 19 5550 20 21 20 20 5610 19 22 22 5700 20 16 20 20 20 5710 21 22 22 22 5690 18 22 22 Page No: 12 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 VHT80 STBC, M0 to M9 1ss 16 22 22 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 13 of 61 Radio Test Report No: EDCS 18429928 A.1 Duty Cycle Duty Cycle Test Requirement From KDB 789033 D02 General UNII Test Procedures New Rules v02r01 B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level 1. All measurements are to be performed with the EUT transmitting at 100 percent duty cycle at its maximum power control level; however, if 100 percent duty cycle cannot be achieved, measurements of duty cycle, x, and maximum-power transmission duration, T, are required for each tested mode of operation. Duty Cycle Test Method From KDB 789033 D02 General UNII Test Procedures New Rules v02r01:
B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level The zero-span mode on a spectrum analyzer or EMI receiver, if the response time and spacing between bins on the sweep are sufficient to permit accurate measurements of the on and off times of the transmitted signal. Set the center frequency of the instrument to the center frequency of the transmission. Set RBW EBW if possible; otherwise, set RBW to the largest available value. Set VBW RBW. Set detector = peak or average. The zero-span measurement method shall not be used unless both RBW and VBW are > 50/T, where T is defined in section II.B.1.a), and the number of sweep points across duration T exceeds 100. (For example, if VBW and/or RBW are limited to 3 MHz, then the zero-span method of measuring duty cycle shall not be used if T 16.7 microseconds.) Duty Cycle Test Information Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix C for list of test equipment Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Date of testing:
20-Nov-19 - 21-Nov-19 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 14 of 61 Radio Test Report No: EDCS 18429928 Duty Cycle Data Table Duty Cycle table and screen captures are shown below for power/psd modes. Frequency Mode Data Rate 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 Duty Cycle correction
(dB) 0.0 0.0 0.0 0.1 0.0 0.2 0.0 0.1 0.0 0.0 0.0 0.2 0.0 0.2 0.0 0.0 0.0 0.1 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 15 of 61 Radio Test Report No: EDCS 18429928 Duty Cycle, 5530 MHz, VHT80, M0 to M9, M0 to M9 1-2ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 16 of 61 Radio Test Report No: EDCS 18429928 A.2 99% and 26dB Bandwidth 99% and 26dB Bandwidth Test Requirement There is no requirement for the value of bandwidth. However, the 26dB BW (EBW) is used to calculate the power limits in 15.407 (a) (2). Power measurements are made using the 99% Bandwidth as the integration bandwidth. Band-crossing emissions: For an emission that crosses the boundary between two adjacent U-NII bands, the boundary frequency between the bands serves as one edge for defining the portion of the EBW that falls within a particular U-NII band. However, the -26 dB points are measured relative to the highest point on the contiguous segmentregardless of which band contains that highest point (Figure4). 99% and 26dB Bandwidth Test Procedure Ref. KDB 789033 Section D. 99 Percent Occupied Bandwidth ANSI C63.10: 2013 Section 6.9.3 KDB 662911 99% BW Test Parameters 1. Set center frequency to the nominal EUT channel center frequency. 2. Set span = 1.5 times to 5.0 times the OBW. 3. Set RBW = 1 % to 5 % of the OBW 4. Set VBW 3 RBW 5. Video averaging is not permitted. Where practical, a sample detection and single sweep mode shall be used. Otherwise, peak detection and max hold mode (until the trace stabilizes) shall be used. 6. Use the 99 % power bandwidth function of the instrument (if available). Ref KDB 789033 in Section C. Measurement Bandwidth, Section 1 26 BW Test parameters X dB BW = -26dB (using the OBW function of the spectrum analyzer) Emission Bandwidth (EBW) a) Set RBW = approximately 1% of the emission bandwidth. b) Set the VBW > RBW. c) Detector = Peak. d) Trace mode = max hold. e) Measure the maximum width of the emission that is 26 dB down from the maximum of the emission. Page No: 17 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Compare this with the RBW setting of the analyzer. Readjust RBW and repeat measurement as needed until the RBW/EBW ratio is approximately 1%. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
Start Date to Finish Date here Page No: 18 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 99% and 26dB Bandwidth Table Frequency
(MHz) 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Mode Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Data Rate 26dB BW 99% BW
(Mbps)
(MHz) 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 19.7 20.1 42.0 40.6 82.7 82.1 41.1 40.9 19.8 20.1 82.6 82.3 83.4 82.3 19.8 20.2 41.5 40.9 14.9 15.1
(MHz) 16.619 17.643 36.408 36.211 76.453 76.438 36.415 36.182 16.619 17.641 76.532 76.364 76.498 76.524 16.626 17.645 36.422 36.210 13.287 13.794 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 19 of 61 Radio Test Report No: EDCS 18429928 26dB / 99% Bandwidth, 5720 MHz, Non HT20, 6 to 54 Mbps This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 20 of 61 Radio Test Report No: EDCS 18429928 A.3 Maximum Conducted Output Power Maximum Conducted Output Power Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Maximum Conducted Output Power Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 ANSI C63.10: 2013 Maximum Conducted Output Power Test Procedure 1. Set the radio in the continuous transmitting mode at full power 2. Compute power by integrating the spectrum across the EBW (or alternatively entire 99% OBW) of the signal using the instruments band power measurement function. The integration shall be performed using the spectrum analyzer band-power measurement function with band limits set equal to the EBW or the Page No: 21 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 OBW band edges. 3. Capture graphs and record pertinent measurement data. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Measurement using a Spectrum Analyzer or EMI Receiver (SA), (d) Method SA-2 Maximum Conducted Output Power Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 System under Support test equipment Date of testing:
Start Date to Finish Date here Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 22 of 61 Radio Test Report No: EDCS 18429928 Maximum Output Power
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n g r a M i Non HT20, 6 to 54 Mbps 1 8 18.9 0.0 18.9 Non HT20, 6 to 54 Mbps 2 8 13.7 12.5 0.0 16.2 Non HT20 Beam Forming, 6 to 54 Mbps 2 11 13.7 12.5 0.0 16.2 HT/VHT20, M0 to M7 1 8 19.1 0.0 19.1 HT/VHT20, M0 to M7 2 8 13.8 12.7 0.0 16.3 HT/VHT20, M8 to M15 2 8 15.9 14.7 0.0 18.4 HT/VHT20 Beam Forming, M0 to M7 2 11 13.8 12.7 0.0 16.3 HT/VHT20 Beam Forming, M8 to M15 2 8 15.9 14.7 0.0 18.4 HT/VHT20 STBC, M0 to M7 2 8 15.9 14.7 0.0 18.4 Non HT40, 6 to 54 Mbps 1 8 15.5 0.0 15.5 Non HT40, 6 to 54 Mbps 2 8 13.5 12.6 0.0 16.1 HT/VHT40, M0 to M7 1 8 15.4 0.1 15.5 HT/VHT40, M0 to M7 2 8 14.3 13.4 0.1 16.9 HT/VHT40, M8 to M15 2 8 14.3 13.4 0.1 16.9 HT/VHT40 Beam Forming, M0 to M7 2 11 13.4 12.5 0.1 16.0 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 Page No: 23 of 61 0 1 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 3.07 5.82 2.82 2.86 5.66 3.61 2.66 3.61 3.61 6.47 5.89 6.55 5.06 5.06 2.97 Radio Test Report No: EDCS 18429928 0 3 5 5 HT/VHT40 Beam Forming, M8 to M15 2 8 14.3 13.4 0.1 16.9 HT/VHT40 STBC, M0 to M7 2 8 14.3 13.4 0.1 16.9 Non HT80, 6 to 54 Mbps 1 8 13.3 0.0 13.3 Non HT80, 6 to 54 Mbps 2 8 11.3 10.8 0.0 14.1 VHT80, M0 to M9 1ss 1 8 13.7 0.2 13.9 VHT80, M0 to M9 1ss 2 8 12.8 12.1 0.2 15.7 VHT80, M0 to M9 2ss 2 8 12.8 12.1 0.2 15.7 VHT80 Beam Forming, M0 to M9 1ss 2 11 10.8 10.3 0.2 13.8 VHT80 Beam Forming, M0 to M9 2ss 2 8 12.8 12.1 0.2 15.7 VHT80 STBC, M0 to M9 1ss 2 8 12.8 12.1 0.2 15.7 Non HT40, 6 to 54 Mbps 1 8 20.1 0.0 20.1 Non HT40, 6 to 54 Mbps 2 8 15.1 14.9 0.0 18.0 HT/VHT40, M0 to M7 1 8 21.2 0.1 21.3 HT/VHT40, M0 to M7 2 8 16.7 16.5 0.1 19.7 0 5 5 5 HT/VHT40, M8 to M15 2 8 16.7 16.5 0.1 19.7 HT/VHT40 Beam Forming, M0 to M7 2 11 15.2 14.9 0.1 18.1 HT/VHT40 Beam Forming, M8 to M15 2 8 16.7 16.5 0.1 19.7 HT/VHT40 STBC, M0 to M7 2 8 16.7 16.5 0.1 19.7 Non HT20, 6 to 54 Mbps 1 8 19.6 0.0 19.6 Non HT20, 6 to 54 Mbps 2 8 12.6 12.8 0.0 15.7 Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 2 1 11 8 12.6 18.7 12.8 0.0 0.0 15.7 18.7 22. 0 22. 0 19. 0 22. Page No: 24 of 61 0 6 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 5.06 5.06 8.67 7.90 8.10 6.34 6.34 5.24 6.34 6.34 1.87 3.96 0.75 2.34 2.34 0.89 2.34 2.34 2.37 6.26 3.26 3.26 Radio Test Report No: EDCS 18429928 HT/VHT20, M0 to M7 2 8 12.8 13.0 0.0 16.0 HT/VHT20, M8 to M15 2 8 16.2 16.6 0.0 19.5 HT/VHT20 Beam Forming, M0 to M7 2 11 12.8 13.0 0.0 16.0 HT/VHT20 Beam Forming, M8 to M15 2 8 16.2 16.6 0.0 19.5 HT/VHT20 STBC, M0 to M7 2 8 16.2 16.6 0.0 19.5 Non HT80, 6 to 54 Mbps 1 8 15.9 0.0 15.9 Non HT80, 6 to 54 Mbps 2 8 15.9 15.4 0.0 18.7 VHT80, M0 to M9 1ss 1 8 21.1 0.2 21.3 VHT80, M0 to M9 1ss 2 8 18.6 18.5 0.2 21.8 0 1 6 5 VHT80, M0 to M9 2ss 2 8 18.6 18.5 0.2 21.8 VHT80 Beam Forming, M0 to M9 1ss 2 11 15.0 15.0 0.2 18.2 VHT80 Beam Forming, M0 to M9 2ss 2 8 18.6 18.5 0.2 21.8 VHT80 STBC, M0 to M9 1ss 2 8 18.6 18.5 0.2 21.8 Non HT80, 6 to 54 Mbps 1 8 15.7 0.0 15.7 Non HT80, 6 to 54 Mbps 2 8 15.7 14.9 0.0 18.4 VHT80, M0 to M9 1ss 1 8 20.8 0.2 21.0 VHT80, M0 to M9 1ss 2 8 18.9 17.7 0.2 21.5 0 9 6 5 VHT80, M0 to M9 2ss 2 8 18.9 17.7 0.2 21.5 VHT80 Beam Forming, M0 to M9 1ss 2 11 15.9 15.6 0.2 19.0 VHT80 Beam Forming, M0 to M9 2ss 2 8 18.9 17.7 0.2 21.5 VHT80 STBC, M0 to M9 1ss 2 8 18.9 17.7 0.2 21.5 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 25 of 61 0 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 6.05 2.54 3.05 2.54 2.54 6.07 3.30 0.71 0.25 0.25 0.80 0.25 0.25 6.27 3.64 1.01 0.46 0.46 0.05 0.46 0.46 Radio Test Report No: EDCS 18429928 Non HT20, 6 to 54 Mbps 1 8 19.7 0.0 19.7 Non HT20, 6 to 54 Mbps 2 8 12.1 13.1 0.0 15.7 Non HT20 Beam Forming, 6 to 54 Mbps 2 11 12.1 13.1 0.0 15.7 HT/VHT20, M0 to M7 1 8 18.9 0.0 18.9 0 0 7 5 HT/VHT20, M0 to M7 2 8 12.3 13.3 0.0 15.9 HT/VHT20, M8 to M15 2 8 16.2 17.2 0.0 19.8 HT/VHT20 Beam Forming, M0 to M7 2 11 12.3 13.3 0.0 15.9 HT/VHT20 Beam Forming, M8 to M15 2 8 16.2 17.2 0.0 19.8 HT/VHT20 STBC, M0 to M7 2 8 16.2 17.2 0.0 19.8 Non HT40, 6 to 54 Mbps 1 8 20.5 0.0 20.5 Non HT40, 6 to 54 Mbps 2 8 15.8 16.1 0.0 19.0 HT/VHT40, M0 to M7 1 8 21.5 0.1 21.6 HT/VHT40, M0 to M7 2 8 15.6 15.8 0.1 18.8 0 1 7 5 HT/VHT40, M8 to M15 2 8 18.7 19.0 0.1 21.9 HT/VHT40 Beam Forming, M0 to M7 2 11 15.6 15.8 0.1 18.8 HT/VHT40 Beam Forming, M8 to M15 2 8 18.7 19.0 0.1 21.9 HT/VHT40 STBC, M0 to M7 57 20 Non HT20, 6 to 54 Mbps 2 8 18.7 19.0 0.1 21.9 1 8 18.5 0.0 18.5 Non HT20, 6 to 54 Mbps 2 8 11.9 12.6 0.0 15.3 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 26 of 61 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 22. 0 2.27 6.33 3.33 3.06 6.12 2.22 3.12 2.22 2.22 1.47 3.01 0.45 3.24 0.09 0.24 0.09 0.09 3.47 6.69 Radio Test Report No: EDCS 18429928 Non HT20 Beam Forming, 6 to 54 Mbps 2 11 11.9 12.6 0.0 15.3 HT/VHT20, M0 to M7 1 8 18.5 0.0 18.5 HT/VHT20, M0 to M7 2 8 12.0 12.7 0.0 15.4 HT/VHT20, M8 to M15 2 8 14.6 15.6 0.0 18.2 HT/VHT20 Beam Forming, M0 to M7 2 11 12.0 12.7 0.0 15.4 HT/VHT20 Beam Forming, M8 to M15 2 8 14.6 15.6 0.0 18.2 HT/VHT20 STBC, M0 to M7 2 8 14.6 15.6 0.0 18.2 19. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 3.69 3.46 6.58 3.82 3.58 3.82 3.82 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 27 of 61 Radio Test Report No: EDCS 18429928 Maximum Transmit Output Power, 5690 MHz, VHT80 Beam Forming, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 28 of 61 Radio Test Report No: EDCS 18429928 A.4 Power Spectral Density Power Spectral Density Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Power Spectral Density Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test Procedure The rules requires maximum power spectral density measurements where the intent is to measure the maximum value of the time average of the power spectral density measured during a period of continuous transmission. 1. Create an average power spectrum for the EUT operating mode being tested by following the instructions in section II.E.2. for measuring maximum conducted output power using a spectrum analyzer or EMI receiver: select the Page No: 29 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 appropriate test method (SA-1, SA-2, SA-3, or alternatives to each) and apply it up to, but not including, the step labeled, Compute power. (This procedure is required even if the maximum conducted output power measurement was performed using a power meter, method PM.) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. b) If Method SA-3 Alternative was used and the linear mode was used in step II.E.2.g)(viii), add 1 dB to the final result to compensate for the difference between linear averaging and power averaging. 4. The result is the Maximum PSD over 1 MHz reference bandwidth. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) F. Maximum Power Spectral Density (PSD) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 30 of 61 Radio Test Report No: EDCS 18429928 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment Date of testing:
Start Date to Finish Date here Page No: 31 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Power Spectral Density
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n g r a M i 0.77 0.27 0.27 0.96 0.56 1.46 0.56 1.46 1.46 7.07 3.21 7.45 2.80 5.80 3.78 5.80 5.80 12.37 8.50 12.30 7.80 10.80 9.58 10.80 10.80 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 1 2 1 2 2 2 2 2 8 11 8 11 8 11 8 8 6.6 1.7 7.4 2.8 2.8 1.2 2.8 2.8 1.7 2.7 2.7 1.1 2.7 2.7 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 6.6 4.7 7.5 5.8 5.8 4.2 5.8 5.8 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 8 11 11 8 11 8 11 8 8 8.9 2.0 2.0 7.7 1.9 5.3 1.9 5.3 5.3 2.2 2.2 1.8 5.7 1.8 5.7 5.7 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 8.9 5.1 5.1 7.7 4.9 8.6 4.9 8.6 8.6 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 1 2 1 2 2 2 2 2 8 11 8 11 8 11 8 8
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-1.0 1.4 3.6 4.1 4.1 1.5 4.1 4.1 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 1 2 2 1 2 2 8 11 11 8 11 8 8.9 1.4 1.4 7.9 1.3 5.1 2.7 2.7 2.4 6.5 0.0 0.0 0.0 0.0 0.0 0.0 8.9 5.1 5.1 7.9 4.9 8.9 9.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 6.0 9.0 6.0 9.0 2.37 1.26 1.55 0.19 3.19 1.79 3.19 3.19 0.07 0.86 0.86 1.26 1.10 0.44 1.10 0.44 0.44 9.87 4.05 5.11 1.55 4.55 5.20 4.55 4.55 9.97 4.56 5.41 1.90 4.90 4.50 4.90 4.90 0.07 0.86 0.86 1.06 1.06 0.09 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 33 of 61 0 0 7 5 Radio Test Report No: EDCS 18429928 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 11 8 8 1.3 5.1 5.1 2.4 6.5 6.5 0.0 0.0 0.0 4.9 8.9 8.9 8 11 8 11 8 11 8 8 7.3 2.6 7.6 1.8 4.6 1.8 4.6 4.6 2.8 1.9 5.2 1.9 5.2 5.2 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 7.3 5.7 7.7 4.9 8.0 4.9 8.0 8.0 8 11 11 8 11 8 11 8 8 8.7 2.6 2.6 8.5 2.4 4.8 2.4 4.8 4.8 2.9 2.9 3.1 5.9 3.1 5.9 5.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 8.7 5.8 5.8 8.5 5.8 8.4 5.8 8.4 8.4 6.0 9.0 9.0 9.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 1.06 0.09 0.09 1.67 0.26 1.35 1.09 1.03 1.09 1.03 1.03 0.27 0.20 0.20 0.46 0.18 0.56 0.18 0.56 0.56 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 34 of 61 Radio Test Report No: EDCS 18429928 Power Spectral Density, 5560 MHz, Non HT20, 6 to 54 Mbps Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 35 of 61 Radio Test Report No: EDCS 18429928 A.5 Conducted Spurious Emissions Conducted Spurious Emissions Test Requirement 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Spurious Emissions Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 36 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Add the max antenna gain + ground reflection factor (4.7 dB for frequencies between 30 MHz and 1000 MHz, and 0 dB for frequencies > 1000 MHz). Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
20-Nov-19 - 21-Nov-19 Page No: 37 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Conducted Spurs Average Upper Conducted Spurs Peak Upper This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 38 of 61 Radio Test Report No: EDCS 18429928 Conducted Spurious Average Table
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-41.25 3.74 8 8 8 8 8 8 8 8 8 8 8 8 8 8 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 Page No: 39 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 0 5 5 5 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 8 8 8 8 8
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-49.1 8 8 8
-45.7
-49.9
-48.7
-49.5
-48.7 11
-49.9
-48.7 8 8
-49.5
-48.7
-49.5
-48.7 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-38.6
-21.25 17.32
-38.1
-21.25 16.85
-38.0
-21.25 16.80
-38.0
-21.25 16.74
-35.2
-21.25 13.94
-35.0
-21.25 13.74
-35.2
-21.25 13.94
-35.2
-21.25 13.94 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-38.5
-21.25 17.22
-38.4
-21.25 17.14
-35.4
-21.25 14.14
-37.7
-21.25 16.41
-38.2
-21.25 16.96
-38.0
-21.25 16.78
-35.2
-21.25 13.96
-38.0
-21.25 16.78
-38.0
-21.25 16.78 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 45 of 61 Radio Test Report No: EDCS 18429928 Conducted Spurs Peak, 5500 MHz, Non HT20 Beam Forming, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 46 of 61 Radio Test Report No: EDCS 18429928 A.6 Conducted Bandedge 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Band Edge Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI Page No: 47 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 C63.10:2013 section 14.3.2.2) 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging System under Support test equipment Date of testing:
20-Nov-19 - 21-Nov-19 Page No: 48 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Conducted Bandedge Average Table
) i
) z H M
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y c n e u q e r F Mode s h t a P x T Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 i B d
(
n a G a n n e t n A d e t a l e r r o C
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(
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l e v e L e g d e d n a B x T l a t o T
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(
n g r a M i 8 8
-52.8
-57.5
-58.7 11
-57.5
-58.7 8 8 8
-52.4
-58.4
-59.2
-57.5
-58.9 11
-58.4
-59.2
-57.5
-58.9
-57.5
-58.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-44.8
-41.25 3.52
-47.0
-41.25 5.77
-44.0
-41.25 2.77
-44.4
-41.25 3.11
-47.7
-41.25 6.48
-47.1
-41.25 5.84
-44.7
-41.25 3.48
-47.1
-41.25 5.84
-47.1
-41.25 5.84
-49.6
-54.6
-57.1
-51.3
-53.5
-54.8
-53.5
-54.8 11
-55.0
-57.0
-53.5
-54.8
-53.5
-54.8 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-41.6
-41.25 0.32
-44.6
-41.25 3.38
-43.2
-41.25 2.00
-43.0
-41.25 1.78
-43.0
-41.25 1.78
-41.8
-41.25 0.58
-43.0
-41.25 1.78
-43.0
-41.25 1.78
-51.0
-56.8
-55.2
-51.5
-52.9
-54.0
-52.9
-54.0 11
-55.7
-57.8 8 8
-52.9
-54.0
-52.9
-54.0 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-43.0
-41.25 1.72
-44.9
-41.25 3.63
-43.3
-41.25 2.05
-42.2
-41.25 0.96
-42.2
-41.25 0.96
-42.4
-41.25 1.17
-42.2
-41.25 0.96
-42.2
-41.25 0.96 8 8 8 8 8 8 8 8 8 8 8 8 8 8 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 49 of 61 Radio Test Report No: EDCS 18429928 Conducted Bandedge Average, 5510 MHz, Non HT40, 6 to 54 Mbps Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 50 of 61 Radio Test Report No: EDCS 18429928 Conducted Bandedge Peak Table
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-32.0
-21.25 10.72
-45.0
-45.3
-34.1
-21.25 12.85 i B d
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n a G a n n e t n A d e t a l e r r o C 8 8 11
-45.0
-45.3
-31.1
-21.25 9.85 8 8 8
-38.6
-30.6
-21.25 9.31
-41.6
-46.1
-32.2
-21.25 10.99
-37.4
-43.7
-28.4
-21.25 7.19 11
-41.6
-46.1
-29.2
-21.25 7.99 8 8 8 8 8 8 8
-37.4
-43.7
-28.4
-21.25 7.19
-37.4
-43.7
-28.4
-21.25 7.19
-29.7
-21.7
-21.25 0.42
-35.7
-36.3
-24.9
-21.25 3.70
-38.9
-30.8
-21.25 9.60
-34.5
-35.3
-23.8
-21.25 2.56
-34.5
-35.3
-23.8
-21.25 2.56 11
-34.3
-38.2
-21.8
-21.25 0.52 8 8 8 8 8 8 8
-34.5
-35.3
-23.8
-21.25 2.56
-34.5
-35.3
-23.8
-21.25 2.56
-37.5
-29.5
-21.25 8.22
-44.4
-43.0
-32.6
-21.25 11.35
-39.6
-31.4
-21.25 10.15
-41.5
-38.4
-28.5
-21.25 7.23
-41.5
-38.4
-28.5
-21.25 7.23 11
-45.4
-41.5
-28.8
-21.25 7.58 8 8
-41.5
-38.4
-28.5
-21.25 7.23
-41.5
-38.4
-28.5
-21.25 7.23 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 51 of 61 Radio Test Report No: EDCS 18429928 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 8 8
-30.8
-22.8
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-21.25 11.95 11
-46.0
-43.0
-30.2
-21.25 8.95 8 8 8
-30.0
-22.0
-21.25 0.71
-43.1
-41.8
-31.3
-21.25 10.10
-37.6
-38.3
-26.9
-21.25 5.63 11
-43.1
-41.8
-28.3
-21.25 7.10 8 8
-37.6
-38.3
-26.9
-21.25 5.63
-37.6
-38.3
-26.9
-21.25 5.63 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 52 of 61 Radio Test Report No: EDCS 18429928 Conducted Bandedge Peak, 5510 MHz, Non HT40, 6 to 54 Mbps Antenna A Conducted Bandedge Peak, 5700 MHz, HT/VHT20, M0 to M7 Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 53 of 61 Radio Test Report No: EDCS 18429928 Appendix B: List of Test Equipment Used to perform the test Equip#
Manufacturer/ Model Description Last Cal Next Due RF Conducted at output antenna port 7329 OMEGA/CT485B Chart Recorder 18 Feb. 2019 18 Feb. 2020 49516 Keysight (Agilent/HP) / N9030A PXA Signal Analyzer, 3Hz to 50GHz 29 Nov. 2019 29 Nov. 2019 55097 Nattional Instruments / PXI-1042 Chassis PXI Cal Not Required Cal Not Required 56089 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 56328 Pasternack / PE5019-1 Torque Wrench 13 Feb. 2019 13 Feb. 2020 57233 Nattional Instruments / PXI-8115 Embedded Controller Cal Not Required Cal Not Required 57253 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 57254 National Instruments / PXI-2799 Switch 1x1 Verify Before Use Verify Before Use 57479 CISCO / ATIL Automation Test Insertion Loss System Verify Before Use Verify Before Use This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 54 of 61 Radio Test Report No: EDCS 18429928 Appendix C: Abbreviation Key and Definitions The following table defines abbreviations used within this test report. Abbreviation Description Abbreviation Description F C Temp Electro Magnetic Compatibility Electro Magnetic Interference Equipment Under Test Information Technology Equipment S/N Qty Test Assessment Schedule emf Electro Static Discharge Electric Fast Transient RMS Qp Engineering Document Control System Configuration Cisco Number (unique identification number for Cisco test equipment) Calibration Av Pk kHz MHz GHz H V dB V kV V A A mS S European Norm International Electro technical Commission International Special Committee on Radio Interference Coupling/Decoupling Network Line Impedance Stabilization Network Protective Earth Ground Line 1 Line2 Line 3 Direct Current Uncorrected measurement value, as indicated by the measuring device Radio Frequency Signal Line Conducted Emissions Measurement distance Not Applicable Power Line Neutral Line Supply EMC EMI EUT ITE TAP ESD EFT EDCS Config CIS#
Cal EN IEC CISPR CDN LISN PE GND L1 L2 L3 DC RAW RF SLCE Meas dist N/A or NA P N S Degrees Fahrenheit Degrees Celsius Temperature Serial Number Quantity Electromotive force Root mean square Quasi Peak Average Peak Kilohertz (1x103) MegaHertz (1x106) Gigahertz (1x109) Horizontal Vertical decibel Volt Kilovolt (1x103) Microvolt (1x10-6) Amp Micro Amp (1x10-6) Milli Second (1x10-3) Micro Second (1x10-6) S m Spec dist SL L R AC Micro Second (1x10-6) Meter Specification distance Signal Line (or Telecom Line) Live Line Return Alternating Current This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 55 of 61 Radio Test Report No: EDCS 18429928 Appendix D: Photographs of Test Setups Title: EUT Pictures Page No: 56 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 57 of 61 Radio Test Report No: EDCS 18429928 Title: Radio Conducted Test Setup Page No: 58 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Appendix E: Software Used to Perform Testing EMIsoft Vasona, version 6.024 Page No: 59 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Appendix F: Test Procedures Measurements were made in accordance with KDB 789033 - D02 General UNII Test Procedures New Rules v02r01 KDB 662911 - MIMO ANSI C63.4 2014 Unintentional Radiators ANSI C63.10 2013 Intentional Radiators Test procedures are summarized below:
FCC 5GHz Test Procedures FCC 5GHz RSE Test Procedures EDCS # 1445048 EDCS # 1511600 Page No: 60 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429928 Appendix G: Scope of Accreditation (A2LA certificate number 1178-01) The scope of accreditation of Cisco Systems, Inc. can be found on the A2LA web page at:
http://www.a2la.org/scopepdf/1178-01.pdf End This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 61 of 61
1 2 3 4 5 6 | UNI IIC Ext 5B | External Photos | 2.95 MiB | September 12 2019 |
Radio Test Report No: EDCS (EDCS) Test Report IW-6300H Series Access Point Cisco Industrial Wireless Hazardous Location Access Point FCC ID: LDKESW6300 IC ID: 2461D-ESW6300 5470-5725 MHz Outside Antennas, 5dBi Gain Against the following Specifications:
CFR47 Part 15.407 RSS-247 Cisco Systems 170 West Tasman Drive San Jose, CA 95134 Approved By: Adam Walb Title: MGR. IoT Compliance Revision: 1.0 Author: Julian Land Tested By: Julian Land This report replaces any previously entered test report under EDCS (EDCS).This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. Test Report Template EDCS#
11644124. Page No: 1 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. SECTION 1: OVERVIEW ......................................................................................................................................... 3 SECTION2: ASSESSMENT INFORMATION ........................................................................................................ 4 2.1 GENERAL ............................................................................................................................................................. 4 2.2 DATE OF TESTING................................................................................................................................................. 6 2.3 REPORT ISSUE DATE ............................................................................................................................................ 6 2.4 TESTING FACILITIES ............................................................................................................................................. 6 2.5 EQUIPMENT ASSESSED (EUT) .............................................................................................................................. 6 2.6 EUT DESCRIPTION ............................................................................................................................................... 7 SECTION 3: RESULT SUMMARY ........................................................................................................................ 10 3.1 RESULTS SUMMARY TABLE ............................................................................................................................... 10 SECTION 4: SAMPLE DETAILS ........................................................................................................................... 11 4.1 SAMPLE DETAILS ............................................................................................................................................... 11 4.2 SYSTEM DETAILS ............................................................................................................................................... 11 4.3 MODE OF OPERATION DETAILS .......................................................................................................................... 11 APPENDIX A: EMISSION TEST RESULTS ........................................................................................................ 12 CONDUCTED TEST SETUP DIAGRAM ........................................................................................................................ 12 TARGET MAXIMUM CHANNEL POWER .................................................................................................................... 12 A.1 DUTY CYCLE .................................................................................................................................................... 14 A.2 99% AND 26DB BANDWIDTH ............................................................................................................................ 17 A.3 MAXIMUM CONDUCTED OUTPUT POWER ......................................................................................................... 21 A.4 POWER SPECTRAL DENSITY .............................................................................................................................. 29 A.5 CONDUCTED SPURIOUS EMISSIONS ................................................................................................................... 36 A.6 CONDUCTED BANDEDGE ................................................................................................................................... 47 APPENDIX B:
LIST OF TEST EQUIPMENT USED TO PERFORM THE TEST .................................... 55 APPENDIX C: ABBREVIATION KEY AND DEFINITIONS ............................................................................. 56 APPENDIX D:
PHOTOGRAPHS OF TEST SETUPS ................................................................................... 57 APPENDIX E:
SOFTWARE USED TO PERFORM TESTING ................................................................... 60 APPENDIX F:
TEST PROCEDURES ............................................................................................................. 61 APPENDIX G: SCOPE OF ACCREDITATION (A2LA CERTIFICATE NUMBER 1178-01) ........................ 62 Page No: 2 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Section 1: Overview The samples were assessed against the tests detailed in section 3 under the requirements of the following specifications:
Specifications:
CFR47 Part 15.407 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 3 of 62 b) c) d) e) Radio Test Report No: EDCS (EDCS) Section2: Assessment Information 2.1 General This report contains an assessment of an apparatus against Electromagnetic Compatibility Standards based upon tests carried out on the samples submitted. The testing was performed by and for the use of Cisco systems Inc:
With regard to this assessment, the following points should be noted:
a) The results contained in this report relate only to the items tested and were obtained in the period between the date of the initial assessment and the date of issue of the report. Manufactured products will not necessarily give identical results due to production and measurement tolerances. The apparatus was set up and exercised using the configuration and modes of operation defined in this report only. Where relevant, the apparatus was only assessed using the susceptibility criteria defined in this report and the Test Assessment Plan (TAP). All testing was performed under the following environmental conditions:
Temperature 15C to 35C (54F to 95F) Atmospheric Pressure 860mbar to 1060mbar (25.4" to 31.3") Humidity 10% to 75*%
All AC testing was performed at one or more of the following supply voltages:
110V 60 Hz (+/-20%) Units of Measurement The units of measurements defined in the appendices are reported in specific terms, which are test dependent. Where radiated measurements are concerned these are defined at a particular distance. Basic voltage measurements are defined in units of [dBuV]
As an example, the basic calculation for all measurements is as follows:
The combinations of correction factors are dependent upon the exact test configurations [see test equipment lists for further details] and may include:-
Emission level [dBuV] = Indicated voltage level [dBuV] + Cable Loss [dB] + Other correction factors [dB]
Antenna Factors, Pre Amplifier Gain, LISN Loss, Pulse Limiter Loss and Filter Insertion Loss Note: to convert the results from dBuV/m to uV/m use the following formula:-
Level in uV/m = Common Antilogarithm [(X dBuV/m)/20] = Y uV/m This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 4 of 62 Radio Test Report No: EDCS (EDCS) Measurement Uncertainty Values voltage and power measurements 2 dB conducted EIRP measurements 1.4 dB radiated measurements 3.2 dB frequency measurements 2.4 10-7 temperature measurements humidity measurements 0.54 2.3%
DC and low frequency measurements 2.5%
Where relevant measurement uncertainty levels have been estimated for tests performed on the apparatus. This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2. Radiated emissions (expanded uncertainty, confidence interval 95%) 30 MHz - 300 MHz 300 MHz - 1000 MHz 1 GHz - 10 GHz 10 GHz - 18GHz 18GHz - 26.5GHz 26.5GHz - 40GHz
+/- 3.8 dB
+/- 4.3 dB
+/- 4.0 dB
+/- 8.2 dB
+/- 4.1 dB
+/- 3.9 dB Conducted emissions (expanded uncertainty, confidence interval 95%) A product is considered to comply with a requirement if the nominal measured value is below the limit line. The product is considered to not be in compliance in case the nominal measured value is above the limit line. 30 MHz 40GHz
+/- 0.38 dB This report must not be reproduced except in full, without written approval of Cisco Systems. Page No: 5 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 2.2 Date of testing 20-Nov-19 - 21-Nov-19 2.3 Report Issue Date 9/23/2019 Cisco uses an electronic system to issue, store and control the revision of test reports. This system is called the Engineering Document Control System (EDCS). The actual report issue date is embedded into the original file on EDCS. Any copies of this report, either electronic or paper, that are not on EDCS must be considered uncontrolled. 2.4 Testing facilities This assessment was performed by:
Testing Laboratory Cisco Systems, Inc. 125 West Tasman Drive (Building P) San Jose, CA 95134 USA Headquarters Cisco Systems, Inc., 170 West Tasman Drive San Jose, CA 95134, USA Registration Numbers for Industry Canada Cisco System Site Address Building P, 10m Chamber Building P, 5m Chamber Building I, 5m Chamber 125 West Tasman Dr San Jose, CA 95134 125 West Tasman Dr San Jose, CA 95134 285 W. Tasman Drive San Jose, California 95134 Site Identifier Company #: 2461N-2 Company #: 2461N-1 Company #: 2461M-1 Building 7, 5m Chamber 425 E. Tasman Drive Company #: 2461N-3 San Jose, California 95134 Test Engineers Julian Land 2.5 Equipment Assessed (EUT) IW 6300H Page No: 6 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 2.6 EUT Description The radio supports the following modes of operation. The modes are further defined in the radio Theory of Operation. The modes included in this report represent the worst case data for all modes. 802.11a - Non HT20, Two Antennas, 6 to 54 Mbps, 1ss 802.11a - Non HT20 Beam Forming, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT20, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT40, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT40, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT40, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT80, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT80, Two Antennas, 6 to 54 Mbps, 1ss 802.11ac - VHT80, One Antenna, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 1ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 STBC, Two Antennas, M0 to M9 2ss 802.11a - Non HT20, One Antenna, 6 to 54 Mbps, 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 7 of 62 Radio Test Report No: EDCS (EDCS) Model / PID Differences IW-6300H-AC-x-K9, IW-6300H-DC-x-K9, IW-6300-DCW-x-K9 and ESW-6300-CON-x-K9, all have the same identical components, electronics circuitries, PCB layout and enclosure. The only differences are listed as below:
IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300-DCW-x-K9 ESW-6300-CON-x-K9 Where x can be replaced with another letter to indicate country domain. Domain letters: A, B, C, D, E, F, H, I, L, M, N, Q, R, S, T, Z Where AC is Alternating Current (AC power supply) Where DC is Direct Current (DC power supply), 54V native input Where DCW is Direct Current; wide range 10-36VDC Where K9 is encryption software. Page No: 8 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) The following antennas are supported by this product series. The data included in this report represent the worst case data for all antennas. Frequency Part Number AIR-ANT2450V-N Antenna Type Single Band Omni AIR-ANT2450V-N-HZ Single Band Omni, Hazloc 2.4 GHz AIR-ANT2480V-N AIR-ANT2450HG-N AIR-ANT2450VG-N AIR-ANT2413P2M-N Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni Single Band, Dual Polarized Directional Patch 5 GHz 2.4/5 GHz Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni AIR-ANT5180V-N AIR-ANT5150HG-N AIR-ANT5150VG-N AIR-ANT5114P2M-N AIR-ANT2547V-N=
AIR-ANT2547VG-N= Dual-band Omni, Gray AIR-ANT2547V-N-HZ= Dual-band Omni, Hazloc Dual-band Omni Single Band, Dual Polarized Directional Patch AIR-ANT2568VG-N AIR-ANT2588P3M-N= Dual-band/Dual Polarized Directional, Patch AIR-ANT2513P4M-N Dual-band Polarization Diverse Patch Array Dual-band Omni
>30 degree 5 GHz Antenna Gain
(dBi) NA NA NA NA NA NA
-3
-5
-6 5
-6
-6
-6 3 1
-5 Antenna Gain
(dBi) 5 5 8 5 5 13 8 5 5 13 4 / 7 4 / 7 4 / 7 6 / 8 8 / 8 13 / 13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 9 of 62 Radio Test Report No: EDCS (EDCS) Section 3: Result Summary 3.1 Results Summary Table Conducted emissions Basic Standard FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.209 FCC 15.205 Technical Requirements / Details 99% & 26 dB Bandwidth:
The 99% occupied bandwidth is the frequency bandwidth such that, below its lower and above its upper frequency limits, the mean powers are each equal to 0.5% of the total mean power of the given emission. There is no limit for 99% OBW. The 26 dB emission is the width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 26 dB relative to the maximum level measured in the fundamental emission. Output Power:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Power Spectral Density:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bandsthe maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Conducted Spurious Emissions / Band-Edge:
15.407 (3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz. Restricted band:
Unwanted emissions falling within the restricted bands, as defined in FCC 15.205 (a) must also comply with the radiated emission limits specified in FCC 15.209 (a). Result Pass Pass Pass Pass Pass Radiated Emissions (General requirements) Basic Standard FCC 15.209 FCC 15.205 FCC 15.207 Technical Requirements / Details TX Spurious Emissions:
Except as provided elsewhere in this subpart, the emissions from an intentional radiator shall not exceed the field strength levels specified in the filed strength limits table in this section. AC conducted Emissions:
Except when the requirements applicable to a given device state otherwise, for any radio apparatus equipped to operate from the public utility AC power supply, either directly or indirectly (such as with a battery charger), the radio frequency voltage of emissions conducted back onto the AC power lines in the frequency range of 0.15 MHz to 30 MHz shall not exceed the limits shown in the table in these sections. The more stringent limit applies at the frequency range boundaries. Result Pass Pass Page No: 10 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Section 4: Sample Details Note: Each sample was evaluated to ensure that its condition was suitable to be used as a test sample prior to the commencement of testing. 4.1 Sample Details Sample No. S01 S02 Equipment Details Manufacturer Hardware Rev. Firmware Rev. Software Rev. Serial Number IW-6300H-DC-B-K9 FSP150-AWAN3 Cisco Systems, Inc. FSP Group Inc. 11
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9.1.8.1 9.0.5.5-W8964 FOC23241G16
-
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H00000063 4.2 System Details System #
1 EUT and Power Supply 4.3 Mode of Operation Details Mode#
Description Description Samples S01, S02 Comments 1 Continuous Transmitting Continuous Transmitting 98% duty cycle All measurements were made in accordance with ANSI C63.10:2013 KDB 789033 D02 General UNII Test Procedures New Rules v01r03 KDB 662911 D01 Multiple Transmitter Output v02r01 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 11 of 62 Radio Test Report No: EDCS (EDCS) Appendix A: Emission Test Results Conducted Test Setup Diagram Target Maximum Channel Power The following table details the maximum supported Total Channel Power for all operating modes. Operating Mode Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M15 HT/VHT20 Beam Forming, M0 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 HT/VHT40 Beam Forming, M0 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss VHT80 Beam Forming, M0 to M9, M0 to M9 1-2ss Maximum Channel Power
(dBm) Frequency (MHz) 5500 21 18 22 22 22 5510 18 18 18 18 5530 17 18 18 5560 21 19 22 22 22 5550 22 23 23 23 5610 21 23 23 5700 21 19 22 22 22 5710 24 24 24 24 5690 22 24 24 Page No: 12 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) VHT80 STBC, M0 to M9 1ss 18 23 24 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 13 of 62 Radio Test Report No: EDCS (EDCS) A.1 Duty Cycle Duty Cycle Test Requirement From KDB 789033 D02 General UNII Test Procedures New Rules v02r01 B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level 1. All measurements are to be performed with the EUT transmitting at 100 percent duty cycle at its maximum power control level; however, if 100 percent duty cycle cannot be achieved, measurements of duty cycle, x, and maximum-power transmission duration, T, are required for each tested mode of operation. Duty Cycle Test Method From KDB 789033 D02 General UNII Test Procedures New Rules v02r01:
B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level The zero-span mode on a spectrum analyzer or EMI receiver, if the response time and spacing between bins on the sweep are sufficient to permit accurate measurements of the on and off times of the transmitted signal. Set the center frequency of the instrument to the center frequency of the transmission. Set RBW EBW if possible; otherwise, set RBW to the largest available value. Set VBW RBW. Set detector = peak or average. The zero-span measurement method shall not be used unless both RBW and VBW are > 50/T, where T is defined in section II.B.1.a), and the number of sweep points across duration T exceeds 100. (For example, if VBW and/or RBW are limited to 3 MHz, then the zero-span method of measuring duty cycle shall not be used if T 16.7 microseconds.) Duty Cycle Test Information Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Date of testing:
20-Nov-19 - 21-Nov-19 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 14 of 62 Radio Test Report No: EDCS (EDCS) Duty Cycle Data Table Duty Cycle table and screen captures are shown below for power/psd modes. Frequency Mode Data Rate 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 Duty Cycle correction
(dB) 0.0 0.0 0.0 0.1 0.0 0.2 0.0 0.1 0.0 0.0 0.0 0.2 0.0 0.2 0.0 0.0 0.0 0.1 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 15 of 62 Radio Test Report No: EDCS (EDCS) Duty Cycle, 5530 MHz, VHT80, M0 to M9, M0 to M9 1-2ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 16 of 62 Radio Test Report No: EDCS (EDCS) A.2 99% and 26dB Bandwidth 99% and 26dB Bandwidth Test Requirement There is no requirement for the value of bandwidth. However, the 26dB BW (EBW) is used to calculate the power limits in 15.407 (a) (2). Power measurements are made using the 99% Bandwidth as the integration bandwidth. Band-crossing emissions: For an emission that crosses the boundary between two adjacent U-NII bands, the boundary frequency between the bands serves as one edge for defining the portion of the EBW that falls within a particular U-NII band. However, the -26 dB points are measured relative to the highest point on the contiguous segmentregardless of which band contains that highest point (Figure4). 99% and 26dB Bandwidth Test Procedure Ref. KDB 789033 Section D. 99 Percent Occupied Bandwidth ANSI C63.10: 2013 Section 6.9.3 KDB 662911 99% BW Test Parameters 1. Set center frequency to the nominal EUT channel center frequency. 2. Set span = 1.5 times to 5.0 times the OBW. 3. Set RBW = 1 % to 5 % of the OBW 4. Set VBW 3 RBW 5. Video averaging is not permitted. Where practical, a sample detection and single sweep mode shall be used. Otherwise, peak detection and max hold mode (until the trace stabilizes) shall be used. 6. Use the 99 % power bandwidth function of the instrument (if available). Ref KDB 789033 in Section C. Measurement Bandwidth, Section 1 26 BW Test parameters X dB BW = -26dB (using the OBW function of the spectrum analyzer) Emission Bandwidth (EBW) a) Set RBW = approximately 1% of the emission bandwidth. b) Set the VBW > RBW. c) Detector = Peak. d) Trace mode = max hold. e) Measure the maximum width of the emission that is 26 dB down from the maximum of the emission. Page No: 17 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Compare this with the RBW setting of the analyzer. Readjust RBW and repeat measurement as needed until the RBW/EBW ratio is approximately 1%. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
Start Date to Finish Date here Page No: 18 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 99% and 26dB Bandwidth Table Frequency
(MHz) 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Mode Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Data Rate 26dB BW 99% BW
(Mbps)
(MHz) 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 19.8 20.1 41.8 40.6 83.2 83.2 41.4 40.6 19.7 20.1 82.0 82.3 82.8 82.3 19.7 20.2 41.3 40.9 14.9 15.1
(MHz) 16.610 17.643 36.387 36.211 76.422 76.471 36.477 36.207 16.615 17.641 76.356 76.364 76.414 76.524 16.612 17.653 36.410 36.210 13.283 13.797 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 19 of 62 Radio Test Report No: EDCS (EDCS) 26dB / 99% Bandwidth, 5720 MHz, Non HT20, 6 to 54 Mbps This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 20 of 62 Radio Test Report No: EDCS (EDCS) A.3 Maximum Conducted Output Power Maximum Conducted Output Power Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Maximum Conducted Output Power Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 ANSI C63.10: 2013 Maximum Conducted Output Power Test Procedure 1. Set the radio in the continuous transmitting mode at full power 2. Compute power by integrating the spectrum across the EBW (or alternatively entire 99% OBW) of the signal using the instruments band power measurement function. The integration shall be performed using the spectrum analyzer band-power measurement function with band limits set equal to the EBW or the OBW band edges. Page No: 21 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 3. Capture graphs and record pertinent measurement data. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Measurement using a Spectrum Analyzer or EMI Receiver (SA), (d) Method SA-2 Maximum Conducted Output Power Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 System under Support test equipment Date of testing:
Start Date to Finish Date here Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 22 of 62 Radio Test Report No: EDCS (EDCS) Maximum Output Power
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n g r a M i Non HT20, 6 to 54 Mbps 1 5 20.8 0.0 20.8 Non HT20, 6 to 54 Mbps 2 5 15.8 14.5 0.0 18.2 Non HT20 Beam Forming, 6 to 54 Mbps 2 8 15.8 14.5 0.0 18.2 HT/VHT20, M0 to M7 1 5 21.0 0.0 21.0 HT/VHT20, M0 to M7 2 5 15.9 14.7 0.0 18.4 HT/VHT20, M8 to M15 2 5 19.1 17.8 0.0 21.6 HT/VHT20 Beam Forming, M0 to M7 2 8 15.9 14.7 0.0 18.4 HT/VHT20 Beam Forming, M8 to M15 2 5 19.1 17.8 0.0 21.6 HT/VHT20 STBC, M0 to M7 2 5 19.1 17.8 0.0 21.6 Non HT40, 6 to 54 Mbps 1 5 16.9 0.0 16.9 Non HT40, 6 to 54 Mbps 2 5 15.5 14.5 0.0 18.1 HT/VHT40, M0 to M7 1 5 16.9 0.1 17.0 HT/VHT40, M0 to M7 2 5 15.4 14.5 0.1 18.0 HT/VHT40, M8 to M15 2 5 15.4 14.5 0.1 18.0 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 2 2 8 5 14.3 15.4 13.4 14.5 0.1 0.1 16.9 18.0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. Page No: 23 of 62 0 1 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 3.17 5.76 3.76 2.96 5.61 2.45 3.61 2.45 2.45 7.07 5.93 7.05 5.97 5.97 5.06 5.97 Radio Test Report No: EDCS (EDCS) 0 3 5 5 HT/VHT40 STBC, M0 to M7 2 5 15.4 14.5 0.1 18.0 Non HT80, 6 to 54 Mbps 1 5 14.7 0.0 14.7 Non HT80, 6 to 54 Mbps 2 5 14.7 13.7 0.0 17.3 VHT80, M0 to M9 1ss 1 5 14.9 0.2 15.1 VHT80, M0 to M9 1ss 2 5 14.9 14.2 0.2 17.8 VHT80, M0 to M9 2ss 2 5 14.9 14.2 0.2 17.8 VHT80 Beam Forming, M0 to M9 1ss 2 8 12.8 12.1 0.2 15.7 VHT80 Beam Forming, M0 to M9 2ss 2 5 14.9 14.2 0.2 17.8 VHT80 STBC, M0 to M9 1ss 2 5 14.9 14.2 0.2 17.8 Non HT40, 6 to 54 Mbps 1 5 20.1 0.0 20.1 Non HT40, 6 to 54 Mbps 2 5 19.1 19.0 0.0 22.1 HT/VHT40, M0 to M7 1 5 21.2 0.1 21.3 HT/VHT40, M0 to M7 2 5 19.1 19.0 0.1 22.1 0 5 5 5 HT/VHT40, M8 to M15 2 5 20.1 19.9 0.1 23.1 HT/VHT40 Beam Forming, M0 to M7 2 8 16.7 16.5 0.1 19.7 HT/VHT40 Beam Forming, M8 to M15 2 5 20.1 19.9 0.1 23.1 HT/VHT40 STBC, M0 to M7 2 5 20.1 19.9 0.1 23.1 Non HT20, 6 to 54 Mbps 1 5 20.7 0.0 20.7 Non HT20, 6 to 54 Mbps 2 5 16.0 16.5 0.0 19.3 Non HT20 Beam Forming, 6 to 54 Mbps 2 8 16.0 16.5 0.0 19.3 HT/VHT20, M0 to M7 1 5 20.9 0.0 20.9 24. 0 24. 0 22. 0 24. 0 Page No: 24 of 62 0 6 5 5 This document is uncontrolled. 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Company Confidential 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 5.97 9.27 6.73 8.91 6.24 6.24 6.34 6.24 6.24 3.87 1.91 2.75 1.89 0.94 2.34 0.94 0.94 3.27 4.70 2.70 3.06 Radio Test Report No: EDCS (EDCS) HT/VHT20, M0 to M7 2 5 16.2 16.6 0.0 19.5 HT/VHT20, M8 to M15 2 5 18.7 19.0 0.0 21.9 HT/VHT20 Beam Forming, M0 to M7 2 8 16.2 16.6 0.0 19.5 HT/VHT20 Beam Forming, M8 to M15 2 5 18.7 19.0 0.0 21.9 HT/VHT20 STBC, M0 to M7 2 5 18.7 19.0 0.0 21.9 Non HT80, 6 to 54 Mbps 1 5 20.8 0.0 20.8 Non HT80, 6 to 54 Mbps 2 5 17.3 16.7 0.0 20.1 VHT80, M0 to M9 1ss 1 5 21.1 0.2 21.3 VHT80, M0 to M9 1ss 2 5 19.8 19.7 0.2 23.0 0 1 6 5 VHT80, M0 to M9 2ss 2 5 19.8 19.7 0.2 23.0 VHT80 Beam Forming, M0 to M9 1ss 2 8 18.6 18.5 0.2 21.8 VHT80 Beam Forming, M0 to M9 2ss 2 5 19.8 19.7 0.2 23.0 VHT80 STBC, M0 to M9 1ss 2 5 19.8 19.7 0.2 23.0 Non HT80, 6 to 54 Mbps 1 5 21.7 0.0 21.7 Non HT80, 6 to 54 Mbps 2 5 17.7 15.9 0.0 19.9 VHT80, M0 to M9 1ss 1 5 21.9 0.2 22.1 VHT80, M0 to M9 1ss 2 5 20.8 20.2 0.2 23.7 0 9 6 5 VHT80, M0 to M9 2ss 2 5 20.8 20.2 0.2 23.7 VHT80 Beam Forming, M0 to M9 1ss 2 8 18.9 17.7 0.2 21.5 VHT80 Beam Forming, M0 to M9 2ss 2 5 20.8 20.2 0.2 23.7 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 4.54 2.09 2.54 2.09 2.09 3.17 3.95 2.71 1.05 1.05 0.25 1.05 1.05 2.27 4.06 1.91 0.29 0.29 0.46 0.29 0.29 VHT80 STBC, M0 to M9 1ss Page No: 25 of 62 2 5 20.8 20.2 0.2 23.7 This document is uncontrolled. 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Company Confidential Radio Test Report No: EDCS (EDCS) 0 0 7 5 Non HT20, 6 to 54 Mbps 1 5 20.8 0.0 20.8 Non HT20, 6 to 54 Mbps 2 5 15.0 16.0 0.0 18.6 Non HT20 Beam Forming, 6 to 54 Mbps 2 8 15.0 16.0 0.0 18.6 HT/VHT20, M0 to M7 1 5 20.9 0.0 20.9 HT/VHT20, M0 to M7 2 5 16.2 17.2 0.0 19.8 HT/VHT20, M8 to M15 2 5 17.9 19.0 0.0 21.5 HT/VHT20 Beam Forming, M0 to M7 2 8 16.2 17.2 0.0 19.8 HT/VHT20 Beam Forming, M8 to M15 2 5 17.9 19.0 0.0 21.5 HT/VHT20 STBC, M0 to M7 2 5 17.9 19.0 0.0 21.5 Non HT40, 6 to 54 Mbps 1 5 23.6 0.0 23.6 Non HT40, 6 to 54 Mbps 2 5 18.1 18.5 0.0 21.3 HT/VHT40, M0 to M7 1 5 22.5 0.1 22.6 HT/VHT40, M0 to M7 2 5 19.5 19.8 0.1 22.7 0 1 7 5 HT/VHT40, M8 to M15 2 5 20.5 20.8 0.1 23.7 HT/VHT40 Beam Forming, M0 to M7 2 8 18.7 19.0 0.1 21.9 HT/VHT40 Beam Forming, M8 to M15 2 5 20.5 20.8 0.1 23.7 HT/VHT40 STBC, M0 to M7 57 20 Non HT20, 6 to 54 Mbps 2 5 20.5 20.8 0.1 23.7 1 5 19.3 0.0 19.3 Non HT20, 6 to 54 Mbps 2 5 14.5 15.5 0.0 18.1 Non HT20 Beam Forming, 6 to 54 Mbps 2 8 14.5 15.5 0.0 18.1 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 1 2 5 5 20.3 14.6 15.6 0.0 0.0 20.3 18.2 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 26 of 62 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 3.17 5.43 3.43 3.06 4.22 2.46 2.22 2.46 2.46 0.37 2.66 1.45 1.29 0.29 0.09 0.29 0.29 4.67 5.93 3.93 3.66 5.82 Radio Test Report No: EDCS (EDCS) HT/VHT20, M8 to M15 2 5 17.1 16.8 0.0 20.0 HT/VHT20 Beam Forming, M0 to M7 2 8 14.6 15.6 0.0 18.2 HT/VHT20 Beam Forming, M8 to M15 2 5 17.1 16.8 0.0 20.0 HT/VHT20 STBC, M0 to M7 2 5 17.1 16.8 0.0 20.0 0 24. 0 22. 0 24. 0 24. 0 3.99 3.82 3.99 3.99 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 27 of 62 Radio Test Report No: EDCS (EDCS) Maximum Transmit Output Power, 5710 MHz, HT/VHT40 Beam Forming, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 28 of 62 Radio Test Report No: EDCS (EDCS) A.4 Power Spectral Density Power Spectral Density Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Power Spectral Density Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test Procedure The rules requires maximum power spectral density measurements where the intent is to measure the maximum value of the time average of the power spectral density measured during a period of continuous transmission. 1. Create an average power spectrum for the EUT operating mode being tested by following the instructions in section II.E.2. for measuring maximum conducted output power using a spectrum analyzer or EMI receiver: select the Page No: 29 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) appropriate test method (SA-1, SA-2, SA-3, or alternatives to each) and apply it up to, but not including, the step labeled, Compute power. (This procedure is required even if the maximum conducted output power measurement was performed using a power meter, method PM.) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. b) If Method SA-3 Alternative was used and the linear mode was used in step II.E.2.g)(viii), add 1 dB to the final result to compensate for the difference between linear averaging and power averaging. 4. The result is the Maximum PSD over 1 MHz reference bandwidth. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) F. Maximum Power Spectral Density (PSD) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 30 of 62 Radio Test Report No: EDCS (EDCS) Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment Date of testing:
Start Date to Finish Date here Page No: 31 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Power Spectral Density
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-1.8 0.3 0.3 11.0 12.87 9.0 8.42 11.0 13.51 9.0 8.70 11.0 10.70 9.0 11.0 11.0 10.80 10.70 10.70 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 5 8 5 8 5 8 5 5 5 8 8 5 8 5 8 5 5 5 8 5 8 5 8 5 5 5 8 5 8 5 8 5 5 5 8 8 5 8 5 6.6 5.5 7.4 5.3 6.2 2.8 6.2 6.2 5.8 5.3 6.1 2.7 6.1 6.1 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 6.6 8.7 7.5 8.4 9.2 5.8 9.2 9.2 11.0 9.0 11.0 9.0 11.0 9.0 11.0 11.0 10.0 5.6 5.6 10.0 5.3 7.7 5.3 7.7 7.7 5.7 5.7 5.7 8.0 5.7 8.0 8.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 10.0 11.0 8.7 8.7 9.0 9.0 10.0 11.0 8.6 9.0 10.9 11.0 8.6 10.9 10.9 3.9 0.2 3.7 2.3 2.3 1.3 2.3 2.3
-0.2 2.0 2.0 1.2 2.0 2.0 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2 3.9 3.0 3.9 5.4 5.4 4.5 5.4 5.4 4.7 0.6 4.4 3.4 3.4 1.5 3.4 3.4
-0.9 2.7 2.7 0.2 2.7 2.7 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2 4.7 3.0 4.6 6.3 6.3 4.1 6.3 6.3 9.0 11.0 11.0 11.0 9.0 11.0 9.0 11.0 9.0 11.0 11.0 11.0 9.0 11.0 9.0 11.0 9.0 11.0 11.0 10.4 4.3 4.3 9.8 5.1 6.8 5.5 5.5 6.5 8.3 0.0 0.0 0.0 0.0 0.0 0.0 10.4 11.0 8.0 8.0 9.8 8.9 9.0 9.0 11.0 9.0 10.7 11.0 4.37 0.31 3.55 0.64 1.79 3.19 1.79 1.79 0.97 0.31 0.31 0.96 0.44 0.09 0.44 0.09 0.09 7.07 5.95 7.11 3.65 5.65 4.55 5.65 5.65 6.27 6.04 6.41 2.74 4.74 4.90 4.74 4.74 0.57 1.02 1.02 1.16 0.09 0.33 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 33 of 62 Radio Test Report No: EDCS (EDCS) HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 8 5 5 5 8 5 8 5 8 5 5 5 8 8 5 8 5 8 5 5 5.1 6.8 6.8 6.5 8.3 8.3 0.0 0.0 0.0 8.9 10.7 10.7 9.0 11.0 11.0 10.0 11.0 10.0 4.9 8.8 5.6 6.6 4.6 6.6 6.6 4.9 5.9 6.7 5.2 6.7 6.7 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 9.6 4.6 4.6 10.6 4.8 7.2 4.8 7.2 7.2 5.8 5.8 5.9 7.1 5.9 7.1 7.1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 7.9 8.9 8.8 9.7 8.0 9.7 9.7 9.6 8.3 8.3 9.0 11.0 9.0 11.0 9.0 11.0 11.0 11.0 9.0 9.0 10.6 11.0 8.4 9.0 10.2 11.0 8.4 10.2 10.2 9.0 11.0 11.0 0.09 0.33 0.33 0.97 1.06 2.15 0.19 1.29 1.03 1.29 1.29 1.37 0.72 0.72 0.36 0.56 0.80 0.56 0.80 0.80 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 34 of 62 Radio Test Report No: EDCS (EDCS) Power Spectral Density, 5700 MHz, HT/VHT20, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 35 of 62 Radio Test Report No: EDCS (EDCS) A.5 Conducted Spurious Emissions Conducted Spurious Emissions Test Requirement 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Spurious Emissions Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 36 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Add the max antenna gain + ground reflection factor (4.7 dB for frequencies between 30 MHz and 1000 MHz, and 0 dB for frequencies > 1000 MHz). Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
20-Nov-19 - 21-Nov-19 Page No: 37 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Conducted Spurs Average Upper Conducted Spurs Peak Upper This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 38 of 62 Radio Test Report No: EDCS (EDCS) Conducted Spurious Average Table
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y c n e u q e r F 0 0 5 5 Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss B d
(
i n a G a n n e t n A d e t a l e r r o C 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
) m B d
(
r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
-50.3
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) B d
(
n o i t c e r r o C e l c y C y t u D 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
(
r u p S d e t c u d n o C l a t o T
) m B d
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t i m L i
) B d
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n g r a M i
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-41.25 6.12 Page No: 39 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 0 5 5 5 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 5 5 5 5 5 8 5 5 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 8 5 5 5
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-41.25 4.15 Page No: 40 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 8 5 5 5 5 5 5 5 8 5 5 5 5 8 5 5 5 8 5 5
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-41.25 5.36 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 41 of 62 Radio Test Report No: EDCS (EDCS) Conducted Spurs Average, 5610 MHz, Non HT80, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 42 of 62 Radio Test Report No: EDCS (EDCS) Conducted Spurious Emissions Peak Table
) i
) z H M
(
y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss B d
(
i n a G a n n e t n A d e t a l e r r o C 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
) m B d
(
r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
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) m B d
(
r e w o P r u p S 3 x T 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
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r u p S d e t c u d n o C l a t o T
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t i m L i
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n g r a M i
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-21.25 16.70 Page No: 43 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 5 5 5 5 5 8 5 5 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 8 5 5 5
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-21.25 17.11 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 44 of 62 Radio Test Report No: EDCS (EDCS) HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 8 5 5 5 5 5 5 5 8 5 5 5 5 8 5 5 5 8 5 5
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-21.25 18.48 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 45 of 62 Radio Test Report No: EDCS (EDCS) Conducted Spurs Peak, 5550 MHz, Non HT40, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 46 of 62 Radio Test Report No: EDCS (EDCS) A.6 Conducted Bandedge 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Band Edge Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 47 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging System under Support test equipment Date of testing:
20-Nov-19 - 21-Nov-19 Page No: 48 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Conducted Bandedge Average Table
) i
) z H M
(
y c n e u q e r F Mode s h t a P x T i B d
(
n a G a n n e t n A d e t a Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss l e r r o C 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
) m B d
(
l e v e L e g d e d n a B 1
) m B d
(
l e v e L e g d e d n a B 2 x T x T
) B d
(
n o i t c e r r o C e l c y C y t u D
) m B d
(
l e v e L e g d e d n a B x T l a t o T
) m B d
(
t i m L i
) B d
(
n g r a M i
-50.8
-57.7
-58.9
-57.7
-58.9
-50.9
-57.5
-58.9
-52.4
-54.5
-57.5
-58.9
-52.4
-54.5
-52.4
-54.5 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-45.8
-41.25 4.52
-50.2
-41.25 8.97
-47.2
-41.25 5.97
-45.9
-41.25 4.61
-50.1
-41.25 8.84
-45.3
-41.25 4.02
-47.1
-41.25 5.84
-45.3
-41.25 4.02
-45.3
-41.25 4.02
-47.4
-49.6
-52.2
-47.6
-51.3
-53.1
-51.3
-53.1
-53.5
-54.8
-51.3
-53.1
-51.3
-53.1 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-42.4
-41.25 1.12
-42.7
-41.25 1.42
-42.5
-41.25 1.30
-44.0
-41.25 2.80
-44.0
-41.25 2.80
-43.0
-41.25 1.78
-44.0
-41.25 2.80
-44.0
-41.25 2.80
-48.8
-48.8
-50.1
-49.4
-49.4
-50.6
-49.4
-50.6
-52.9
-54.0
-49.4
-50.6
-49.4
-50.6 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-43.8
-41.25 2.52
-41.4
-41.25 0.11
-44.2
-41.25 2.96
-41.8
-41.25 0.51
-41.8
-41.25 0.51
-42.2
-41.25 0.96
-41.8
-41.25 0.51
-41.8
-41.25 0.51 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 49 of 62 Radio Test Report No: EDCS (EDCS) Conducted Bandedge Average, 5530 MHz, Non HT80, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 50 of 62 Radio Test Report No: EDCS (EDCS) Conducted Bandedge Peak Table
) z H M
(
y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss
) i i B d
(
n a G a n n e t n A d e t a l e r r o C 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5
) m B d
(
l e v e L e g d e d n a B 1
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(
l e v e L e g d e d n a B 2 x T x T
) m B d
(
l e v e L e g d e d n a B x T l a t o T
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(
t i m L i
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(
n g r a M i
-37.3
-32.3
-21.25 11.02
-41.1
-43.8
-34.2
-21.25 12.95
-41.1
-43.8
-31.2
-21.25 9.95
-36.9
-31.9
-21.25 10.61
-37.4
-43.7
-31.4
-21.25 10.19
-38.6
-40.4
-31.4
-21.25 10.10
-37.4
-43.7
-28.4
-21.25 7.19
-38.6
-40.4
-31.4
-21.25 10.10
-38.6
-40.4
-31.4
-21.25 10.10
-30.7
-25.7
-21.25 4.42
-29.7
-40.1
-24.3
-21.25 3.04
-32.7
-27.6
-21.25 6.40
-38.9
-34.5
-28.1
-21.25 6.85
-38.9
-34.5
-28.1
-21.25 6.85
-34.5
-35.3
-23.8
-21.25 2.56
-38.9
-34.5
-28.1
-21.25 6.85
-38.9
-34.5
-28.1
-21.25 6.85
-34.2
-29.2
-21.25 7.92
-34.2
-40.0
-28.2
-21.25 6.90
-39.2
-34.0
-21.25 12.76
-39.2
-40.5
-31.6
-21.25 10.35
-39.2
-40.5
-31.6
-21.25 10.35
-41.5
-38.4
-28.5
-21.25 7.23
-39.2
-40.5
-31.6
-21.25 10.35
-39.2
-40.5
-31.6
-21.25 10.35 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 51 of 62 Radio Test Report No: EDCS (EDCS) Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 5 5 8 5 5 5 8 5 5 1 2 2 1 2 2 2 2 2
-28.6
-23.6
-21.25 2.32
-43.0
-33.8
-28.3
-21.25 7.02
-43.0
-33.8
-25.3
-21.25 4.02
-28.2
-23.2
-21.25 1.91
-37.6
-38.3
-29.9
-21.25 8.63
-32.6
-34.4
-25.4
-21.25 4.10
-37.6
-38.3
-26.9
-21.25 5.63
-32.6
-34.4
-25.4
-21.25 4.10
-32.6
-34.4
-25.4
-21.25 4.10 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 52 of 62 Radio Test Report No: EDCS (EDCS) Conducted Bandedge Peak, 5510 MHz, HT/VHT40 Beam Forming, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 53 of 62 Radio Test Report No: EDCS (EDCS) Conducted Bandedge Peak, 5700 MHz, HT/VHT20, M0 to M7 Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 54 of 62 Radio Test Report No: EDCS (EDCS) Appendix B: List of Test Equipment Used to perform the test Equip#
Manufacturer/ Model Description Last Cal Next Due 7329 OMEGA/CT485B Chart Recorder 18 Feb. 2019 18 Feb. 2020 RF Conducted at output antenna port 49516 Keysight (Agilent/HP) / N9030A PXA Signal Analyzer, 3Hz to 50GHz 29 Nov. 2019 29 Nov. 2019 55097 Nattional Instruments / PXI-1042 Chassis PXI Cal Not Required Cal Not Required 56089 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 56328 Pasternack / PE5019-1 Torque Wrench 13 Feb. 2019 13 Feb. 2020 57233 Nattional Instruments / PXI-8115 Embedded Controller Cal Not Required Cal Not Required 57253 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 57254 National Instruments / PXI-2799 Switch 1x1 Verify Before Use Verify Before Use 57479 CISCO / ATIL Automation Test Insertion Loss System Verify Before Use Verify Before Use This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 55 of 62 Radio Test Report No: EDCS (EDCS) Appendix C: Abbreviation Key and Definitions The following table defines abbreviations used within this test report. Abbreviation Description Abbreviation Description F C Temp Electro Magnetic Compatibility Electro Magnetic Interference Equipment Under Test Information Technology Equipment S/N Qty Test Assessment Schedule emf Electro Static Discharge Electric Fast Transient RMS Qp Engineering Document Control System Configuration Cisco Number (unique identification number for Cisco test equipment) Calibration Av Pk kHz MHz GHz H V dB V kV V A A mS S European Norm International Electro technical Commission International Special Committee on Radio Interference Coupling/Decoupling Network Line Impedance Stabilization Network Protective Earth Ground Line 1 Line2 Line 3 Direct Current Uncorrected measurement value, as indicated by the measuring device Radio Frequency Signal Line Conducted Emissions Measurement distance Not Applicable Power Line Neutral Line Supply EMC EMI EUT ITE TAP ESD EFT EDCS Config CIS#
Cal EN IEC CISPR CDN LISN PE GND L1 L2 L3 DC RAW RF SLCE Meas dist N/A or NA P N S Degrees Fahrenheit Degrees Celsius Temperature Serial Number Quantity Electromotive force Root mean square Quasi Peak Average Peak Kilohertz (1x103) MegaHertz (1x106) Gigahertz (1x109) Horizontal Vertical decibel Volt Kilovolt (1x103) Microvolt (1x10-6) Amp Micro Amp (1x10-6) Milli Second (1x10-3) Micro Second (1x10-6) S m Spec dist SL L R AC Micro Second (1x10-6) Meter Specification distance Signal Line (or Telecom Line) Live Line Return Alternating Current This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 56 of 62 Radio Test Report No: EDCS (EDCS) Appendix D: Photographs of Test Setups Title: EUT Pictures Page No: 57 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 58 of 62 Radio Test Report No: EDCS (EDCS) Title: Radio Conducted Test Setup Page No: 59 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Appendix E: Software Used to Perform Testing EMIsoft Vasona, version 6.024 Page No: 60 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Appendix F: Test Procedures Measurements were made in accordance with KDB 789033 - D02 General UNII Test Procedures New Rules v02r01 KDB 662911 - MIMO ANSI C63.4 2014 Unintentional Radiators ANSI C63.10 2013 Intentional Radiators Test procedures are summarized below:
FCC 5GHz Test Procedures FCC 5GHz RSE Test Procedures EDCS # 1445048 EDCS # 1511600 Page No: 61 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS (EDCS) Appendix G: Scope of Accreditation (A2LA certificate number 1178-01) The scope of accreditation of Cisco Systems, Inc. can be found on the A2LA web page at:
http://www.a2la.org/scopepdf/1178-01.pdf End This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 62 of 62
1 2 3 4 5 6 | UNI IIC INT 13B | External Photos | 2.77 MiB | September 12 2019 |
Radio Test Report No: EDCS 18429908 Test Report IW-6300H Series Access Point Cisco Industrial Wireless Hazardous Location Access Point FCC ID: LDKESW6300 IC ID: 2461D-ESW6300 5470-5725 MHz Inside Antennas, 13dBi Gain Against the following Specifications:
CFR47 Part 15.407 Cisco Systems 170 West Tasman Drive San Jose, CA 95134 Approved By: Adam Walb Title: MGR. IoT Compliance Revision: 1.0 Author: Julian Land Tested By: Julian Land This report replaces any previously entered test report under EDCS 18429908.This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. Test Report Template EDCS# 11644124. Page No: 1 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. SECTION 1: OVERVIEW ......................................................................................................................................... 3 SECTION2: ASSESSMENT INFORMATION ........................................................................................................ 4 2.1 GENERAL ............................................................................................................................................................. 4 2.2 DATE OF TESTING................................................................................................................................................. 6 2.3 REPORT ISSUE DATE ............................................................................................................................................ 6 2.4 TESTING FACILITIES ............................................................................................................................................. 6 2.5 EQUIPMENT ASSESSED (EUT) .............................................................................................................................. 6 2.6 EUT DESCRIPTION ............................................................................................................................................... 7 SECTION 3: RESULT SUMMARY ........................................................................................................................ 10 3.1 RESULTS SUMMARY TABLE ............................................................................................................................... 10 SECTION 4: SAMPLE DETAILS ........................................................................................................................... 11 4.1 SAMPLE DETAILS ............................................................................................................................................... 11 4.2 SYSTEM DETAILS ............................................................................................................................................... 11 4.3 MODE OF OPERATION DETAILS .......................................................................................................................... 11 APPENDIX A: EMISSION TEST RESULTS ........................................................................................................ 12 CONDUCTED TEST SETUP DIAGRAM ........................................................................................................................ 12 TARGET MAXIMUM CHANNEL POWER .................................................................................................................... 12 A.1 DUTY CYCLE .................................................................................................................................................... 14 A.2 99% AND 26DB BANDWIDTH ............................................................................................................................ 17 A.3 MAXIMUM CONDUCTED OUTPUT POWER ......................................................................................................... 21 A.4 POWER SPECTRAL DENSITY .............................................................................................................................. 29 A.5 CONDUCTED SPURIOUS EMISSIONS ................................................................................................................... 36 A.6 CONDUCTED BANDEDGE ................................................................................................................................... 47 APPENDIX B:
NOT DEFINED. LIST OF TEST EQUIPMENT USED TO PERFORM THE TEST . ERROR! BOOKMARK APPENDIX C: ABBREVIATION KEY AND DEFINITIONS ............................................................................. 55 APPENDIX D:
PHOTOGRAPHS OF TEST SETUPS ................................................................................... 57 APPENDIX E:
SOFTWARE USED TO PERFORM TESTING ................................................................... 60 APPENDIX F:
TEST PROCEDURES ............................................................................................................. 61 APPENDIX G: SCOPE OF ACCREDITATION (A2LA CERTIFICATE NUMBER 1178-01) ........................ 62 Page No: 2 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Section 1: Overview The samples were assessed against the tests detailed in section 3 under the requirements of the following specifications:
Specifications:
CFR47 Part 15.407 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 3 of 62 b) c) d) e) Radio Test Report No: EDCS 18429908 Section2: Assessment Information 2.1 General This report contains an assessment of an apparatus against Electromagnetic Compatibility Standards based upon tests carried out on the samples submitted. The testing was performed by and for the use of Cisco systems Inc:
With regard to this assessment, the following points should be noted:
a) The results contained in this report relate only to the items tested and were obtained in the period between the date of the initial assessment and the date of issue of the report. Manufactured products will not necessarily give identical results due to production and measurement tolerances. The apparatus was set up and exercised using the configuration and modes of operation defined in this report only. Where relevant, the apparatus was only assessed using the susceptibility criteria defined in this report and the Test Assessment Plan (TAP). All testing was performed under the following environmental conditions:
Temperature 15C to 35C (54F to 95F) Atmospheric Pressure 860mbar to 1060mbar (25.4" to 31.3") Humidity 10% to 75*%
All AC testing was performed at one or more of the following supply voltages:
110V 60 Hz (+/-20%) Units of Measurement The units of measurements defined in the appendices are reported in specific terms, which are test dependent. Where radiated measurements are concerned these are defined at a particular distance. Basic voltage measurements are defined in units of [dBuV]
As an example, the basic calculation for all measurements is as follows:
The combinations of correction factors are dependent upon the exact test configurations [see test equipment lists for further details] and may include:-
Emission level [dBuV] = Indicated voltage level [dBuV] + Cable Loss [dB] + Other correction factors [dB]
Antenna Factors, Pre Amplifier Gain, LISN Loss, Pulse Limiter Loss and Filter Insertion Loss Note: to convert the results from dBuV/m to uV/m use the following formula:-
Level in uV/m = Common Antilogarithm [(X dBuV/m)/20] = Y uV/m This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 4 of 62 Radio Test Report No: EDCS 18429908 Measurement Uncertainty Values voltage and power measurements 2 dB conducted EIRP measurements 1.4 dB radiated measurements 3.2 dB frequency measurements 2.4 10-7 temperature measurements humidity measurements 0.54 2.3%
DC and low frequency measurements 2.5%
Where relevant measurement uncertainty levels have been estimated for tests performed on the apparatus. This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2. Radiated emissions (expanded uncertainty, confidence interval 95%) 30 MHz - 300 MHz 300 MHz - 1000 MHz 1 GHz - 10 GHz 10 GHz - 18GHz 18GHz - 26.5GHz 26.5GHz - 40GHz
+/- 3.8 dB
+/- 4.3 dB
+/- 4.0 dB
+/- 8.2 dB
+/- 4.1 dB
+/- 3.9 dB Conducted emissions (expanded uncertainty, confidence interval 95%) A product is considered to comply with a requirement if the nominal measured value is below the limit line. The product is considered to not be in compliance in case the nominal measured value is above the limit line. 30 MHz 40GHz
+/- 0.38 dB This report must not be reproduced except in full, without written approval of Cisco Systems. Page No: 5 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 2.2 Date of testing 11-Nov-19 - 11-Nov-19 2.3 Report Issue Date 11/14/2019 Cisco uses an electronic system to issue, store and control the revision of test reports. This system is called the Engineering Document Control System (EDCS). The actual report issue date is embedded into the original file on EDCS. Any copies of this report, either electronic or paper, that are not on EDCS must be considered uncontrolled. 2.4 Testing facilities This assessment was performed by:
Testing Laboratory Cisco Systems, Inc. 125 West Tasman Drive (Building P) San Jose, CA 95134 USA Headquarters Cisco Systems, Inc., 170 West Tasman Drive San Jose, CA 95134, USA Registration Numbers for Industry Canada Cisco System Site Address Building P, 10m Chamber Building P, 5m Chamber Building I, 5m Chamber 125 West Tasman Dr San Jose, CA 95134 125 West Tasman Dr San Jose, CA 95134 285 W. Tasman Drive San Jose, California 95134 Site Identifier Company #: 2461N-2 Company #: 2461N-1 Company #: 2461M-1 Building 7, 5m Chamber 425 E. Tasman Drive Company #: 2461N-3 San Jose, California 95134 Test Engineers Julian Land 2.5 Equipment Assessed (EUT) IW 6300H Page No: 6 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 2.6 EUT Description The radio supports the following modes of operation. The modes are further defined in the radio Theory of Operation. The modes included in this report represent the worst case data for all modes. 802.11a - Non HT20, Two Antennas, 6 to 54 Mbps, 1ss 802.11a - Non HT20 Beam Forming, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT20, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT40, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT40, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT40, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT80, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT80, Two Antennas, 6 to 54 Mbps, 1ss 802.11ac - VHT80, One Antenna, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 1ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 STBC, Two Antennas, M0 to M9 2ss 802.11a - Non HT20, One Antenna, 6 to 54 Mbps, 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 7 of 62 Radio Test Report No: EDCS 18429908 Model / PID Differences IW-6300H-AC-x-K9, IW-6300H-DC-x-K9, IW-6300-DCW-x-K9 and ESW-6300-CON-x-K9, all have the same identical components, electronics circuitries, PCB layout and enclosure. The only differences are listed as below:
IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300-DCW-x-K9 ESW-6300-CON-x-K9 Where x can be replaced with another letter to indicate country domain. Domain letters: A, B, C, D, E, F, H, I, L, M, N, Q, R, S, T, Z Where AC is Alternating Current (AC power supply) Where DC is Direct Current (DC power supply), 54V native input Where DCW is Direct Current; wide range 10-36VDC Where K9 is encryption software. Page No: 8 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 The following antennas are supported by this product series. The data included in this report represent the worst case data for all antennas. Frequency Part Number AIR-ANT2450V-N Antenna Type Single Band Omni AIR-ANT2450V-N-HZ Single Band Omni, Hazloc 2.4 GHz AIR-ANT2480V-N AIR-ANT2450HG-N AIR-ANT2450VG-N AIR-ANT2413P2M-N Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni Single Band, Dual Polarized Directional Patch 5 GHz 2.4/5 GHz Single Band Omni Horizontal Polarized Omni AIR-ANT5180V-N AIR-ANT5150HG-N AIR-ANT5150VG-N AIR-ANT5114P2M-N AIR-ANT2547V-N=
AIR-ANT2547VG-N= Dual-band Omni, Gray AIR-ANT2547V-N-HZ= Dual-band Omni, Hazloc Vertical Polarized Omni Dual-band Omni Single Band, Dual Polarized Directional Patch AIR-ANT2568VG-N AIR-ANT2588P3M-N= Dual-band/Dual Polarized Directional, Patch AIR-ANT2513P4M-N Dual-band Polarization Diverse Patch Array Dual-band Omni
>30 degree 5 GHz Antenna Gain
(dBi) NA NA NA NA NA NA
-3
-5
-6 5
-6
-6
-6 3 1
-5 Antenna Gain
(dBi) 5 5 8 5 5 13 8 5 5 13 4 / 7 4 / 7 4 / 7 6 / 8 8 / 8 13 / 13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 9 of 62 Radio Test Report No: EDCS 18429908 Section 3: Result Summary 3.1 Results Summary Table Conducted emissions Basic Standard FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.209 FCC 15.205 Technical Requirements / Details 99% & 26 dB Bandwidth:
The 99% occupied bandwidth is the frequency bandwidth such that, below its lower and above its upper frequency limits, the mean powers are each equal to 0.5% of the total mean power of the given emission. There is no limit for 99% OBW. The 26 dB emission is the width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 26 dB relative to the maximum level measured in the fundamental emission. Output Power:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Power Spectral Density:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bandsthe maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Conducted Spurious Emissions / Band-Edge:
15.407 (3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz. Restricted band:
Unwanted emissions falling within the restricted bands, as defined in FCC 15.205 (a) must also comply with the radiated emission limits specified in FCC 15.209 (a). Result Pass Pass Pass Pass Pass Radiated Emissions (General requirements) Basic Standard FCC 15.209 FCC 15.205 FCC 15.207 Technical Requirements / Details TX Spurious Emissions:
Except as provided elsewhere in this subpart, the emissions from an intentional radiator shall not exceed the field strength levels specified in the filed strength limits table in this section. AC conducted Emissions:
Except when the requirements applicable to a given device state otherwise, for any radio apparatus equipped to operate from the public utility AC power supply, either directly or indirectly (such as with a battery charger), the radio frequency voltage of emissions conducted back onto the AC power lines in the frequency range of 0.15 MHz to 30 MHz shall not exceed the limits shown in the table in these sections. The more stringent limit applies at the frequency range boundaries. Result Pass Pass Page No: 10 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Section 4: Sample Details Note: Each sample was evaluated to ensure that its condition was suitable to be used as a test sample prior to the commencement of testing. 4.1 Sample Details Sample No. S01 S02 Equipment Details Manufacturer Hardware Rev. Firmware Rev. Software Rev. Serial Number IW-6300H-DC-B-K9 FSP150-AWAN3 Cisco Systems, Inc. FSP Group Inc. 11
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9.1.8.1 9.0.5.5-W8964 FOC23241G16
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H00000063 4.2 System Details System #
1 EUT and Power Supply 4.3 Mode of Operation Details Mode#
Description Description Samples S01, S02 Comments 1 Continuous Transmitting Continuous Transmitting 98% duty cycle This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 11 of 62 Radio Test Report No: EDCS 18429908 Appendix A: Emission Test Results Conducted Test Setup Diagram Target Maximum Channel Power The following table details the maximum supported Total Channel Power for all operating modes. Operating Mode Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M15 HT/VHT20 Beam Forming, M0 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 HT/VHT40 Beam Forming, M0 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss VHT80 Beam Forming, M0 to M9, M0 to M9 1-2ss Maximum Channel Power
(dBm) Frequency (MHz) 5500 13 11 15 15 15 5510 12 14 14 14 5530 11 13 13 5560 12 11 14 14 14 5550 12 14 14 14 5610 11 16 15 5700 14 12 14 14 14 5710 14 14 14 14 5690 11 14 14 Page No: 12 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 VHT80 STBC, M0 to M9 1ss 13 15 14 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 13 of 62 Radio Test Report No: EDCS 18429908 A.1 Duty Cycle Duty Cycle Test Requirement From KDB 789033 D02 General UNII Test Procedures New Rules v02r01 B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level 1. All measurements are to be performed with the EUT transmitting at 100 percent duty cycle at its maximum power control level; however, if 100 percent duty cycle cannot be achieved, measurements of duty cycle, x, and maximum-power transmission duration, T, are required for each tested mode of operation. Duty Cycle Test Method From KDB 789033 D02 General UNII Test Procedures New Rules v02r01:
B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level The zero-span mode on a spectrum analyzer or EMI receiver, if the response time and spacing between bins on the sweep are sufficient to permit accurate measurements of the on and off times of the transmitted signal. Set the center frequency of the instrument to the center frequency of the transmission. Set RBW EBW if possible; otherwise, set RBW to the largest available value. Set VBW RBW. Set detector = peak or average. The zero-span measurement method shall not be used unless both RBW and VBW are > 50/T, where T is defined in section II.B.1.a), and the number of sweep points across duration T exceeds 100. (For example, if VBW and/or RBW are limited to 3 MHz, then the zero-span method of measuring duty cycle shall not be used if T 16.7 microseconds.) Duty Cycle Test Information Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Date of testing:
11-Nov-19 - 11-Nov-19 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 14 of 62 Radio Test Report No: EDCS 18429908 Duty Cycle Data Table Duty Cycle table and screen captures are shown below for power/psd modes. Frequency Mode Data Rate 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 Duty Cycle correction
(dB) 0.0 0.0 0.0 0.1 0.0 0.2 0.0 0.1 0.0 0.0 0.0 0.2 0.0 0.2 0.0 0.0 0.0 0.1 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 15 of 62 Radio Test Report No: EDCS 18429908 Duty Cycle Plot, 5530, VHT80, M0 to M9, M0 to M9 1-2ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 16 of 62 Radio Test Report No: EDCS 18429908 A.2 99% and 26dB Bandwidth 99% and 26dB Bandwidth Test Requirement There is no requirement for the value of bandwidth. However, the 26dB BW (EBW) is used to calculate the power limits in 15.407 (a) (2). Power measurements are made using the 99% Bandwidth as the integration bandwidth. Band-crossing emissions: For an emission that crosses the boundary between two adjacent U-NII bands, the boundary frequency between the bands serves as one edge for defining the portion of the EBW that falls within a particular U-NII band. However, the -26 dB points are measured relative to the highest point on the contiguous segmentregardless of which band contains that highest point (Figure4). 99% and 26dB Bandwidth Test Procedure Ref. KDB 789033 Section D. 99 Percent Occupied Bandwidth ANSI C63.10: 2013 Section 6.9.3 KDB 662911 99% BW Test Parameters 1. Set center frequency to the nominal EUT channel center frequency. 2. Set span = 1.5 times to 5.0 times the OBW. 3. Set RBW = 1 % to 5 % of the OBW 4. Set VBW 3 RBW 5. Video averaging is not permitted. Where practical, a sample detection and single sweep mode shall be used. Otherwise, peak detection and max hold mode (until the trace stabilizes) shall be used. 6. Use the 99 % power bandwidth function of the instrument (if available). Ref KDB 789033 in Section C. Measurement Bandwidth, Section 1 26 BW Test parameters X dB BW = -26dB (using the OBW function of the spectrum analyzer) Emission Bandwidth (EBW) a) Set RBW = approximately 1% of the emission bandwidth. b) Set the VBW > RBW. c) Detector = Peak. d) Trace mode = max hold. Page No: 17 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 e) Measure the maximum width of the emission that is 26 dB down from the maximum of the emission. Compare this with the RBW setting of the analyzer. Readjust RBW and repeat measurement as needed until the RBW/EBW ratio is approximately 1%. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
Start Date to Finish Date here Page No: 18 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 99% and 26dB Bandwidth Table Frequency
(MHz) 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Mode Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Data Rate 26dB BW 99% BW
(Mbps)
(MHz) 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 19.7 20.5 42.5 41.0 82.2 82.6 42.0 40.7 19.9 20.3 81.8 82.5 84.4 82.2 19.8 20.2 41.5 40.9 14.9 15.1
(MHz) 16.609 17.638 36.409 36.202 76.377 76.435 36.355 36.195 16.603 17.652 76.343 76.295 76.465 76.398 16.614 17.643 36.380 36.185 13.341 13.849 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 19 of 62 Radio Test Report No: EDCS 18429908 26dB / 99% Bandwidth, 5720 MHz, Non HT20, 6 to 54 Mbps This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 20 of 62 Radio Test Report No: EDCS 18429908 A.3 Maximum Conducted Output Power Maximum Conducted Output Power Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Maximum Conducted Output Power Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 ANSI C63.10: 2013 Maximum Conducted Output Power Test Procedure 1. Set the radio in the continuous transmitting mode at full power 2. Compute power by integrating the spectrum across the EBW (or alternatively entire 99% OBW) of the signal using the instruments band power measurement function. The integration shall be performed using the spectrum analyzer band-power measurement function with band limits set equal to the EBW or the OBW band edges. Page No: 21 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 3. Capture graphs and record pertinent measurement data. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Measurement using a Spectrum Analyzer or EMI Receiver (SA), (d) Method SA-2 Maximum Conducted Output Power Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 System under Support test equipment Date of testing:
Start Date to Finish Date here Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 22 of 62 Radio Test Report No: EDCS 18429908 Maximum Output Power
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n g r a M i Non HT20, 6 to 54 Mbps 1 13 12.9 0.0 12.9 Non HT20, 6 to 54 Mbps 2 13 7.7 7.3 0.0 10.5 Non HT20 Beam Forming, 6 to 54 Mbps 2 16 7.7 7.3 0.0 10.5 HT/VHT20, M0 to M7 1 13 12.9 0.0 12.9 HT/VHT20, M0 to M7 2 13 8.7 8.5 0.0 11.7 HT/VHT20, M8 to M15 2 13 11.8 11.5 0.0 14.7 HT/VHT20 Beam Forming, M0 to M7 2 16 8.7 8.5 0.0 11.7 HT/VHT20 Beam Forming, M8 to M15 2 13 11.8 11.5 0.0 14.7 HT/VHT20 STBC, M0 to M7 2 13 11.8 11.5 0.0 14.7 17. 0 17. 0 14. 0 17. 0 17. 0 17. 0 14. 0 17. 0 17. 0 Non HT40, 6 to 54 Mbps 1 13 11.5 0.0 11.5 Non HT40, 6 to 54 Mbps 2 13 9.6 9.1 0.0 12.4 HT/VHT40, M0 to M7 1 13 11.4 0.1 11.5 HT/VHT40, M0 to M7 2 13 11.4 11.0 0.1 14.3 HT/VHT40, M8 to M15 2 13 11.4 11.0 0.1 14.3 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 2 2 16 13 7.4 7.0 11.4 11.0 0.1 0.1 10.3 14.3 17. 0 17. 0 17. 0 17. 0 17. 0 14. 0 17. Page No: 23 of 62 0 1 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 4.07 6.45 3.45 4.06 5.35 2.29 2.35 2.29 2.29 5.46 4.59 5.54 2.73 2.73 3.73 2.73 Radio Test Report No: EDCS 18429908 HT/VHT40 STBC, M0 to M7 2 13 11.4 11.0 0.1 14.3 0 17. 0 Non HT80, 6 to 54 Mbps 1 13 10.7 0.0 10.7 Non HT80, 6 to 54 Mbps 2 13 5.5 5.0 0.0 8.3 VHT80, M0 to M9 1ss 1 13 11.1 0.2 11.3 VHT80, M0 to M9 1ss 2 13 10.0 9.3 0.2 12.9 0 3 5 5 VHT80, M0 to M9 2ss 2 13 10.0 9.3 0.2 12.9 VHT80 Beam Forming, M0 to M9 1ss 2 16 5.9 5.4 0.2 8.9 VHT80 Beam Forming, M0 to M9 2ss 2 13 10.0 9.3 0.2 12.9 VHT80 STBC, M0 to M9 1ss 2 13 10.0 9.3 0.2 12.9 17. 0 17. 0 17. 0 17. 0 17. 0 14. 0 17. 0 17. 0 Non HT40, 6 to 54 Mbps 1 13 11.5 0.0 11.5 Non HT40, 6 to 54 Mbps 2 13 9.5 9.1 0.0 12.4 HT/VHT40, M0 to M7 1 13 11.4 0.1 11.5 HT/VHT40, M0 to M7 2 13 11.4 10.9 0.1 14.2 0 5 5 5 HT/VHT40, M8 to M15 2 13 11.4 10.9 0.1 14.2 HT/VHT40 Beam Forming, M0 to M7 2 16 9.3 8.8 0.1 12.1 HT/VHT40 Beam Forming, M8 to M15 2 13 11.4 10.9 0.1 14.2 HT/VHT40 STBC, M0 to M7 2 13 11.4 10.9 0.1 14.2 Non HT20, 6 to 54 Mbps 1 13 12.0 0.0 12.0 Non HT20, 6 to 54 Mbps 2 13 7.9 7.8 0.0 10.9 Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 2 1 16 13 7.9 12.1 7.8 0.0 0.0 10.9 12.1 17. 0 17. 0 14. 0 17. Page No: 24 of 62 0 6 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 2.73 6.27 8.70 5.70 4.13 4.13 5.14 4.13 4.13 5.46 4.64 5.54 2.78 2.78 1.88 2.78 2.78 4.97 6.11 3.11 4.86 17. 0 17. 0 17. 0 17. 0 17. 0 14. 0 17. 0 17. 0 Radio Test Report No: EDCS 18429908 HT/VHT20, M0 to M7 2 13 8.0 8.0 0.0 11.1 HT/VHT20, M8 to M15 2 13 11.2 11.0 0.0 14.2 HT/VHT20 Beam Forming, M0 to M7 2 16 8.0 8.0 0.0 11.1 HT/VHT20 Beam Forming, M8 to M15 2 13 11.2 11.0 0.0 14.2 HT/VHT20 STBC, M0 to M7 2 13 11.2 11.0 0.0 14.2 0 17. 0 17. 0 14. 0 17. 0 17. 0 Non HT80, 6 to 54 Mbps 1 13 11.3 0.0 11.3 Non HT80, 6 to 54 Mbps 2 13 5.2 5.0 0.0 8.1 VHT80, M0 to M9 1ss 1 13 16.1 0.2 16.3 VHT80, M0 to M9 1ss 2 13 11.7 11.4 0.2 14.8 0 1 6 5 VHT80, M0 to M9 2ss 2 13 11.7 11.4 0.2 14.8 VHT80 Beam Forming, M0 to M9 1ss 2 16 9.6 9.2 0.2 12.6 VHT80 Beam Forming, M0 to M9 2ss 2 13 11.7 11.4 0.2 14.8 VHT80 STBC, M0 to M9 1ss 2 13 11.7 11.4 0.2 14.8 17. 0 17. 0 17. 0 17. 0 17. 0 14. 0 17. 0 17. 0 Non HT80, 6 to 54 Mbps 1 13 11.1 0.0 11.1 Non HT80, 6 to 54 Mbps 2 13 7.9 7.7 0.0 10.8 VHT80, M0 to M9 1ss 1 13 13.4 0.2 13.6 VHT80, M0 to M9 1ss 2 13 11.4 11.0 0.2 14.4 0 9 6 5 VHT80, M0 to M9 2ss 2 13 11.4 11.0 0.2 14.4 VHT80 Beam Forming, M0 to M9 1ss 2 16 9.1 9.0 0.2 12.3 VHT80 Beam Forming, M0 to M9 2ss 2 13 11.4 11.0 0.2 14.4 VHT80 STBC, M0 to M9 1ss 2 13 11.4 11.0 0.2 14.4 17. 0 17. 0 17. 0 17. 0 17. 0 14. 0 17. 0 17. 0 5.95 2.85 2.95 2.85 2.85 5.67 8.86 0.70 2.24 2.24 1.39 2.24 2.24 5.87 6.16 3.40 2.59 2.59 1.74 2.59 2.59 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 25 of 62 Radio Test Report No: EDCS 18429908 Non HT20, 6 to 54 Mbps 1 13 14.0 0.0 14.0 Non HT20, 6 to 54 Mbps 2 13 7.9 9.2 0.0 11.6 Non HT20 Beam Forming, 6 to 54 Mbps 2 16 7.9 9.2 0.0 11.6 HT/VHT20, M0 to M7 1 13 13.4 0.0 13.4 0 0 7 5 HT/VHT20, M0 to M7 2 13 7.1 8.5 0.0 10.9 HT/VHT20, M8 to M15 2 13 10.0 11.3 0.0 13.8 HT/VHT20 Beam Forming, M0 to M7 2 16 7.1 8.5 0.0 10.9 HT/VHT20 Beam Forming, M8 to M15 2 13 10.0 11.3 0.0 13.8 HT/VHT20 STBC, M0 to M7 2 13 10.0 11.3 0.0 13.8 17. 0 17. 0 14. 0 17. 0 17. 0 17. 0 14. 0 17. 0 17. 0 Non HT40, 6 to 54 Mbps 1 13 13.7 0.0 13.7 Non HT40, 6 to 54 Mbps 2 13 8.8 9.3 0.0 12.1 HT/VHT40, M0 to M7 1 13 13.5 0.1 13.6 HT/VHT40, M0 to M7 2 13 10.2 10.9 0.1 13.6 0 1 7 5 HT/VHT40, M8 to M15 2 13 10.2 10.9 0.1 13.6 HT/VHT40 Beam Forming, M0 to M7 2 16 8.5 9.1 0.1 11.9 HT/VHT40 Beam Forming, M8 to M15 2 13 10.2 10.9 0.1 13.6 HT/VHT40 STBC, M0 to M7 2 13 10.2 10.9 0.1 13.6 17. 0 17. 0 17. 0 17. 0 17. 0 14. 0 17. 0 17. 0 57 20 Non HT20, 6 to 54 Mbps 1 13 12.7 0.0 12.7 17. 0 17. 0 Non HT20, 6 to 54 Mbps 2 13 6.5 7.8 0.0 10.2 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 26 of 62 2.97 5.36 2.36 3.56 6.09 3.25 3.09 3.25 3.25 3.26 4.89 3.44 3.37 3.37 2.12 3.37 3.37 4.27 6.76 Radio Test Report No: EDCS 18429908 Non HT20 Beam Forming, 6 to 54 Mbps 2 16 6.5 7.8 0.0 10.2 HT/VHT20, M0 to M7 1 13 12.7 0.0 12.7 HT/VHT20, M0 to M7 2 13 6.6 7.9 0.0 10.4 HT/VHT20, M8 to M15 2 13 9.4 10.7 0.0 13.2 HT/VHT20 Beam Forming, M0 to M7 2 16 6.6 7.9 0.0 10.4 HT/VHT20 Beam Forming, M8 to M15 2 13 9.4 10.7 0.0 13.2 HT/VHT20 STBC, M0 to M7 2 13 9.4 10.7 0.0 13.2 14. 0 17. 0 17. 0 17. 0 14. 0 17. 0 17. 0 3.76 4.26 6.65 3.85 3.65 3.85 3.85 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 27 of 62 Radio Test Report No: EDCS 18429908 Maximum Transmit Output Power, 5610 MHz, VHT80, M0 to M9 1ss Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 28 of 62 Radio Test Report No: EDCS 18429908 A.4 Power Spectral Density Power Spectral Density Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Power Spectral Density Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test Procedure The rules requires maximum power spectral density measurements where the intent is to measure the maximum value of the time average of the power spectral density measured during a period of continuous transmission. 1. Create an average power spectrum for the EUT operating mode being tested by following the instructions in section II.E.2. for measuring maximum conducted output power using a spectrum analyzer or EMI receiver: select the Page No: 29 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 appropriate test method (SA-1, SA-2, SA-3, or alternatives to each) and apply it up to, but not including, the step labeled, Compute power. (This procedure is required even if the maximum conducted output power measurement was performed using a power meter, method PM.) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. b) If Method SA-3 Alternative was used and the linear mode was used in step II.E.2.g)(viii), add 1 dB to the final result to compensate for the difference between linear averaging and power averaging. 4. The result is the Maximum PSD over 1 MHz reference bandwidth. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) F. Maximum Power Spectral Density (PSD) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 30 of 62 Radio Test Report No: EDCS 18429908 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment Date of testing:
Start Date to Finish Date here Page No: 31 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Power Spectral Density
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-2.1 0.4 0.0 0.0 0.0 0.0 0.0 0.0 3.6 0.9 0.9 2.6 0.3 2.8 4.0 1.0 4.0 1.0 4.0 1.0 4.0 4.0 4.0 1.0 1.0 4.0 1.0 4.0 1.0 4.0 4.0 4.0 1.0 4.0 1.0 4.0 1.0 4.0 4.0 4.0 1.0 4.0 1.0 4.0 1.0 4.0 4.0 4.0 1.0 1.0 4.0 1.0 4.0 6.16 2.14 6.54 0.63 3.63 2.78 3.63 3.63 2.87 0.81 0.81 2.46 0.75 0.60 0.75 0.60 0.60 9.57 9.85 5.20 3.64 6.64 5.89 6.64 6.64 9.87 6.90 8.00 3.79 6.79 6.09 6.79 6.79 0.37 0.07 0.07 1.36 0.73 1.19 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 33 of 62 0 0 7 5 Radio Test Report No: EDCS 18429908 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 16 13 13
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-2.0 0.9 0.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 3.1 0.8 0.8 2.9 0.5 3.3 0.5 3.3 3.3 1.0 4.0 4.0 4.0 1.0 4.0 1.0 4.0 1.0 4.0 4.0 4.0 1.0 1.0 4.0 1.0 4.0 1.0 4.0 4.0 0.73 1.19 1.19 3.66 2.59 4.54 1.07 4.07 2.88 4.07 4.07 0.87 0.22 0.22 1.06 0.51 0.69 0.51 0.69 0.69 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 34 of 62 Radio Test Report No: EDCS 18429908 Power Spectral Density, 5500 MHz, HT/VHT20, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 35 of 62 Radio Test Report No: EDCS 18429908 A.5 Conducted Spurious Emissions Conducted Spurious Emissions Test Requirement 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Spurious Emissions Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 36 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Add the max antenna gain + ground reflection factor (4.7 dB for frequencies between 30 MHz and 1000 MHz, and 0 dB for frequencies > 1000 MHz). Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
11-Nov-19 - 11-Nov-19 Page No: 37 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Conducted Spurs Average Upper Conducted Spurs Peak Upper This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 38 of 62 Radio Test Report No: EDCS 18429908 Conducted Spurious Average Table
) i
) m B d
(
r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
-54.3
-60.2
-62.3
-60.2
-62.3
-54.5
-59.9
-61.8
-58.7
-60.3
-59.9
-61.8
-58.7
-60.3
-58.7
-60.3
) B d
(
n o i t c e r r o C e l c y C y t u D 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
(
r u p S d e t c u d n o C l a t o T
) m B d
(
t i m L i
) B d
(
n g r a M i
-41.3
-41.25 0.02
-45.1
-41.25 3.83
-42.1
-41.25 0.83
-41.5
-41.25 0.21
-44.7
-41.25 3.44
-43.4
-41.25 2.12
-41.7
-41.25 0.44
-43.4
-41.25 2.12
-43.4
-41.25 2.12
-54.5
-59.3
-61.5
-58.7
-58.7
-60.6
-58.7
-60.6
-60.0
-62.2
-58.7
-60.6
-58.7
-60.6 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-41.5
-41.25 0.21
-44.2
-41.25 2.96
-45.6
-41.25 4.39
-43.5
-41.25 2.23
-43.5
-41.25 2.23
-41.9
-41.25 0.64
-43.5
-41.25 2.23
-43.5
-41.25 2.23
-54.4
-60.4
-62.8
-58.9
-59.2
-61.4
-59.2
-61.4
-64.6
-66.3
-59.2
-61.4
-59.2
-61.4 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-41.4
-41.25 0.12
-45.4
-41.25 4.14
-45.7
-41.25 4.45
-44.0
-41.25 2.70
-44.0
-41.25 2.70
-46.2
-41.25 4.91
-44.0
-41.25 2.70
-44.0
-41.25 2.70 B d
(
i n a G a n n e t n A d e t a l e r r o C 13 13 16 13 13 13 16 13 13 13 13 13 13 13 16 13 13 13 13 13 13 13 16 13 13 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
) z H M
(
y c n e u q e r F 0 0 5 5 Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Page No: 39 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 0 5 5 5 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 13 13 13 13 13 16 13 13 13 13 16 13 13 13 16 13 13 13 13 13 13 13 16 13 13 13 13 13 13 13 16 13 13 13 13 16 13 13 13
-54.4
-59.2
-61.5
-58.5
-58.5
-60.9
-58.5
-60.9
-59.3
-61.7
-58.5
-60.9
-58.5
-60.9 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-41.4
-41.25 0.11
-44.1
-41.25 2.90
-45.4
-41.25 4.19
-43.5
-41.25 2.22
-43.5
-41.25 2.22
-41.3
-41.25 0.02
-43.5
-41.25 2.22
-43.5
-41.25 2.22
-54.7
-59.9
-62.1
-59.9
-62.1
-54.4
-59.9
-61.9
-58.6
-60.9
-59.9
-61.9
-58.6
-60.9
-58.6
-60.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-41.7
-41.25 0.42
-44.8
-41.25 3.57
-41.8
-41.25 0.57
-41.4
-41.25 0.11
-44.7
-41.25 3.48
-43.5
-41.25 2.30
-41.7
-41.25 0.48
-43.5
-41.25 2.30
-43.5
-41.25 2.30
-54.9
-61.0
-63.4
-54.5
-58.2
-60.8
-58.2
-60.8
-59.5
-62.0
-58.2
-60.8
-58.2
-60.8 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-41.9
-41.25 0.62
-46.0
-41.25 4.74
-41.3
-41.25 0.05
-43.1
-41.25 1.85
-43.1
-41.25 1.85
-41.4
-41.25 0.12
-43.1
-41.25 1.85
-43.1
-41.25 1.85
-55.8
-56.6
-58.2
-54.7
-58.4
-60.5
-58.4
-60.5
-59.7
-61.9
-58.4
-60.5
-58.4
-60.5 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-42.8
-41.25 1.52
-41.3
-41.25 0.03
-41.5
-41.25 0.25
-43.1
-41.25 1.87
-43.1
-41.25 1.87
-41.5
-41.25 0.20
-43.1
-41.25 1.87
-43.1
-41.25 1.87
-54.4
-60.2
-61.5
-60.2
-61.5
-54.6
-60.8
-61.9
-59.0
-60.0 0.0 0.0 0.0 0.0 0.0 0.0
-41.4
-41.25 0.12
-44.8
-41.25 3.51
-41.8
-41.25 0.51
-41.6
-41.25 0.31
-45.3
-41.25 4.01
-43.4
-41.25 2.17 Page No: 40 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 16 13 13 13 13 13 13 13 16 13 13 13 13 16 13 13 13 16 13 13
-60.8
-61.9
-59.0
-60.0
-59.0
-60.0 0.0 0.0 0.0
-42.3
-41.25 1.01
-43.4
-41.25 2.17
-43.4
-41.25 2.17
-54.4
-59.8
-61.2
-54.5
-58.8
-60.0
-58.8
-60.0
-59.8
-61.1
-58.8
-60.0
-58.8
-60.0 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-41.4
-41.25 0.11
-44.4
-41.25 3.14
-41.4
-41.25 0.19
-43.3
-41.25 2.04
-43.3
-41.25 2.04
-41.3
-41.25 0.08
-43.3
-41.25 2.04
-43.3
-41.25 2.04
-54.6
-60.6
-61.6
-60.6
-61.6
-54.4
-60.3
-61.3
-58.7
-59.4
-60.3
-61.3
-58.7
-59.4
-58.7
-59.4 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-41.6
-41.25 0.32
-45.0
-41.25 3.78
-42.0
-41.25 0.78
-41.4
-41.25 0.11
-44.7
-41.25 3.47
-43.0
-41.25 1.73
-41.7
-41.25 0.47
-43.0
-41.25 1.73
-43.0
-41.25 1.73 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 41 of 62 Radio Test Report No: EDCS 18429908 Conducted Spurs Average, 5500 MHz, Non HT20, 6 to 54 Mbps Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 42 of 62 Radio Test Report No: EDCS 18429908 Conducted Spurious Emissions Peak Table
) i
) z H M
(
y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss B d
(
i n a G a n n e t n A d e t a s h t a P x T l e r r o C 13 13 16 13 13 13 16 13 13 1 2 2 1 2 2 2 2 2
) m B d
(
r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
-48.2
-52.8
-51.9
-52.8
-51.9
-47.7
-51.7
-51.6
-50.6
-49.9
-51.7
-51.6
-50.6
-49.9
-50.6
-49.9
) m B d
(
r e w o P r u p S 3 x T 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
(
r u p S d e t c u d n o C l a t o T
) m B d
(
t i m L i
) B d
(
n g r a M i
-35.2
-21.25 13.92
-36.3
-21.25 15.03
-33.3
-21.25 12.03
-34.7
-21.25 13.41
-35.6
-21.25 14.35
-34.2
-21.25 12.93
-32.6
-21.25 11.35
-34.2
-21.25 12.93
-34.2
-21.25 12.93 1 2 1 2 2 2 2 2 13 13 13 13 13 16 13 13
-48.9
-51.5
-50.8
-50.7
-50.7
-50.5
-50.7
-50.5
-53.3
-52.2
-50.7
-50.5
-50.7
-50.5 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-35.9
-21.25 14.61
-35.1
-21.25 13.83
-37.6
-21.25 16.39
-34.5
-21.25 13.28
-34.5
-21.25 13.28
-33.6
-21.25 12.40
-34.5
-21.25 13.28
-34.5
-21.25 13.28 1 2 1 2 2 2 2 2 13 13 13 13 13 16 13 13
-49.1
-53.7
-53.0
-51.4
-51.9
-51.3
-51.9
-51.3
-56.0
-54.9
-51.9
-51.3
-51.9
-51.3 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-36.1
-21.25 14.82
-37.3
-21.25 16.04
-38.2
-21.25 16.95
-35.4
-21.25 14.13
-35.4
-21.25 14.13
-36.2
-21.25 14.96
-35.4
-21.25 14.13
-35.4
-21.25 14.13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 43 of 62 Radio Test Report No: EDCS 18429908 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 13 13 13 13 13 16 13 13
-48.8
-51.7
-51.4
-51.9
-51.9
-50.2
-51.9
-50.2
-52.9
-50.8
-51.9
-50.2
-51.9
-50.2 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-35.8
-21.25 14.51
-35.5
-21.25 14.25
-38.8
-21.25 17.59
-34.9
-21.25 13.65
-34.9
-21.25 13.65
-32.7
-21.25 11.41
-34.9
-21.25 13.65
-34.9
-21.25 13.65 1 2 2 1 2 2 2 2 2 13 13 16 13 13 13 16 13 13
-48.0
-53.4
-53.0
-53.4
-53.0
-48.7
-53.3
-52.5
-51.2
-50.9
-53.3
-52.5
-51.2
-50.9
-51.2
-50.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-35.0
-21.25 13.72
-37.2
-21.25 15.90
-34.2
-21.25 12.90
-35.7
-21.25 14.41
-36.8
-21.25 15.58
-35.0
-21.25 13.74
-33.8
-21.25 12.58
-35.0
-21.25 13.74
-35.0
-21.25 13.74 1 2 1 2 2 2 2 2 13 13 13 13 13 16 13 13
-49.2
-55.2
-54.1
-48.3
-50.6
-51.5
-50.6
-51.5
-52.9
-52.2
-50.6
-51.5
-50.6
-51.5 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-36.2
-21.25 14.92
-38.6
-21.25 17.32
-35.1
-21.25 13.85
-34.8
-21.25 13.57
-34.8
-21.25 13.57
-33.3
-21.25 12.08
-34.8
-21.25 13.57
-34.8
-21.25 13.57 1 2 1 2 2 2 2 2 13 13 13 13 13 16 13 13
-49.1
-49.1
-48.9
-48.3
-52.4
-51.7
-52.4
-51.7
-52.7
-52.1
-52.4
-51.7
-52.4
-51.7 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-36.1
-21.25 14.82
-33.0
-21.25 11.71
-35.1
-21.25 13.85
-35.8
-21.25 14.58
-35.8
-21.25 14.58
-33.2
-21.25 11.93
-35.8
-21.25 14.58
-35.8
-21.25 14.58 1 2 2 1 2 2 13 13 16 13 13 13
-48.3
-52.6
-51.2
-52.6
-51.2
-48.4
-53.0
-53.0
-51.0
-50.6 0.0 0.0 0.0 0.0 0.0 0.0
-35.3
-21.25 14.02
-35.8
-21.25 14.55
-32.8
-21.25 11.55
-35.4
-21.25 14.11
-36.9
-21.25 15.70
-34.7
-21.25 13.49 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 44 of 62 Radio Test Report No: EDCS 18429908 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 16 13 13
-53.0
-53.0
-51.0
-50.6
-51.0
-50.6 0.0 0.0 0.0
-33.9
-21.25 12.70
-34.7
-21.25 13.49
-34.7
-21.25 13.49 13 13 13 13 13 16 13 13
-48.1
-53.5
-52.4
-47.2
-52.8
-51.4
-52.8
-51.4
-53.1
-52.1
-52.8
-51.4
-52.8
-51.4 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-35.1
-21.25 13.81
-36.9
-21.25 15.61
-34.1
-21.25 12.89
-36.0
-21.25 14.73
-36.0
-21.25 14.73
-33.5
-21.25 12.25
-36.0
-21.25 14.73
-36.0
-21.25 14.73 13 13 16 13 13 13 16 13 13
-48.8
-53.6
-52.2
-53.6
-52.2
-48.1
-52.0
-51.8
-52.2
-51.2
-52.0
-51.8
-52.2
-51.2
-52.2
-51.2 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-35.8
-21.25 14.52
-36.8
-21.25 15.55
-33.8
-21.25 12.55
-35.1
-21.25 13.81
-35.8
-21.25 14.60
-35.6
-21.25 14.37
-32.8
-21.25 11.60
-35.6
-21.25 14.37
-35.6
-21.25 14.37 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 45 of 62 Radio Test Report No: EDCS 18429908 Conducted Spurs Peak, 5500 MHz, HT/VHT20 Beam Forming, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 46 of 62 Radio Test Report No: EDCS 18429908 A.6 Conducted Bandedge 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Band Edge Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI Page No: 47 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 C63.10:2013 section 14.3.2.2) 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging System under Support test equipment Date of testing:
11-Nov-19 - 11-Nov-19 Page No: 48 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Conducted Bandedge Average Table
) i
) z H M
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y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss i B d
(
n a G a n n e t n A d e t a s h t a P x T l e r r o C 13 13 16 13 13 13 16 13 13 1 2 2 1 2 2 2 2 2
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(
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n o i t c e r r o C e l c y C y t u D
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l e v e L e g d e d n a B x T l a t o T
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(
t i m L i
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(
n g r a M i
-57.9
-62.8
-63.5
-62.8
-63.5
-58.1
-62.8
-63.9
-61.1
-62.2
-62.8
-63.9
-61.1
-62.2
-61.1
-62.2 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-44.9
-41.25 3.62
-47.1
-41.25 5.84
-44.1
-41.25 2.84
-45.1
-41.25 3.81
-47.3
-41.25 6.01
-45.6
-41.25 4.31
-44.3
-41.25 3.01
-45.6
-41.25 4.31
-45.6
-41.25 4.31 1 2 1 2 2 2 2 2 13 13 13 13 13 16 13 13
-55.9
-60.3
-61.4
-59.9
-59.9
-59.9
-59.9
-59.9
-59.4
-63.5
-59.9
-59.9
-59.9
-59.9 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-42.9
-41.25 1.61
-44.8
-41.25 3.51
-46.8
-41.25 5.59
-43.8
-41.25 2.58
-43.8
-41.25 2.58
-41.9
-41.25 0.67
-43.8
-41.25 2.58
-43.8
-41.25 2.58 1 2 1 2 2 2 2 2 13 13 13 13 13 16 13 13
-54.7
-60.8
-60.8
-56.0
-57.1
-58.2
-57.1
-58.2
-61.6
-63.4
-57.1
-58.2
-57.1
-58.2 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-41.7
-41.25 0.42
-44.8
-41.25 3.51
-42.8
-41.25 1.55
-41.4
-41.25 0.16
-41.4
-41.25 0.16
-43.2
-41.25 1.95
-41.4
-41.25 0.16
-41.4
-41.25 0.16 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 49 of 62 Radio Test Report No: EDCS 18429908 Conducted Bandedge Average, 5530 MHz, VHT80, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 50 of 62 Radio Test Report No: EDCS 18429908 Conducted Bandedge Peak Table
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-44.4
-31.4
-21.25 10.12
-50.2
-51.6
-34.8
-21.25 13.55
-50.2
-51.6
-31.8
-21.25 10.55
-44.0
-31.0
-21.25 9.71
-50.2
-49.3
-33.7
-21.25 12.42
-46.7
-49.0
-31.6
-21.25 10.40
-50.2
-49.3
-30.7
-21.25 9.42
-46.7
-49.0
-31.6
-21.25 10.40
-46.7
-49.0
-31.6
-21.25 10.40
-41.2
-28.2
-21.25 6.91
-36.3
-46.0
-22.8
-21.25 1.57
-39.7
-26.6
-21.25 5.39
-39.7
-42.4
-24.8
-21.25 3.53
-39.7
-42.4
-24.8
-21.25 3.53
-44.4
-40.2
-22.7
-21.25 1.49
-39.7
-42.4
-24.8
-21.25 3.53
-39.7
-42.4
-24.8
-21.25 3.53
-43.6
-30.6
-21.25 9.32
-48.1
-48.4
-32.2
-21.25 10.95
-42.6
-29.4
-21.25 8.15
-48.5
-45.5
-30.5
-21.25 9.29
-48.5
-45.5
-30.5
-21.25 9.29
-45.9
-47.8
-27.5
-21.25 6.29
-48.5
-45.5
-30.5
-21.25 9.29
-48.5
-45.5
-30.5
-21.25 9.29 i B d
(
n a G a n n e t n A d e t a l e r r o C 13 13 16 13 13 13 16 13 13 13 13 13 13 13 16 13 13 13 13 13 13 13 16 13 13 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 Page No: 51 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 13 13 16 13 13 13 16 13 13 1 2 2 1 2 2 2 2 2
-40.8
-27.8
-21.25 6.52
-50.1
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-29.2
-21.25 7.94
-50.1
-43.0
-26.2
-21.25 4.94
-42.3
-29.3
-21.25 8.01
-40.5
-46.9
-26.6
-21.25 5.31
-48.0
-41.7
-27.7
-21.25 6.49
-40.5
-46.9
-23.6
-21.25 2.31
-48.0
-41.7
-27.7
-21.25 6.49
-48.0
-41.7
-27.7
-21.25 6.49 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 52 of 62 Radio Test Report No: EDCS 18429908 Conducted Bandedge Peak, 5510 MHz, HT/VHT40 Beam Forming, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 53 of 62 Radio Test Report No: EDCS 18429908 Conducted Bandedge Peak, 5700 MHz, HT/VHT20 Beam Forming, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 54 of 62 Radio Test Report No: EDCS 18429908 Appendix B: List of Test Equipment Used to perform the test Equip#
Manufacturer/ Model Description Last Cal Next Due RF Conducted at output antenna port 7329 OMEGA/CT485B Chart Recorder 18 Feb. 2019 18 Feb. 2020 49516 Keysight (Agilent/HP) / N9030A PXA Signal Analyzer, 3Hz to 50GHz 29 Nov. 2019 29 Nov. 2019 55097 Nattional Instruments / PXI-1042 Chassis PXI Cal Not Required Cal Not Required 56089 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 56328 Pasternack / PE5019-1 Torque Wrench 13 Feb. 2019 13 Feb. 2020 57233 Nattional Instruments / PXI-8115 Embedded Controller Cal Not Required Cal Not Required 57253 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 57254 National Instruments / PXI-2799 Switch 1x1 Verify Before Use Verify Before Use 57479 CISCO / ATIL Automation Test Insertion Loss System Verify Before Use Verify Before Use This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 55 of 62 Radio Test Report No: EDCS 18429908 Appendix C: Abbreviation Key and Definitions The following table defines abbreviations used within this test report. Abbreviation Description Abbreviation Description F C Temp Electro Magnetic Compatibility Electro Magnetic Interference Equipment Under Test Information Technology Equipment S/N Qty Test Assessment Schedule emf Electro Static Discharge Electric Fast Transient RMS Qp Engineering Document Control System Configuration Cisco Number (unique identification number for Cisco test equipment) Calibration Av Pk kHz MHz GHz H V dB V kV V A A mS S European Norm International Electro technical Commission International Special Committee on Radio Interference Coupling/Decoupling Network Line Impedance Stabilization Network Protective Earth Ground Line 1 Line2 Line 3 Direct Current Uncorrected measurement value, as indicated by the measuring device Radio Frequency Signal Line Conducted Emissions Measurement distance Not Applicable Power Line Neutral Line Supply EMC EMI EUT ITE TAP ESD EFT EDCS Config CIS#
Cal EN IEC CISPR CDN LISN PE GND L1 L2 L3 DC RAW RF SLCE Meas dist N/A or NA P N S Degrees Fahrenheit Degrees Celsius Temperature Serial Number Quantity Electromotive force Root mean square Quasi Peak Average Peak Kilohertz (1x103) MegaHertz (1x106) Gigahertz (1x109) Horizontal Vertical decibel Volt Kilovolt (1x103) Microvolt (1x10-6) Amp Micro Amp (1x10-6) Milli Second (1x10-3) Micro Second (1x10-6) S m Spec dist SL L R AC Micro Second (1x10-6) Meter Specification distance Signal Line (or Telecom Line) Live Line Return Alternating Current This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 56 of 62 Radio Test Report No: EDCS 18429908 Appendix D: Photographs of Test Setups Title: EUT Pictures Page No: 57 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 58 of 62 Radio Test Report No: EDCS 18429908 Title: Radio Conducted Test Setup Page No: 59 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Appendix E: Software Used to Perform Testing EMIsoft Vasona, version 6.024 Page No: 60 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Appendix F: Test Procedures Measurements were made in accordance with KDB 789033 - D02 General UNII Test Procedures New Rules v02r01 KDB 662911 - MIMO ANSI C63.4 2014 Unintentional Radiators ANSI C63.10 2013 Intentional Radiators Test procedures are summarized below:
FCC 5GHz Test Procedures FCC 5GHz RSE Test Procedures EDCS # 1445048 EDCS # 1511600 Page No: 61 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429908 Appendix G: Scope of Accreditation (A2LA certificate number 1178-01) The scope of accreditation of Cisco Systems, Inc. can be found on the A2LA web page at:
http://www.a2la.org/scopepdf/1178-01.pdf End This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 62 of 62
1 2 3 4 5 6 | UNI IIC INT 5B | External Photos | 2.78 MiB | September 12 2019 |
Radio Test Report No: EDCS 18429904 Test Report IW-6300H Series Access Point Cisco Industrial Wireless Hazardous Location Access Point FCC ID: LDKESW6300 IC ID: 2461D-ESW6300 5470-5725 MHz Inside Antennas, 5dBi Gain Against the following Specifications:
CFR47 Part 15.407 Cisco Systems 170 West Tasman Drive San Jose, CA 95134 Approved By: Adam Walb Title: MGR. IoT Compliance Revision: 1.0 Author: Julian Land Tested By: Julian Land This report replaces any previously entered test report under EDCS 18429904.This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. Test Report Template EDCS# 11644124. Page No: 1 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. SECTION 1: OVERVIEW ......................................................................................................................................... 3 SECTION2: ASSESSMENT INFORMATION ........................................................................................................ 4 2.1 GENERAL ............................................................................................................................................................. 4 2.2 DATE OF TESTING................................................................................................................................................. 6 2.3 REPORT ISSUE DATE ............................................................................................................................................ 6 2.4 TESTING FACILITIES ............................................................................................................................................. 6 2.5 EQUIPMENT ASSESSED (EUT) .............................................................................................................................. 6 2.6 EUT DESCRIPTION ............................................................................................................................................... 7 SECTION 3: RESULT SUMMARY ........................................................................................................................ 10 3.1 RESULTS SUMMARY TABLE ............................................................................................................................... 10 SECTION 4: SAMPLE DETAILS ........................................................................................................................... 11 4.1 SAMPLE DETAILS ............................................................................................................................................... 11 4.2 SYSTEM DETAILS ............................................................................................................................................... 11 4.3 MODE OF OPERATION DETAILS .......................................................................................................................... 11 APPENDIX A: EMISSION TEST RESULTS ........................................................................................................ 12 CONDUCTED TEST SETUP DIAGRAM ........................................................................................................................ 12 TARGET MAXIMUM CHANNEL POWER .................................................................................................................... 12 A.2 99% AND 26DB BANDWIDTH ............................................................................................................................ 16 A.3 MAXIMUM CONDUCTED OUTPUT POWER ......................................................................................................... 20 A.4 POWER SPECTRAL DENSITY .............................................................................................................................. 28 A.5 CONDUCTED SPURIOUS EMISSIONS ................................................................................................................... 35 A.6 CONDUCTED BANDEDGE ................................................................................................................................... 46 APPENDIX B:
NOT DEFINED. LIST OF TEST EQUIPMENT USED TO PERFORM THE TEST . ERROR! BOOKMARK APPENDIX C: ABBREVIATION KEY AND DEFINITIONS ............................................................................. 54 APPENDIX D:
PHOTOGRAPHS OF TEST SETUPS ................................................................................... 56 APPENDIX E:
SOFTWARE USED TO PERFORM TESTING ................................................................... 59 APPENDIX F:
TEST PROCEDURES ............................................................................................................. 60 APPENDIX G: SCOPE OF ACCREDITATION (A2LA CERTIFICATE NUMBER 1178-01) ........................ 61 Page No: 2 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Section 1: Overview The samples were assessed against the tests detailed in section 3 under the requirements of the following specifications:
Specifications:
CFR47 Part 15.407 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 3 of 61 b) c) d) e) Radio Test Report No: EDCS 18429904 Section2: Assessment Information 2.1 General This report contains an assessment of an apparatus against Electromagnetic Compatibility Standards based upon tests carried out on the samples submitted. The testing was performed by and for the use of Cisco systems Inc:
With regard to this assessment, the following points should be noted:
a) The results contained in this report relate only to the items tested and were obtained in the period between the date of the initial assessment and the date of issue of the report. Manufactured products will not necessarily give identical results due to production and measurement tolerances. The apparatus was set up and exercised using the configuration and modes of operation defined in this report only. Where relevant, the apparatus was only assessed using the susceptibility criteria defined in this report and the Test Assessment Plan (TAP). All testing was performed under the following environmental conditions:
Temperature 15C to 35C (54F to 95F) Atmospheric Pressure 860mbar to 1060mbar (25.4" to 31.3") Humidity 10% to 75*%
All AC testing was performed at one or more of the following supply voltages:
110V 60 Hz (+/-20%) Units of Measurement The units of measurements defined in the appendices are reported in specific terms, which are test dependent. Where radiated measurements are concerned these are defined at a particular distance. Basic voltage measurements are defined in units of [dBuV]
As an example, the basic calculation for all measurements is as follows:
The combinations of correction factors are dependent upon the exact test configurations [see test equipment lists for further details] and may include:-
Emission level [dBuV] = Indicated voltage level [dBuV] + Cable Loss [dB] + Other correction factors [dB]
Antenna Factors, Pre Amplifier Gain, LISN Loss, Pulse Limiter Loss and Filter Insertion Loss Note: to convert the results from dBuV/m to uV/m use the following formula:-
Level in uV/m = Common Antilogarithm [(X dBuV/m)/20] = Y uV/m This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 4 of 61 Radio Test Report No: EDCS 18429904 Measurement Uncertainty Values voltage and power measurements 2 dB conducted EIRP measurements 1.4 dB radiated measurements 3.2 dB frequency measurements 2.4 10-7 temperature measurements humidity measurements 0.54 2.3%
DC and low frequency measurements 2.5%
Where relevant measurement uncertainty levels have been estimated for tests performed on the apparatus. This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2. Radiated emissions (expanded uncertainty, confidence interval 95%) 30 MHz - 300 MHz 300 MHz - 1000 MHz 1 GHz - 10 GHz 10 GHz - 18GHz 18GHz - 26.5GHz 26.5GHz - 40GHz
+/- 3.8 dB
+/- 4.3 dB
+/- 4.0 dB
+/- 8.2 dB
+/- 4.1 dB
+/- 3.9 dB Conducted emissions (expanded uncertainty, confidence interval 95%) A product is considered to comply with a requirement if the nominal measured value is below the limit line. The product is considered to not be in compliance in case the nominal measured value is above the limit line. 30 MHz 40GHz
+/- 0.38 dB This report must not be reproduced except in full, without written approval of Cisco Systems. Page No: 5 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 2.2 Date of testing 11-Nov-19 - 11-Nov-19 2.3 Report Issue Date 11/11/2019 Cisco uses an electronic system to issue, store and control the revision of test reports. This system is called the Engineering Document Control System (EDCS). The actual report issue date is embedded into the original file on EDCS. Any copies of this report, either electronic or paper, that are not on EDCS must be considered uncontrolled. 2.4 Testing facilities This assessment was performed by:
Testing Laboratory Cisco Systems, Inc. 125 West Tasman Drive (Building P) San Jose, CA 95134 USA Headquarters Cisco Systems, Inc., 170 West Tasman Drive San Jose, CA 95134, USA Registration Numbers for Industry Canada Cisco System Site Address Building P, 10m Chamber Building P, 5m Chamber Building I, 5m Chamber 125 West Tasman Dr San Jose, CA 95134 125 West Tasman Dr San Jose, CA 95134 285 W. Tasman Drive San Jose, California 95134 Site Identifier Company #: 2461N-2 Company #: 2461N-1 Company #: 2461M-1 Building 7, 5m Chamber 425 E. Tasman Drive Company #: 2461N-3 San Jose, California 95134 Test Engineers Julian Land 2.5 Equipment Assessed (EUT) IW 6300H Page No: 6 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 2.6 EUT Description The radio supports the following modes of operation. The modes are further defined in the radio Theory of Operation. The modes included in this report represent the worst case data for all modes. 802.11a - Non HT20, Two Antennas, 6 to 54 Mbps, 1ss 802.11a - Non HT20 Beam Forming, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT20, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT40, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT40, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT40, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT80, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT80, Two Antennas, 6 to 54 Mbps, 1ss 802.11ac - VHT80, One Antenna, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 1ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 STBC, Two Antennas, M0 to M9 2ss 802.11a - Non HT20, One Antenna, 6 to 54 Mbps, 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 7 of 61 Radio Test Report No: EDCS 18429904 Model / PID Differences IW-6300H-AC-x-K9, IW-6300H-DC-x-K9, IW-6300-DCW-x-K9 and ESW-6300-CON-x-K9, all have the same identical components, electronics circuitries, PCB layout and enclosure. The only differences are listed as below:
IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300-DCW-x-K9 ESW-6300-CON-x-K9 Where x can be replaced with another letter to indicate country domain. Domain letters: A, B, C, D, E, F, H, I, L, M, N, Q, R, S, T, Z Where AC is Alternating Current (AC power supply) Where DC is Direct Current (DC power supply), 54V native input Where DCW is Direct Current; wide range 10-36VDC Where K9 is encryption software. Page No: 8 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 The following antennas are supported by this product series. The data included in this report represent the worst case data for all antennas. Frequency Part Number AIR-ANT2450V-N Antenna Type Single Band Omni AIR-ANT2450V-N-HZ Single Band Omni, Hazloc 2.4 GHz AIR-ANT2480V-N AIR-ANT2450HG-N AIR-ANT2450VG-N AIR-ANT2413P2M-N Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni Single Band, Dual Polarized Directional Patch 5 GHz 2.4/5 GHz Single Band Omni Horizontal Polarized Omni AIR-ANT5180V-N AIR-ANT5150HG-N AIR-ANT5150VG-N AIR-ANT5114P2M-N AIR-ANT2547V-N=
AIR-ANT2547VG-N= Dual-band Omni, Gray AIR-ANT2547V-N-HZ= Dual-band Omni, Hazloc Vertical Polarized Omni Dual-band Omni Single Band, Dual Polarized Directional Patch AIR-ANT2568VG-N AIR-ANT2588P3M-N= Dual-band/Dual Polarized Directional, Patch AIR-ANT2513P4M-N Dual-band Polarization Diverse Patch Array Dual-band Omni
>30 degree 5 GHz Antenna Gain
(dBi) NA NA NA NA NA NA
-3
-5
-6 5
-6
-6
-6 3 1
-5 Antenna Gain
(dBi) 5 5 8 5 5 13 8 5 5 13 4 / 7 4 / 7 4 / 7 6 / 8 8 / 8 13 / 13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 9 of 61 Radio Test Report No: EDCS 18429904 Section 3: Result Summary 3.1 Results Summary Table Conducted emissions Basic Standard FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.209 FCC 15.205 Technical Requirements / Details 99% & 26 dB Bandwidth:
The 99% occupied bandwidth is the frequency bandwidth such that, below its lower and above its upper frequency limits, the mean powers are each equal to 0.5% of the total mean power of the given emission. There is no limit for 99% OBW. The 26 dB emission is the width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 26 dB relative to the maximum level measured in the fundamental emission. Output Power:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Power Spectral Density:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bandsthe maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Conducted Spurious Emissions / Band-Edge:
15.407 (3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz. Restricted band:
Unwanted emissions falling within the restricted bands, as defined in FCC 15.205 (a) must also comply with the radiated emission limits specified in FCC 15.209 (a). Result Pass Pass Pass Pass Pass Radiated Emissions (General requirements) Basic Standard FCC 15.209 FCC 15.205 FCC 15.207 Technical Requirements / Details TX Spurious Emissions:
Except as provided elsewhere in this subpart, the emissions from an intentional radiator shall not exceed the field strength levels specified in the filed strength limits table in this section. AC conducted Emissions:
Except when the requirements applicable to a given device state otherwise, for any radio apparatus equipped to operate from the public utility AC power supply, either directly or indirectly (such as with a battery charger), the radio frequency voltage of emissions conducted back onto the AC power lines in the frequency range of 0.15 MHz to 30 MHz shall not exceed the limits shown in the table in these sections. The more stringent limit applies at the frequency range boundaries. Result Pass Pass Page No: 10 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Section 4: Sample Details Note: Each sample was evaluated to ensure that its condition was suitable to be used as a test sample prior to the commencement of testing. 4.1 Sample Details Sample No. S01 S02 Equipment Details Manufacturer Hardware Rev. Firmware Rev. Software Rev. Serial Number IW-6300H-DC-B-K9 FSP150-AWAN3 Cisco Systems, Inc. FSP Group Inc. 11
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9.1.8.1 9.0.5.5-W8964 FOC23241G16
-
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H00000063 4.2 System Details System #
1 EUT and Power Supply 4.3 Mode of Operation Details Mode#
Description Description Samples S01, S02 Comments 1 Continuous Transmitting Continuous Transmitting 98% duty cycle This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 11 of 61 Radio Test Report No: EDCS 18429904 Appendix A: Emission Test Results Conducted Test Setup Diagram Target Maximum Channel Power The following table details the maximum supported Total Channel Power for all operating modes. Operating Mode Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M15 HT/VHT20 Beam Forming, M0 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 HT/VHT40 Beam Forming, M0 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss VHT80 Beam Forming, M0 to M9, M0 to M9 1-2ss VHT80 STBC, M0 to M9 1ss Maximum Channel Power
(dBm) Frequency (MHz) 5500 20 19 21 21 21 5510 19 18 18 18 5530 16 17 17 17 5560 19 19 21 21 21 5550 22 23 23 23 5610 19 23 23 23 5700 19 19 21 21 21 5710 22 24 24 24 5690 20 23 23 23 Page No: 12 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 A.1 Duty Cycle Duty Cycle Test Requirement From KDB 789033 D02 General UNII Test Procedures New Rules v02r01 B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level 1. All measurements are to be performed with the EUT transmitting at 100 percent duty cycle at its maximum power control level; however, if 100 percent duty cycle cannot be achieved, measurements of duty cycle, x, and maximum-power transmission duration, T, are required for each tested mode of operation. Duty Cycle Test Method From KDB 789033 D02 General UNII Test Procedures New Rules v02r01:
B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level The zero-span mode on a spectrum analyzer or EMI receiver, if the response time and spacing between bins on the sweep are sufficient to permit accurate measurements of the on and off times of the transmitted signal. Set the center frequency of the instrument to the center frequency of the transmission. Set RBW EBW if possible; otherwise, set RBW to the largest available value. Set VBW RBW. Set detector = peak or average. The zero-span measurement method shall not be used unless both RBW and VBW are > 50/T, where T is defined in section II.B.1.a), and the number of sweep points across duration T exceeds 100. (For example, if VBW and/or RBW are limited to 3 MHz, then the zero-span method of measuring duty cycle shall not be used if T 16.7 microseconds.) Duty Cycle Test Information Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Date of testing:
11-Nov-19 - 11-Nov-19 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 13 of 61 Radio Test Report No: EDCS 18429904 Duty Cycle Data Table Duty Cycle table and screen captures are shown below for power/psd modes. Frequency Mode Data Rate 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 Duty Cycle correction
(dB) 0.0 0.0 0.0 0.1 0.0 0.2 0.0 0.1 0.0 0.0 0.0 0.2 0.0 0.2 0.0 0.0 0.0 0.1 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 14 of 61 Radio Test Report No: EDCS 18429904 Duty Cycle Plot, 5530, VHT80, M0 to M9, M0 to M9 1-2ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 15 of 61 Radio Test Report No: EDCS 18429904 A.2 99% and 26dB Bandwidth 99% and 26dB Bandwidth Test Requirement There is no requirement for the value of bandwidth. However, the 26dB BW (EBW) is used to calculate the power limits in 15.407 (a) (2). Power measurements are made using the 99% Bandwidth as the integration bandwidth. Band-crossing emissions: For an emission that crosses the boundary between two adjacent U-NII bands, the boundary frequency between the bands serves as one edge for defining the portion of the EBW that falls within a particular U-NII band. However, the -26 dB points are measured relative to the highest point on the contiguous segmentregardless of which band contains that highest point (Figure4). 99% and 26dB Bandwidth Test Procedure Ref. KDB 789033 Section D. 99 Percent Occupied Bandwidth ANSI C63.10: 2013 Section 6.9.3 KDB 662911 99% BW Test Parameters 1. Set center frequency to the nominal EUT channel center frequency. 2. Set span = 1.5 times to 5.0 times the OBW. 3. Set RBW = 1 % to 5 % of the OBW 4. Set VBW 3 RBW 5. Video averaging is not permitted. Where practical, a sample detection and single sweep mode shall be used. Otherwise, peak detection and max hold mode (until the trace stabilizes) shall be used. 6. Use the 99 % power bandwidth function of the instrument (if available). Ref KDB 789033 in Section C. Measurement Bandwidth, Section 1 26 BW Test parameters X dB BW = -26dB (using the OBW function of the spectrum analyzer) Emission Bandwidth (EBW) a) Set RBW = approximately 1% of the emission bandwidth. b) Set the VBW > RBW. c) Detector = Peak. d) Trace mode = max hold. e) Measure the maximum width of the emission that is 26 dB down from the maximum of the emission. Page No: 16 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Compare this with the RBW setting of the analyzer. Readjust RBW and repeat measurement as needed until the RBW/EBW ratio is approximately 1%. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
Start Date to Finish Date here Page No: 17 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 99% and 26dB Bandwidth Table Frequency
(MHz) 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Mode Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Data Rate 26dB BW 99% BW
(Mbps)
(MHz) 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 19.7 20.2 42.0 40.8 83.6 82.3 44.3 40.9 19.7 20.2 82.1 82.2 82.4 82.3 19.9 20.1 41.1 40.9 15.3 15.1
(MHz) 16.616 17.651 36.375 36.192 76.353 76.523 36.496 36.227 16.630 17.650 76.309 76.474 76.439 76.513 16.596 17.639 36.448 36.234 13.362 13.848 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 18 of 61 Radio Test Report No: EDCS 18429904 26dB / 99% Bandwidth, 5720 MHz, Non HT20, 6 to 54 Mbps This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 19 of 61 Radio Test Report No: EDCS 18429904 A.3 Maximum Conducted Output Power Maximum Conducted Output Power Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Maximum Conducted Output Power Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 ANSI C63.10: 2013 Maximum Conducted Output Power Test Procedure 1. Set the radio in the continuous transmitting mode at full power 2. Compute power by integrating the spectrum across the EBW (or alternatively entire 99% OBW) of the signal using the instruments band power measurement function. The integration shall be performed using the spectrum analyzer band-power measurement function with band limits set equal to the EBW or the OBW band edges. Page No: 20 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 3. Capture graphs and record pertinent measurement data. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Measurement using a Spectrum Analyzer or EMI Receiver (SA), (d) Method SA-2 Maximum Conducted Output Power Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 System under Support test equipment Date of testing:
Start Date to Finish Date here Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 21 of 61 Radio Test Report No: EDCS 18429904 Maximum Output Power
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n g r a M i Non HT20, 6 to 54 Mbps 1 5 20.2 0.0 20.2 Non HT20, 6 to 54 Mbps 2 5 16.2 15.7 0.0 19.0 Non HT20 Beam Forming, 6 to 54 Mbps 2 8 16.2 15.7 0.0 19.0 HT/VHT20, M0 to M7 1 5 20.2 0.0 20.2 HT/VHT20, M0 to M7 2 5 16.4 15.8 0.0 19.2 HT/VHT20, M8 to M15 2 5 18.2 17.6 0.0 21.0 HT/VHT20 Beam Forming, M0 to M7 2 8 16.4 15.8 0.0 19.2 HT/VHT20 Beam Forming, M8 to M15 2 5 18.2 17.6 0.0 21.0 HT/VHT20 STBC, M0 to M7 2 5 18.2 17.6 0.0 21.0 Non HT40, 6 to 54 Mbps 1 5 15.7 0.0 15.7 Non HT40, 6 to 54 Mbps 2 5 15.7 15.2 0.0 18.5 HT/VHT40, M0 to M7 1 5 15.8 0.1 15.9 HT/VHT40, M0 to M7 2 5 15.6 15.1 0.1 18.4 HT/VHT40, M8 to M15 2 5 15.6 15.1 0.1 18.4 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 2 2 8 5 14.4 15.6 14.0 15.1 0.1 0.1 17.3 18.4 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. Page No: 22 of 61 0 1 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 3.77 5.00 3.00 3.76 4.84 3.04 2.84 3.04 3.04 8.26 5.49 8.14 5.58 5.58 4.73 5.58 Radio Test Report No: EDCS 18429904 HT/VHT40 STBC, M0 to M7 2 5 15.6 15.1 0.1 18.4 0 24. 0 Non HT80, 6 to 54 Mbps 1 5 14.8 0.0 14.8 Non HT80, 6 to 54 Mbps 2 5 13.6 13.0 0.0 16.4 VHT80, M0 to M9 1ss 1 5 15.2 0.2 15.4 VHT80, M0 to M9 1ss 2 5 14.0 13.4 0.2 16.9 0 3 5 5 VHT80, M0 to M9 2ss 2 5 14.0 13.4 0.2 16.9 VHT80 Beam Forming, M0 to M9 1ss 2 8 13.1 12.5 0.2 16.0 VHT80 Beam Forming, M0 to M9 2ss 2 5 14.0 13.4 0.2 16.9 VHT80 STBC, M0 to M9 1ss 2 5 14.0 13.4 0.2 16.9 Non HT40, 6 to 54 Mbps 1 5 20.0 0.0 20.0 Non HT40, 6 to 54 Mbps 2 5 18.9 18.3 0.0 21.7 HT/VHT40, M0 to M7 1 5 20.0 0.1 20.1 HT/VHT40, M0 to M7 2 5 20.0 19.4 0.1 22.8 0 5 5 5 HT/VHT40, M8 to M15 2 5 20.0 19.4 0.1 22.8 HT/VHT40 Beam Forming, M0 to M7 2 8 17.1 16.6 0.1 19.9 HT/VHT40 Beam Forming, M8 to M15 2 5 20.0 19.4 0.1 22.8 HT/VHT40 STBC, M0 to M7 2 5 20.0 19.4 0.1 22.8 Non HT20, 6 to 54 Mbps 1 5 19.4 0.0 19.4 Non HT20, 6 to 54 Mbps 2 5 16.1 16.3 0.0 19.2 Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 2 1 8 5 16.1 19.6 16.3 0.0 0.0 19.2 19.6 24. 0 24. 0 22. 0 24. Page No: 23 of 61 0 6 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 5.58 9.17 7.65 8.60 7.08 7.08 5.98 7.08 7.08 3.96 2.34 3.94 1.22 1.22 2.08 1.22 1.22 4.57 4.76 2.76 4.36 Radio Test Report No: EDCS 18429904 HT/VHT20, M0 to M7 2 5 16.3 16.4 0.0 19.4 HT/VHT20, M8 to M15 2 5 18.5 18.3 0.0 21.5 HT/VHT20 Beam Forming, M0 to M7 2 8 16.3 16.4 0.0 19.4 HT/VHT20 Beam Forming, M8 to M15 2 5 18.5 18.3 0.0 21.5 HT/VHT20 STBC, M0 to M7 2 5 18.5 18.3 0.0 21.5 Non HT80, 6 to 54 Mbps 1 5 19.3 0.0 19.3 Non HT80, 6 to 54 Mbps 2 5 14.4 13.6 0.0 17.1 VHT80, M0 to M9 1ss 1 5 19.6 0.2 19.8 VHT80, M0 to M9 1ss 2 5 19.6 19.2 0.2 22.6 0 1 6 5 VHT80, M0 to M9 2ss 2 5 19.6 19.2 0.2 22.6 VHT80 Beam Forming, M0 to M9 1ss 2 8 16.1 16.6 0.2 19.6 VHT80 Beam Forming, M0 to M9 2ss 2 5 19.6 19.2 0.2 22.6 VHT80 STBC, M0 to M9 1ss 2 5 19.6 19.2 0.2 22.6 Non HT80, 6 to 54 Mbps 1 5 19.5 0.0 19.5 Non HT80, 6 to 54 Mbps 2 5 15.5 13.9 0.0 17.8 VHT80, M0 to M9 1ss 1 5 21.7 0.2 21.9 VHT80, M0 to M9 1ss 2 5 20.5 20.0 0.2 23.5 0 9 6 5 VHT80, M0 to M9 2ss 2 5 20.5 20.0 0.2 23.5 VHT80 Beam Forming, M0 to M9 1ss 2 8 17.1 16.3 0.2 19.9 VHT80 Beam Forming, M0 to M9 2ss 2 5 20.5 20.0 0.2 23.5 VHT80 STBC, M0 to M9 1ss 2 5 20.5 20.0 0.2 23.5 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 24 of 61 0 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 4.60 2.55 2.60 2.55 2.55 4.67 6.94 4.20 1.39 1.39 2.44 1.39 1.39 4.47 6.18 2.10 0.54 0.54 2.07 0.54 0.54 Radio Test Report No: EDCS 18429904 0 0 7 5 Non HT20, 6 to 54 Mbps 1 5 18.0 0.0 18.0 Non HT20, 6 to 54 Mbps 2 5 15.3 16.4 0.0 18.9 Non HT20 Beam Forming, 6 to 54 Mbps 2 8 15.3 16.4 0.0 18.9 HT/VHT20, M0 to M7 1 5 19.2 0.0 19.2 HT/VHT20, M0 to M7 2 5 15.4 16.6 0.0 19.1 HT/VHT20, M8 to M15 2 5 17.2 18.4 0.0 20.9 HT/VHT20 Beam Forming, M0 to M7 2 8 15.4 16.6 0.0 19.1 HT/VHT20 Beam Forming, M8 to M15 2 5 17.2 18.4 0.0 20.9 HT/VHT20 STBC, M0 to M7 2 5 17.2 18.4 0.0 20.9 Non HT40, 6 to 54 Mbps 1 5 19.7 0.0 19.7 Non HT40, 6 to 54 Mbps 2 5 18.7 19.4 0.0 22.1 HT/VHT40, M0 to M7 1 5 21.5 0.1 21.6 HT/VHT40, M0 to M7 2 5 18.6 19.2 0.1 22.0 0 1 7 5 HT/VHT40, M8 to M15 2 5 20.5 20.9 0.1 23.8 HT/VHT40 Beam Forming, M0 to M7 2 8 17.3 17.9 0.1 20.7 HT/VHT40 Beam Forming, M8 to M15 2 5 20.5 20.9 0.1 23.8 HT/VHT40 STBC, M0 to M7 57 20 Non HT20, 6 to 54 Mbps 2 5 20.5 20.9 0.1 23.8 1 5 19.5 0.0 19.5 Non HT20, 6 to 54 Mbps 2 5 13.6 14.8 0.0 17.3 Non HT20 Beam Forming, 6 to 54 Mbps 2 8 13.6 14.8 0.0 17.3 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 1 2 5 5 20.6 14.7 16.0 0.0 0.0 20.6 18.5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 25 of 61 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 0 24. 0 24. 0 22. 0 24. 0 24. 5.97 5.07 3.07 4.76 4.91 3.11 2.91 3.11 3.11 4.26 1.88 2.44 2.02 0.23 1.32 0.23 0.23 4.47 6.72 4.72 3.36 5.55 Radio Test Report No: EDCS 18429904 HT/VHT20, M8 to M15 2 5 16.7 17.8 0.0 20.3 HT/VHT20 Beam Forming, M0 to M7 2 8 14.7 16.0 0.0 18.5 HT/VHT20 Beam Forming, M8 to M15 2 5 16.7 17.8 0.0 20.3 HT/VHT20 STBC, M0 to M7 2 5 16.7 17.8 0.0 20.3 0 24. 0 22. 0 24. 0 24. 0 3.66 3.55 3.66 3.66 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 26 of 61 Radio Test Report No: EDCS 18429904 Maximum Transmit Output Power, 5710 MHz, HT/VHT40, M8 to M15 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 27 of 61 Radio Test Report No: EDCS 18429904 A.4 Power Spectral Density Power Spectral Density Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Power Spectral Density Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test Procedure The rules requires maximum power spectral density measurements where the intent is to measure the maximum value of the time average of the power spectral density measured during a period of continuous transmission. 1. Create an average power spectrum for the EUT operating mode being tested by following the instructions in section II.E.2. for measuring maximum conducted output power using a spectrum analyzer or EMI receiver: select the Page No: 28 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 appropriate test method (SA-1, SA-2, SA-3, or alternatives to each) and apply it up to, but not including, the step labeled, Compute power. (This procedure is required even if the maximum conducted output power measurement was performed using a power meter, method PM.) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. b) If Method SA-3 Alternative was used and the linear mode was used in step II.E.2.g)(viii), add 1 dB to the final result to compensate for the difference between linear averaging and power averaging. 4. The result is the Maximum PSD over 1 MHz reference bandwidth. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) F. Maximum Power Spectral Density (PSD) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 29 of 61 Radio Test Report No: EDCS 18429904 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment Date of testing:
Start Date to Finish Date here Page No: 30 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Power Spectral Density
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-0.8 11.0 13.17 9.0 9.59 11.0 13.00 9.0 9.78 11.0 11.78 9.0 11.0 11.0 10.57 11.78 11.78 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 5 8 5 8 5 8 5 5 5 8 8 5 8 5 8 5 5 5 8 5 8 5 8 5 5 5 8 5 8 5 8 5 5 5 8 8 5 8 5 6.6 5.4 5.8 5.8 5.8 3.1 5.8 5.8 5.0 5.7 5.7 2.9 5.7 5.7 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 6.6 8.3 5.9 8.8 8.8 6.1 8.8 8.8 11.0 9.0 11.0 9.0 11.0 9.0 11.0 11.0 8.7 5.3 5.3 8.9 5.6 7.8 5.6 7.8 7.8 6.0 6.0 5.4 7.5 5.4 7.5 7.5 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 8.7 8.7 8.7 8.9 8.6 11.0 9.0 9.0 11.0 9.0 10.7 11.0 8.6 10.7 10.7 9.0 11.0 11.0 11.0 9.0 11.0 9.0 11.0 9.0 11.0 11.0 11.0 9.0 11.0 9.0 11.0 9.0 11.0 11.0 11.0 9.0 9.0 11.0 9.0 2.2
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-0.9 3.0 3.0 2.7 2.7 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2 2.7 1.1 4.3 6.1 6.1 2.7 6.1 6.1 7.7 4.6 4.6 8.1 4.6 6.3 5.8 5.8 5.6 7.5 0.0 0.0 0.0 0.0 0.0 0.0 7.7 8.3 8.3 8.1 8.2 10.0 11.0 4.36 0.74 5.14 0.18 2.18 2.93 2.18 2.18 2.27 0.29 0.29 2.06 0.45 0.29 0.45 0.29 0.29 8.77 8.73 8.50 3.78 5.78 6.93 5.78 5.78 8.27 7.92 6.70 2.94 4.94 6.33 4.94 4.94 3.27 0.72 0.72 2.86 0.82 1.01 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 32 of 61 Radio Test Report No: EDCS 18429904 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 8 5 5 5 8 5 8 5 8 5 5 5 8 8 5 8 5 8 5 5 4.6 6.3 6.3 5.6 7.5 7.5 0.0 0.0 0.0 8.2 10.0 10.0 9.0 11.0 11.0 11.0 9.0 11.0 9.0 9.0 11.0 11.0 11.0 9.0 9.0 6.1 8.6 7.8 8.2 6.8 10.0 10.0 9.9 7.7 7.7 10.0 11.0 10.7 11.0 8.8 9.0 10.5 11.0 8.8 10.5 10.5 9.0 11.0 11.0 0.82 1.01 1.01 4.86 0.38 3.24 0.82 0.97 2.23 0.97 0.97 1.07 1.34 1.34 0.26 0.19 0.51 0.19 0.51 0.51 6.1 5.2 7.7 4.8 6.6 3.5 6.6 6.6 5.9 5.4 7.3 3.9 7.3 7.3 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 9.9 3.8 3.8 10.7 5.0 6.8 5.0 6.8 6.8 5.3 5.3 6.4 8.0 6.4 8.0 8.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 33 of 61 Radio Test Report No: EDCS 18429904 Power Spectral Density, 5550 MHz, HT/VHT40, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 34 of 61 Radio Test Report No: EDCS 18429904 A.5 Conducted Spurious Emissions Conducted Spurious Emissions Test Requirement 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Spurious Emissions Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 35 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Add the max antenna gain + ground reflection factor (4.7 dB for frequencies between 30 MHz and 1000 MHz, and 0 dB for frequencies > 1000 MHz). Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
11-Nov-19 - 11-Nov-19 Page No: 36 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Conducted Spurs Average Upper Conducted Spurs Peak Upper This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 37 of 61 Radio Test Report No: EDCS 18429904 Conducted Spurious Average Table
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r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
-50.5
-51.7
-53.3
-51.7
-53.3
-50.7
-51.8
-53.3
-51.4
-52.3
-51.8
-53.3
-51.4
-52.3
-51.4
-52.3
) B d
(
n o i t c e r r o C e l c y C y t u D 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
(
r u p S d e t c u d n o C l a t o T
) m B d
(
t i m L i
) B d
(
n g r a M i
-45.5
-41.25 4.22
-44.4
-41.25 3.13
-41.4
-41.25 0.13
-45.7
-41.25 4.41
-44.4
-41.25 3.18
-43.8
-41.25 2.52
-41.4
-41.25 0.18
-43.8
-41.25 2.52
-43.8
-41.25 2.52
-50.0
-50.0
-52.0
-51.5
-53.3
-55.8
-53.3
-55.8
-53.7
-56.0
-53.3
-55.8
-53.3
-55.8 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-45.0
-41.25 3.71
-42.8
-41.25 1.58
-46.4
-41.25 5.19
-46.3
-41.25 5.05
-46.3
-41.25 5.05
-43.6
-41.25 2.38
-46.3
-41.25 5.05
-46.3
-41.25 5.05
-51.6
-49.9
-52.4
-53.5
-54.0
-56.1
-54.0
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-56.6
-54.0
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-56.1 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-46.6
-41.25 5.32
-42.9
-41.25 1.68
-48.3
-41.25 7.05
-46.7
-41.25 5.47
-46.7
-41.25 5.47
-43.8
-41.25 2.52
-46.7
-41.25 5.47
-46.7
-41.25 5.47 B d
(
i n a G a n n e t n A d e t a l e r r o C 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
) z H M
(
y c n e u q e r F 0 0 5 5 Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Page No: 38 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 0 5 5 5 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 5 5 5 5 5 8 5 5 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 8 5 5 5
-46.3
-50.6
-52.6
-50.3
-50.3
-52.2
-50.3
-52.2
-52.5
-55.0
-50.3
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-52.2 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-41.3
-41.25 0.01
-43.4
-41.25 2.18
-45.2
-41.25 3.99
-43.1
-41.25 1.83
-43.1
-41.25 1.83
-42.5
-41.25 1.25
-43.1
-41.25 1.83
-43.1
-41.25 1.83
-50.7
-51.4
-53.5
-51.4
-53.5
-50.6
-51.5
-53.6
-50.7
-52.8
-51.5
-53.6
-50.7
-52.8
-50.7
-52.8 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-45.7
-41.25 4.42
-44.3
-41.25 3.03
-41.3
-41.25 0.03
-45.6
-41.25 4.31
-44.4
-41.25 3.12
-43.6
-41.25 2.32
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-41.25 0.12
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-41.5
-41.25 0.22
-45.0
-41.25 3.75
-45.3
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-41.25 1.62
-42.5
-41.25 1.26
-43.3
-41.25 2.05
-41.9
-41.25 0.65
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-41.25 0.65
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-41.25 1.49
-41.9
-41.25 0.65
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-41.25 0.65
-50.4
-53.8
-54.9
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-41.25 4.12
-46.3
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-41.25 2.07 Page No: 39 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 8 5 5 5 5 5 5 5 8 5 5 5 5 8 5 5 5 8 5 5
-53.6
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-41.25 1.83 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 40 of 61 Radio Test Report No: EDCS 18429904 Conducted Spurs Average, 5550 MHz, Non HT40, 6 to 54 Mbps Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 41 of 61 Radio Test Report No: EDCS 18429904 Conducted Spurious Emissions Peak Table
) i
) z H M
(
y c n e u q e r F Mode s h t a P x T Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps 1 2 Non HT20 Beam Forming, 6 to 54 Mbps 2 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss B d
(
i n a G a n n e t n A d e t a l e r r o C 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5
) m B d
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r e w o P r u p S 1 x T
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) m B d
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r e w o P r u p S 3 x T 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
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r u p S d e t c u d n o C l a t o T
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t i m L i
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n g r a M i
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-38.4
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-21.25 17.19 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 42 of 61 Radio Test Report No: EDCS 18429904 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 5 5 5 5 5 8 5 5 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 8 5 5 5
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-21.25 15.62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 43 of 61 Radio Test Report No: EDCS 18429904 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 8 5 5 5 5 5 5 5 8 5 5 5 5 8 5 5 5 8 5 5
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-21.25 16.24 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 44 of 61 Radio Test Report No: EDCS 18429904 Conducted Spurs Peak, 5500 MHz, Non HT20 Beam Forming, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 45 of 61 Radio Test Report No: EDCS 18429904 A.6 Conducted Bandedge 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Band Edge Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI Page No: 46 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 C63.10:2013 section 14.3.2.2) 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging System under Support test equipment Date of testing:
11-Nov-19 - 11-Nov-19 Page No: 47 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Conducted Bandedge Average Table
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(
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n a G a n n e t n A d e t a Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss l e r r o C 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
) m B d
(
l
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(
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n o i t c e r r o C e l c y C y t u D
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l e v e L e g d e d n a B x T l a t o T
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-51.1
-55.3
-55.4
-55.3
-55.4
-50.9
-54.7
-55.0
-53.9
-54.0
-54.7
-55.0
-53.9
-54.0
-53.9
-54.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-46.1
-41.25 4.82
-47.3
-41.25 6.06
-44.3
-41.25 3.06
-45.9
-41.25 4.61
-46.8
-41.25 5.54
-45.9
-41.25 4.65
-43.8
-41.25 2.54
-45.9
-41.25 4.65
-45.9
-41.25 4.65
-49.7
-49.7
-51.4
-47.9
-51.2
-51.8
-51.2
-51.8
-52.9
-53.3
-51.2
-51.8
-51.2
-51.8 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-44.7
-41.25 3.41
-42.4
-41.25 1.17
-42.8
-41.25 1.59
-43.4
-41.25 2.17
-43.4
-41.25 2.17
-42.0
-41.25 0.78
-43.4
-41.25 2.17
-43.4
-41.25 2.17
-47.6
-50.7
-50.0
-49.1
-51.7
-51.5
-51.7
-51.5
-52.4
-52.8
-51.7
-51.5
-51.7
-51.5 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-42.6
-41.25 1.32
-42.3
-41.25 1.04
-43.9
-41.25 2.65
-43.4
-41.25 2.14
-43.4
-41.25 2.14
-41.4
-41.25 0.14
-43.4
-41.25 2.14
-43.4
-41.25 2.14 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 48 of 61 Radio Test Report No: EDCS 18429904 Conducted Bandedge Average, 5530 MHz, VHT80 Beam Forming, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 49 of 61 Radio Test Report No: EDCS 18429904 Conducted Bandedge Peak Table
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n g r a M i
-32.7
-27.7
-21.25 6.42
-36.5
-36.6
-28.5
-21.25 7.26
-36.5
-36.6
-25.5
-21.25 4.26
-34.3
-29.3
-21.25 8.01
-41.4
-43.5
-34.3
-21.25 13.02
-40.5
-42.4
-33.3
-21.25 12.04
-41.4
-43.5
-31.3
-21.25 10.02
-40.5
-42.4
-33.3
-21.25 12.04
-40.5
-42.4
-33.3
-21.25 12.04
-34.7
-29.7
-21.25 8.41
-34.7
-29.2
-23.1
-21.25 1.83
-33.8
-28.7
-21.25 7.49
-31.6
-36.0
-25.2
-21.25 3.95
-31.6
-36.0
-25.2
-21.25 3.95
-34.7
-33.0
-22.7
-21.25 1.45
-31.6
-36.0
-25.2
-21.25 3.95
-31.6
-36.0
-25.2
-21.25 3.95
-33.9
-28.9
-21.25 7.62
-40.2
-41.0
-32.5
-21.25 11.29
-38.2
-33.0
-21.25 11.75
-38.0
-38.7
-30.1
-21.25 8.88
-38.0
-38.7
-30.1
-21.25 8.88
-41.5
-40.3
-29.7
-21.25 8.40
-38.0
-38.7
-30.1
-21.25 8.88
-38.0
-38.7
-30.1
-21.25 8.88 i B d
(
n a G a n n e t n A d e t a l e r r o C 5 5 8 5 5 5 8 5 5 5 5 5 5 5 8 5 5 5 5 5 5 5 8 5 5 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 Page No: 50 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 5 5 8 5 5 5 8 5 5 1 2 2 1 2 2 2 2 2
-33.4
-28.4
-21.25 7.12
-43.1
-37.0
-31.0
-21.25 9.76
-43.1
-37.0
-28.0
-21.25 6.76
-27.2
-22.2
-21.25 0.91
-37.5
-35.5
-28.3
-21.25 7.08
-36.3
-27.4
-21.8
-21.25 0.58
-37.5
-35.5
-25.3
-21.25 4.08
-36.3
-27.4
-21.8
-21.25 0.58
-36.3
-27.4
-21.8
-21.25 0.58 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 51 of 61 Radio Test Report No: EDCS 18429904 Conducted Bandedge Peak, 5510 MHz, HT/VHT40 Beam Forming, M0 to M7 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 52 of 61 Radio Test Report No: EDCS 18429904 Conducted Bandedge Peak, 5700 MHz, HT/VHT20, M8 to M15 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 53 of 61 Radio Test Report No: EDCS 18429904 Appendix B: List of Test Equipment Used to perform the test Equip#
Manufacturer/ Model Description Last Cal Next Due 7329 OMEGA/CT485B Chart Recorder 18 Feb. 2019 18 Feb. 2020 RF Conducted at output antenna port 49516 Keysight (Agilent/HP) / N9030A PXA Signal Analyzer, 3Hz to 50GHz 29 Nov. 2019 29 Nov. 2019 55097 Nattional Instruments / PXI-1042 Chassis PXI Cal Not Required Cal Not Required 56089 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 56328 Pasternack / PE5019-1 Torque Wrench 13 Feb. 2019 13 Feb. 2020 57233 Nattional Instruments / PXI-8115 Embedded Controller Cal Not Required Cal Not Required 57253 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 57254 National Instruments / PXI-2799 Switch 1x1 Verify Before Use Verify Before Use 57479 CISCO / ATIL Automation Test Insertion Loss System Verify Before Use Verify Before Use This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 54 of 61 Radio Test Report No: EDCS 18429904 Appendix C: Abbreviation Key and Definitions The following table defines abbreviations used within this test report. Abbreviation Description Abbreviation Description F C Temp Electro Magnetic Compatibility Electro Magnetic Interference Equipment Under Test Information Technology Equipment S/N Qty Test Assessment Schedule emf Electro Static Discharge Electric Fast Transient RMS Qp Engineering Document Control System Configuration Cisco Number (unique identification number for Cisco test equipment) Calibration Av Pk kHz MHz GHz H V dB V kV V A A mS S European Norm International Electro technical Commission International Special Committee on Radio Interference Coupling/Decoupling Network Line Impedance Stabilization Network Protective Earth Ground Line 1 Line2 Line 3 Direct Current Uncorrected measurement value, as indicated by the measuring device Radio Frequency Signal Line Conducted Emissions Measurement distance Not Applicable Power Line Neutral Line Supply EMC EMI EUT ITE TAP ESD EFT EDCS Config CIS#
Cal EN IEC CISPR CDN LISN PE GND L1 L2 L3 DC RAW RF SLCE Meas dist N/A or NA P N S Degrees Fahrenheit Degrees Celsius Temperature Serial Number Quantity Electromotive force Root mean square Quasi Peak Average Peak Kilohertz (1x103) MegaHertz (1x106) Gigahertz (1x109) Horizontal Vertical decibel Volt Kilovolt (1x103) Microvolt (1x10-6) Amp Micro Amp (1x10-6) Milli Second (1x10-3) Micro Second (1x10-6) S m Spec dist SL L R AC Micro Second (1x10-6) Meter Specification distance Signal Line (or Telecom Line) Live Line Return Alternating Current This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 55 of 61 Radio Test Report No: EDCS 18429904 Appendix D: Photographs of Test Setups Title: EUT Pictures Page No: 56 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 57 of 61 Radio Test Report No: EDCS 18429904 Title: Radio Conducted Test Setup Page No: 58 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Appendix E: Software Used to Perform Testing EMIsoft Vasona, version 6.024 Page No: 59 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Appendix F: Test Procedures Measurements were made in accordance with KDB 789033 - D02 General UNII Test Procedures New Rules v02r01 KDB 662911 - MIMO ANSI C63.4 2014 Unintentional Radiators ANSI C63.10 2013 Intentional Radiators Test procedures are summarized below:
FCC 5GHz Test Procedures FCC 5GHz RSE Test Procedures EDCS # 1445048 EDCS # 1511600 Page No: 60 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429904 Appendix G: Scope of Accreditation (A2LA certificate number 1178-01) The scope of accreditation of Cisco Systems, Inc. can be found on the A2LA web page at:
http://www.a2la.org/scopepdf/1178-01.pdf End This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 61 of 61
1 2 3 4 5 6 | UNI IIC INT 7B | External Photos | 2.93 MiB | September 12 2019 |
Radio Test Report No: EDCS 18429906 Test Report IW-6300H Series Access Point Cisco Industrial Wireless Hazardous Location Access Point FCC ID: LDKESW6300 IC ID: 2461D-ESW6300 5470-5725 MHz Inside Antennas, 7dBi Gain Against the following Specifications:
CFR47 Part 15.407 Cisco Systems 170 West Tasman Drive San Jose, CA 95134 Approved By: Adam Walb Title: MGR. IoT Compliance Revision: 1.0 Author: Julian Land Tested By: Julian Land This report replaces any previously entered test report under EDCS 18429906.This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. Test Report Template EDCS# 11644124. Page No: 1 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. SECTION 1: OVERVIEW ......................................................................................................................................... 3 SECTION2: ASSESSMENT INFORMATION ........................................................................................................ 4 2.1 GENERAL ............................................................................................................................................................. 4 2.2 DATE OF TESTING................................................................................................................................................. 6 2.3 REPORT ISSUE DATE ............................................................................................................................................ 6 2.4 TESTING FACILITIES ............................................................................................................................................. 6 2.5 EQUIPMENT ASSESSED (EUT) .............................................................................................................................. 6 2.6 EUT DESCRIPTION ............................................................................................................................................... 7 SECTION 3: RESULT SUMMARY ........................................................................................................................ 10 3.1 RESULTS SUMMARY TABLE ............................................................................................................................... 10 SECTION 4: SAMPLE DETAILS ........................................................................................................................... 11 4.1 SAMPLE DETAILS ............................................................................................................................................... 11 4.2 SYSTEM DETAILS ............................................................................................................................................... 11 4.3 MODE OF OPERATION DETAILS .......................................................................................................................... 11 APPENDIX A: EMISSION TEST RESULTS ........................................................................................................ 12 CONDUCTED TEST SETUP DIAGRAM ........................................................................................................................ 12 TARGET MAXIMUM CHANNEL POWER .................................................................................................................... 12 A.1 DUTY CYCLE .................................................................................................................................................... 14 A.2 99% AND 26DB BANDWIDTH ............................................................................................................................ 17 A.3 MAXIMUM CONDUCTED OUTPUT POWER ......................................................................................................... 21 A.4 POWER SPECTRAL DENSITY .............................................................................................................................. 29 A.5 CONDUCTED SPURIOUS EMISSIONS ................................................................................................................... 36 A.6 CONDUCTED BANDEDGE ................................................................................................................................... 47 APPENDIX B:
NOT DEFINED. LIST OF TEST EQUIPMENT USED TO PERFORM THE TEST . ERROR! BOOKMARK APPENDIX C: ABBREVIATION KEY AND DEFINITIONS ............................................................................. 55 APPENDIX D:
PHOTOGRAPHS OF TEST SETUPS ................................................................................... 57 APPENDIX E:
SOFTWARE USED TO PERFORM TESTING ................................................................... 60 APPENDIX F:
TEST PROCEDURES ............................................................................................................. 61 APPENDIX G: SCOPE OF ACCREDITATION (A2LA CERTIFICATE NUMBER 1178-01) ........................ 62 Page No: 2 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Section 1: Overview The samples were assessed against the tests detailed in section 3 under the requirements of the following specifications:
Specifications:
CFR47 Part 15.407 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 3 of 62 b) c) d) e) Radio Test Report No: EDCS 18429906 Section2: Assessment Information 2.1 General This report contains an assessment of an apparatus against Electromagnetic Compatibility Standards based upon tests carried out on the samples submitted. The testing was performed by and for the use of Cisco systems Inc:
With regard to this assessment, the following points should be noted:
a) The results contained in this report relate only to the items tested and were obtained in the period between the date of the initial assessment and the date of issue of the report. Manufactured products will not necessarily give identical results due to production and measurement tolerances. The apparatus was set up and exercised using the configuration and modes of operation defined in this report only. Where relevant, the apparatus was only assessed using the susceptibility criteria defined in this report and the Test Assessment Plan (TAP). All testing was performed under the following environmental conditions:
Temperature 15C to 35C (54F to 95F) Atmospheric Pressure 860mbar to 1060mbar (25.4" to 31.3") Humidity 10% to 75*%
All AC testing was performed at one or more of the following supply voltages:
110V 60 Hz (+/-20%) Units of Measurement The units of measurements defined in the appendices are reported in specific terms, which are test dependent. Where radiated measurements are concerned these are defined at a particular distance. Basic voltage measurements are defined in units of [dBuV]
As an example, the basic calculation for all measurements is as follows:
The combinations of correction factors are dependent upon the exact test configurations [see test equipment lists for further details] and may include:-
Emission level [dBuV] = Indicated voltage level [dBuV] + Cable Loss [dB] + Other correction factors [dB]
Antenna Factors, Pre Amplifier Gain, LISN Loss, Pulse Limiter Loss and Filter Insertion Loss Note: to convert the results from dBuV/m to uV/m use the following formula:-
Level in uV/m = Common Antilogarithm [(X dBuV/m)/20] = Y uV/m This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 4 of 62 Radio Test Report No: EDCS 18429906 Measurement Uncertainty Values voltage and power measurements 2 dB conducted EIRP measurements 1.4 dB radiated measurements 3.2 dB frequency measurements 2.4 10-7 temperature measurements humidity measurements 0.54 2.3%
DC and low frequency measurements 2.5%
Where relevant measurement uncertainty levels have been estimated for tests performed on the apparatus. This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2. Radiated emissions (expanded uncertainty, confidence interval 95%) 30 MHz - 300 MHz 300 MHz - 1000 MHz 1 GHz - 10 GHz 10 GHz - 18GHz 18GHz - 26.5GHz 26.5GHz - 40GHz
+/- 3.8 dB
+/- 4.3 dB
+/- 4.0 dB
+/- 8.2 dB
+/- 4.1 dB
+/- 3.9 dB Conducted emissions (expanded uncertainty, confidence interval 95%) A product is considered to comply with a requirement if the nominal measured value is below the limit line. The product is considered to not be in compliance in case the nominal measured value is above the limit line. 30 MHz 40GHz
+/- 0.38 dB This report must not be reproduced except in full, without written approval of Cisco Systems. Page No: 5 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 2.2 Date of testing 11-Nov-19 - 11-Nov-19 2.3 Report Issue Date 11/11/2019 Cisco uses an electronic system to issue, store and control the revision of test reports. This system is called the Engineering Document Control System (EDCS). The actual report issue date is embedded into the original file on EDCS. Any copies of this report, either electronic or paper, that are not on EDCS must be considered uncontrolled. 2.4 Testing facilities This assessment was performed by:
Testing Laboratory Cisco Systems, Inc. 125 West Tasman Drive (Building P) San Jose, CA 95134 USA Headquarters Cisco Systems, Inc., 170 West Tasman Drive San Jose, CA 95134, USA Registration Numbers for Industry Canada Cisco System Site Address Building P, 10m Chamber Building P, 5m Chamber Building I, 5m Chamber 125 West Tasman Dr San Jose, CA 95134 125 West Tasman Dr San Jose, CA 95134 285 W. Tasman Drive San Jose, California 95134 Site Identifier Company #: 2461N-2 Company #: 2461N-1 Company #: 2461M-1 Building 7, 5m Chamber 425 E. Tasman Drive Company #: 2461N-3 San Jose, California 95134 Test Engineers Julian Land 2.5 Equipment Assessed (EUT) IW 6300H Page No: 6 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 2.6 EUT Description The radio supports the following modes of operation. The modes are further defined in the radio Theory of Operation. The modes included in this report represent the worst case data for all modes. 802.11a - Non HT20, Two Antennas, 6 to 54 Mbps, 1ss 802.11a - Non HT20 Beam Forming, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT20, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT40, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT40, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT40, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT80, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT80, Two Antennas, 6 to 54 Mbps, 1ss 802.11ac - VHT80, One Antenna, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 1ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 STBC, Two Antennas, M0 to M9 2ss 802.11a - Non HT20, One Antenna, 6 to 54 Mbps, 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 7 of 62 Radio Test Report No: EDCS 18429906 Model / PID Differences IW-6300H-AC-x-K9, IW-6300H-DC-x-K9, IW-6300-DCW-x-K9 and ESW-6300-CON-x-K9, all have the same identical components, electronics circuitries, PCB layout and enclosure. The only differences are listed as below:
IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300-DCW-x-K9 ESW-6300-CON-x-K9 Where x can be replaced with another letter to indicate country domain. Domain letters: A, B, C, D, E, F, H, I, L, M, N, Q, R, S, T, Z Where AC is Alternating Current (AC power supply) Where DC is Direct Current (DC power supply), 54V native input Where DCW is Direct Current; wide range 10-36VDC Where K9 is encryption software. Page No: 8 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 The following antennas are supported by this product series. The data included in this report represent the worst case data for all antennas. Frequency Part Number AIR-ANT2450V-N Antenna Type Single Band Omni AIR-ANT2450V-N-HZ Single Band Omni, Hazloc 2.4 GHz AIR-ANT2480V-N AIR-ANT2450HG-N AIR-ANT2450VG-N AIR-ANT2413P2M-N Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni Single Band, Dual Polarized Directional Patch 5 GHz 2.4/5 GHz Single Band Omni Horizontal Polarized Omni AIR-ANT5180V-N AIR-ANT5150HG-N AIR-ANT5150VG-N AIR-ANT5114P2M-N AIR-ANT2547V-N=
AIR-ANT2547VG-N= Dual-band Omni, Gray AIR-ANT2547V-N-HZ= Dual-band Omni, Hazloc Vertical Polarized Omni Dual-band Omni Single Band, Dual Polarized Directional Patch AIR-ANT2568VG-N AIR-ANT2588P3M-N= Dual-band/Dual Polarized Directional, Patch AIR-ANT2513P4M-N Dual-band Polarization Diverse Patch Array Dual-band Omni
>30 degree 5 GHz Antenna Gain
(dBi) NA NA NA NA NA NA
-3
-5
-6 5
-6
-6
-6 3 1
-5 Antenna Gain
(dBi) 5 5 8 5 5 13 8 5 5 13 4 / 7 4 / 7 4 / 7 6 / 8 8 / 8 13 / 13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 9 of 62 Radio Test Report No: EDCS 18429906 Section 3: Result Summary 3.1 Results Summary Table Conducted emissions Basic Standard FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.209 FCC 15.205 Technical Requirements / Details 99% & 26 dB Bandwidth:
The 99% occupied bandwidth is the frequency bandwidth such that, below its lower and above its upper frequency limits, the mean powers are each equal to 0.5% of the total mean power of the given emission. There is no limit for 99% OBW. The 26 dB emission is the width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 26 dB relative to the maximum level measured in the fundamental emission. Output Power:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Power Spectral Density:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bandsthe maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Conducted Spurious Emissions / Band-Edge:
15.407 (3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz. Restricted band:
Unwanted emissions falling within the restricted bands, as defined in FCC 15.205 (a) must also comply with the radiated emission limits specified in FCC 15.209 (a). Result Pass Pass Pass Pass Pass Radiated Emissions (General requirements) Basic Standard FCC 15.209 FCC 15.205 FCC 15.207 Technical Requirements / Details TX Spurious Emissions:
Except as provided elsewhere in this subpart, the emissions from an intentional radiator shall not exceed the field strength levels specified in the filed strength limits table in this section. AC conducted Emissions:
Except when the requirements applicable to a given device state otherwise, for any radio apparatus equipped to operate from the public utility AC power supply, either directly or indirectly (such as with a battery charger), the radio frequency voltage of emissions conducted back onto the AC power lines in the frequency range of 0.15 MHz to 30 MHz shall not exceed the limits shown in the table in these sections. The more stringent limit applies at the frequency range boundaries. Result Pass Pass Page No: 10 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Section 4: Sample Details Note: Each sample was evaluated to ensure that its condition was suitable to be used as a test sample prior to the commencement of testing. 4.1 Sample Details Sample No. S01 S02 Equipment Details Manufacturer Hardware Rev. Firmware Rev. Software Rev. Serial Number IW-6300H-DC-B-K9 FSP150-AWAN3 Cisco Systems, Inc. FSP Group Inc. 11
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9.1.8.1 9.0.5.5-W8964 FOC23241G16
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H00000063 4.2 System Details System #
1 EUT and Power Supply 4.3 Mode of Operation Details Mode#
Description Description Samples S01, S02 Comments 1 Continuous Transmitting Continuous Transmitting 98% duty cycle This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 11 of 62 Radio Test Report No: EDCS 18429906 Appendix A: Emission Test Results Conducted Test Setup Diagram Target Maximum Channel Power The following table details the maximum supported Total Channel Power for all operating modes. Operating Mode Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M15 HT/VHT20 Beam Forming, M0 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 HT/VHT40 Beam Forming, M0 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss VHT80 Beam Forming, M0 to M9, M0 to M9 1-2ss Maximum Channel Power
(dBm) Frequency (MHz) 5500 20 17 20 20 20 5510 18 18 18 18 5530 15 17 17 5560 19 17 20 20 20 5550 20 22 22 22 5610 17 21 21 5700 18 17 21 21 21 5710 20 22 21 21 5690 18 22 21 Page No: 12 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 VHT80 STBC, M0 to M9 1ss 17 21 21 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 13 of 62 Radio Test Report No: EDCS 18429906 A.1 Duty Cycle Duty Cycle Test Requirement From KDB 789033 D02 General UNII Test Procedures New Rules v02r01 B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level 1. All measurements are to be performed with the EUT transmitting at 100 percent duty cycle at its maximum power control level; however, if 100 percent duty cycle cannot be achieved, measurements of duty cycle, x, and maximum-power transmission duration, T, are required for each tested mode of operation. Duty Cycle Test Method From KDB 789033 D02 General UNII Test Procedures New Rules v02r01:
B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level The zero-span mode on a spectrum analyzer or EMI receiver, if the response time and spacing between bins on the sweep are sufficient to permit accurate measurements of the on and off times of the transmitted signal. Set the center frequency of the instrument to the center frequency of the transmission. Set RBW EBW if possible; otherwise, set RBW to the largest available value. Set VBW RBW. Set detector = peak or average. The zero-span measurement method shall not be used unless both RBW and VBW are > 50/T, where T is defined in section II.B.1.a), and the number of sweep points across duration T exceeds 100. (For example, if VBW and/or RBW are limited to 3 MHz, then the zero-span method of measuring duty cycle shall not be used if T 16.7 microseconds.) Duty Cycle Test Information Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Date of testing:
11-Nov-19 - 11-Nov-19 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 14 of 62 Radio Test Report No: EDCS 18429906 Duty Cycle Data Table Duty Cycle table and screen captures are shown below for power/psd modes. Frequency Mode Data Rate 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 Duty Cycle correction
(dB) 0.0 0.0 0.0 0.1 0.0 0.2 0.0 0.1 0.0 0.0 0.0 0.2 0.0 0.2 0.0 0.0 0.0 0.1 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 15 of 62 Radio Test Report No: EDCS 18429906 Duty Cycle Plot, 5530, VHT80, M0 to M9, M0 to M9 1-2ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 16 of 62 Radio Test Report No: EDCS 18429906 A.2 99% and 26dB Bandwidth 99% and 26dB Bandwidth Test Requirement There is no requirement for the value of bandwidth. However, the 26dB BW (EBW) is used to calculate the power limits in 15.407 (a) (2). Power measurements are made using the 99% Bandwidth as the integration bandwidth. Band-crossing emissions: For an emission that crosses the boundary between two adjacent U-NII bands, the boundary frequency between the bands serves as one edge for defining the portion of the EBW that falls within a particular U-NII band. However, the -26 dB points are measured relative to the highest point on the contiguous segmentregardless of which band contains that highest point (Figure4). 99% and 26dB Bandwidth Test Procedure Ref. KDB 789033 Section D. 99 Percent Occupied Bandwidth ANSI C63.10: 2013 Section 6.9.3 KDB 662911 99% BW Test Parameters 1. Set center frequency to the nominal EUT channel center frequency. 2. Set span = 1.5 times to 5.0 times the OBW. 3. Set RBW = 1 % to 5 % of the OBW 4. Set VBW 3 RBW 5. Video averaging is not permitted. Where practical, a sample detection and single sweep mode shall be used. Otherwise, peak detection and max hold mode (until the trace stabilizes) shall be used. 6. Use the 99 % power bandwidth function of the instrument (if available). Ref KDB 789033 in Section C. Measurement Bandwidth, Section 1 26 BW Test parameters X dB BW = -26dB (using the OBW function of the spectrum analyzer) Emission Bandwidth (EBW) a) Set RBW = approximately 1% of the emission bandwidth. b) Set the VBW > RBW. c) Detector = Peak. d) Trace mode = max hold. e) Measure the maximum width of the emission that is 26 dB down from the maximum of the emission. Page No: 17 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Compare this with the RBW setting of the analyzer. Readjust RBW and repeat measurement as needed until the RBW/EBW ratio is approximately 1%. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
Start Date to Finish Date here Page No: 18 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 99% and 26dB Bandwidth Table Frequency
(MHz) 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Mode Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Data Rate 26dB BW 99% BW
(Mbps)
(MHz) 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 19.8 20.1 41.9 40.6 81.9 82.2 41.4 40.8 19.7 20.2 82.1 82.5 82.8 82.2 19.9 20.2 41.5 40.7 15.0 15.1
(MHz) 16.618 17.638 36.372 36.213 76.366 76.528 36.447 36.212 16.617 17.648 76.309 76.295 76.424 76.552 16.596 17.646 36.387 36.212 13.354 13.849 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 19 of 62 Radio Test Report No: EDCS 18429906 26dB / 99% Bandwidth, 5720 MHz, Non HT20, 6 to 54 Mbps This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 20 of 62 Radio Test Report No: EDCS 18429906 A.3 Maximum Conducted Output Power Maximum Conducted Output Power Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Maximum Conducted Output Power Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 ANSI C63.10: 2013 Maximum Conducted Output Power Test Procedure 1. Set the radio in the continuous transmitting mode at full power 2. Compute power by integrating the spectrum across the EBW (or alternatively entire 99% OBW) of the signal using the instruments band power measurement function. The integration shall be performed using the spectrum analyzer band-power measurement function with band limits set equal to the EBW or the OBW band edges. Page No: 21 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 3. Capture graphs and record pertinent measurement data. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Measurement using a Spectrum Analyzer or EMI Receiver (SA), (d) Method SA-2 Maximum Conducted Output Power Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 System under Support test equipment Date of testing:
Start Date to Finish Date here Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 22 of 62 Radio Test Report No: EDCS 18429906 Maximum Output Power
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n g r a M i Non HT20, 6 to 54 Mbps 1 7 20.2 0.0 20.2 Non HT20, 6 to 54 Mbps 2 7 14.6 14.1 0.0 17.4 Non HT20 Beam Forming, 6 to 54 Mbps 2 10 14.6 14.1 0.0 17.4 HT/VHT20, M0 to M7 1 7 20.2 0.0 20.2 HT/VHT20, M0 to M7 2 7 14.7 14.3 0.0 17.6 HT/VHT20, M8 to M15 2 7 17.2 16.7 0.0 20.0 HT/VHT20 Beam Forming, M0 to M7 2 10 14.7 14.3 0.0 17.6 HT/VHT20 Beam Forming, M8 to M15 2 7 17.2 16.7 0.0 20.0 HT/VHT20 STBC, M0 to M7 2 7 17.2 16.7 0.0 20.0 Non HT40, 6 to 54 Mbps 1 7 15.7 0.0 15.7 Non HT40, 6 to 54 Mbps 2 7 15.6 15.1 0.0 18.4 HT/VHT40, M0 to M7 1 7 15.6 0.1 15.7 HT/VHT40, M0 to M7 2 7 15.6 15.1 0.1 18.4 HT/VHT40, M8 to M15 2 7 15.6 15.1 0.1 18.4 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 2 2 10 7 13.6 15.6 13.1 15.1 0.1 0.1 16.4 18.4 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. Page No: 23 of 62 0 1 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 2.77 5.60 2.60 2.76 5.44 2.99 2.44 2.99 2.99 7.26 4.59 7.34 4.58 4.58 3.58 4.58 Radio Test Report No: EDCS 18429906 HT/VHT40 STBC, M0 to M7 2 7 15.6 15.1 0.1 18.4 0 23. 0 Non HT80, 6 to 54 Mbps 1 7 15.0 0.0 15.0 Non HT80, 6 to 54 Mbps 2 7 11.6 11.0 0.0 14.4 VHT80, M0 to M9 1ss 1 7 15.2 0.2 15.4 VHT80, M0 to M9 1ss 2 7 14.0 13.4 0.2 16.9 0 3 5 5 VHT80, M0 to M9 2ss 2 7 14.0 13.4 0.2 16.9 VHT80 Beam Forming, M0 to M9 1ss 2 10 12.0 11.5 0.2 15.0 VHT80 Beam Forming, M0 to M9 2ss 2 7 14.0 13.4 0.2 16.9 VHT80 STBC, M0 to M9 1ss 2 7 14.0 13.4 0.2 16.9 Non HT40, 6 to 54 Mbps 1 7 18.9 0.0 18.9 Non HT40, 6 to 54 Mbps 2 7 16.9 16.5 0.0 19.8 HT/VHT40, M0 to M7 1 7 20.0 0.1 20.1 HT/VHT40, M0 to M7 2 7 17.8 17.4 0.1 20.7 0 5 5 5 HT/VHT40, M8 to M15 2 7 18.8 18.3 0.1 21.6 HT/VHT40 Beam Forming, M0 to M7 2 10 15.6 15.0 0.1 18.4 HT/VHT40 Beam Forming, M8 to M15 2 7 18.8 18.3 0.1 21.6 HT/VHT40 STBC, M0 to M7 2 7 18.8 18.3 0.1 21.6 Non HT20, 6 to 54 Mbps 1 7 19.4 0.0 19.4 Non HT20, 6 to 54 Mbps 2 7 13.9 13.6 0.0 16.8 Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 2 1 10 7 13.9 19.6 13.6 0.0 0.0 16.8 19.6 23. 0 23. 0 20. 0 23. Page No: 24 of 62 0 6 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 4.58 7.97 8.65 7.60 6.08 6.08 5.04 6.08 6.08 4.06 3.24 2.94 2.33 1.38 1.62 1.38 1.38 3.57 6.20 3.20 3.36 Radio Test Report No: EDCS 18429906 HT/VHT20, M0 to M7 2 7 14.1 13.8 0.0 17.0 HT/VHT20, M8 to M15 2 7 17.4 17.4 0.0 20.5 HT/VHT20 Beam Forming, M0 to M7 2 10 14.1 13.8 0.0 17.0 HT/VHT20 Beam Forming, M8 to M15 2 7 17.4 17.4 0.0 20.5 HT/VHT20 STBC, M0 to M7 2 7 17.4 17.4 0.0 20.5 Non HT80, 6 to 54 Mbps 1 7 14.4 0.0 14.4 Non HT80, 6 to 54 Mbps 2 7 14.4 13.6 0.0 17.1 VHT80, M0 to M9 1ss 1 7 19.6 0.2 19.8 VHT80, M0 to M9 1ss 2 7 18.4 17.9 0.2 21.4 0 1 6 5 VHT80, M0 to M9 2ss 2 7 18.4 17.9 0.2 21.4 VHT80 Beam Forming, M0 to M9 1ss 2 10 16.1 15.3 0.2 18.9 VHT80 Beam Forming, M0 to M9 2ss 2 7 18.4 17.9 0.2 21.4 VHT80 STBC, M0 to M9 1ss 2 7 18.4 17.9 0.2 21.4 Non HT80, 6 to 54 Mbps 1 7 15.5 0.0 15.5 Non HT80, 6 to 54 Mbps 2 7 15.3 14.5 0.0 18.0 VHT80, M0 to M9 1ss 1 7 21.7 0.2 21.9 VHT80, M0 to M9 1ss 2 7 17.5 17.4 0.2 20.7 0 9 6 5 VHT80, M0 to M9 2ss 2 7 17.5 17.4 0.2 20.7 VHT80 Beam Forming, M0 to M9 1ss 2 10 15.3 15.3 0.2 18.5 VHT80 Beam Forming, M0 to M9 2ss 2 7 17.5 17.4 0.2 20.7 VHT80 STBC, M0 to M9 1ss 2 7 17.5 17.4 0.2 20.7 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 25 of 62 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 5.99 2.55 2.99 2.55 2.55 8.57 5.94 3.20 1.64 1.64 1.07 1.64 1.64 7.47 5.04 1.10 2.34 2.34 1.49 2.34 2.34 Radio Test Report No: EDCS 18429906 Non HT20, 6 to 54 Mbps 1 7 18.0 0.0 18.0 Non HT20, 6 to 54 Mbps 2 7 13.2 14.3 0.0 16.8 Non HT20 Beam Forming, 6 to 54 Mbps 2 10 13.2 14.3 0.0 16.8 HT/VHT20, M0 to M7 1 7 17.2 0.0 17.2 0 0 7 5 HT/VHT20, M0 to M7 2 7 13.4 14.4 0.0 17.0 HT/VHT20, M8 to M15 2 7 16.9 18.0 0.0 20.5 HT/VHT20 Beam Forming, M0 to M7 2 10 13.4 14.4 0.0 17.0 HT/VHT20 Beam Forming, M8 to M15 2 7 16.9 18.0 0.0 20.5 HT/VHT20 STBC, M0 to M7 2 7 16.9 18.0 0.0 20.5 Non HT40, 6 to 54 Mbps 1 7 19.7 0.0 19.7 Non HT40, 6 to 54 Mbps 2 7 15.6 16.1 0.0 18.9 HT/VHT40, M0 to M7 1 7 21.5 0.1 21.6 HT/VHT40, M0 to M7 2 7 17.3 17.9 0.1 20.7 0 1 7 5 HT/VHT40, M8 to M15 2 7 17.7 18.2 0.1 21.0 HT/VHT40 Beam Forming, M0 to M7 2 10 14.4 15.0 0.1 17.8 HT/VHT40 Beam Forming, M8 to M15 2 7 17.7 18.2 0.1 21.0 HT/VHT40 STBC, M0 to M7 57 20 Non HT20, 6 to 54 Mbps 2 7 17.7 18.2 0.1 21.0 1 7 19.5 0.0 19.5 Non HT20, 6 to 54 Mbps 2 7 12.7 13.7 0.0 16.3 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 26 of 62 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 23. 0 23. 0 4.97 6.17 3.17 5.76 6.02 2.46 3.02 2.46 2.46 3.26 4.09 1.44 2.32 1.98 2.22 1.98 1.98 3.47 6.73 Radio Test Report No: EDCS 18429906 Non HT20 Beam Forming, 6 to 54 Mbps 2 10 12.7 13.7 0.0 16.3 HT/VHT20, M0 to M7 1 7 18.7 0.0 18.7 HT/VHT20, M0 to M7 2 7 12.7 13.8 0.0 16.3 HT/VHT20, M8 to M15 2 7 16.4 16.3 0.0 19.4 HT/VHT20 Beam Forming, M0 to M7 2 10 12.7 13.8 0.0 16.3 HT/VHT20 Beam Forming, M8 to M15 2 7 16.4 16.3 0.0 19.4 HT/VHT20 STBC, M0 to M7 2 7 16.4 16.3 0.0 19.4 20. 0 23. 0 23. 0 23. 0 20. 0 23. 0 23. 0 3.73 4.26 6.66 3.60 3.66 3.60 3.60 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 27 of 62 Radio Test Report No: EDCS 18429906 Maximum Transmit Output Power, 5610 MHz, VHT80 Beam Forming, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 28 of 62 Radio Test Report No: EDCS 18429906 A.4 Power Spectral Density Power Spectral Density Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Power Spectral Density Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test Procedure The rules requires maximum power spectral density measurements where the intent is to measure the maximum value of the time average of the power spectral density measured during a period of continuous transmission. 1. Create an average power spectrum for the EUT operating mode being tested by following the instructions in section II.E.2. for measuring maximum conducted output power using a spectrum analyzer or EMI receiver: select the Page No: 29 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 appropriate test method (SA-1, SA-2, SA-3, or alternatives to each) and apply it up to, but not including, the step labeled, Compute power. (This procedure is required even if the maximum conducted output power measurement was performed using a power meter, method PM.) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. b) If Method SA-3 Alternative was used and the linear mode was used in step II.E.2.g)(viii), add 1 dB to the final result to compensate for the difference between linear averaging and power averaging. 4. The result is the Maximum PSD over 1 MHz reference bandwidth. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) F. Maximum Power Spectral Density (PSD) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 30 of 62 Radio Test Report No: EDCS 18429906 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment Date of testing:
Start Date to Finish Date here Page No: 31 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Power Spectral Density
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-0.8 10.0 11.77 7.0 9.60 10.0 12.00 7.0 7.78 10.0 10.78 7.0 10.0 10.0 9.63 10.78 10.78 Page No: 32 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 1 2 1 2 2 2 2 2 7 10 7 10 7 10 7 7 5.4 3.4 5.8 4.0 4.9 2.0 4.9 4.9 3.2 3.4 4.5 1.3 4.5 4.5 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 5.4 6.4 5.9 6.8 7.8 4.7 7.8 7.8 10.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 7 10 10 7 10 7 10 7 7 8.7 3.2 3.2 8.9 3.5 6.4 3.5 6.4 6.4 3.0 3.0 2.9 6.6 2.9 6.6 6.6 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 8.7 6.1 6.1 8.9 6.3 9.6 6.3 9.6 9.6 10.0 7.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 4.56 0.65 4.14 0.22 2.23 2.27 2.23 2.23 1.27 0.86 0.86 1.06 0.74 0.45 0.74 0.45 0.45 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 1 2 1 2 2 2 2 2 7 10 7 10 7 10 7 7
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-1.4 10.0 11.37 0 0 7 5 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 1 2 2 1 2 2 7 10 10 7 10 7 7.7 2.5 2.5 6.3 2.6 6.0 3.6 3.6 3.6 7.2 0.0 0.0 0.0 0.0 0.0 0.0 7.7 6.1 6.1 6.3 6.2 9.7 10.0 7.0 7.0 10.0 7.0 10.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 33 of 62 5.66 5.70 3.74 6.74 5.84 6.74 6.74 2.27 0.87 0.87 3.66 0.82 0.31 Radio Test Report No: EDCS 18429906 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 10 7 7 2.6 6.0 6.0 3.6 7.2 7.2 0.0 0.0 0.0 6.2 9.7 9.7 7 10 7 10 7 10 7 7 6.1 2.2 7.7 3.5 3.7 0.6 3.7 3.7 2.5 3.9 4.4 1.0 4.4 4.4 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 6.1 5.4 7.8 6.8 7.1 3.9 7.1 7.1 7 10 10 7 10 7 10 7 7 9.9 3.1 3.1 8.7 2.9 6.7 2.9 6.7 6.7 4.1 4.1 4.1 6.5 4.1 6.5 6.5 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 9.9 6.7 6.7 8.7 6.6 9.7 6.6 9.7 9.7 7.0 10.0 10.0 10.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 10.0 7.0 7.0 10.0 7.0 10.0 7.0 10.0 10.0 0.82 0.31 0.31 3.86 1.60 2.24 0.23 2.87 3.13 2.87 2.87 0.07 0.33 0.33 1.26 0.41 0.35 0.41 0.35 0.35 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 34 of 62 Radio Test Report No: EDCS 18429906 Power Spectral Density, 5720 MHz, Non HT20, 6 to 54 Mbps Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 35 of 62 Radio Test Report No: EDCS 18429906 A.5 Conducted Spurious Emissions Conducted Spurious Emissions Test Requirement 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Spurious Emissions Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 36 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Add the max antenna gain + ground reflection factor (4.7 dB for frequencies between 30 MHz and 1000 MHz, and 0 dB for frequencies > 1000 MHz). Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
11-Nov-19 - 11-Nov-19 Page No: 37 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Conducted Spurs Average Upper Conducted Spurs Peak Upper This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 38 of 62 Radio Test Report No: EDCS 18429906 Conducted Spurious Average Table
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i n a G a n n e t n A d e t a l e r r o C 7 7
) m B d
(
r e w o P r u p S 1 x T
) m B d
(
r e w o P r u p S 2 x T
-50.5
-54.1
-56.0 10
-54.1
-56.0 7 7 7
-50.7
-54.0
-55.8
-51.6
-52.7 10
-54.0
-55.8
-51.6
-52.7
-51.6
-52.7
) B d
(
n o i t c e r r o C e l c y C y t u D 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
) m B d
(
r u p S d e t c u d n o C l a t o T
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(
t i m L i
) B d
(
n g r a M i
-43.5
-41.25 2.22
-44.9
-41.25 3.65
-41.9
-41.25 0.65
-43.7
-41.25 2.41
-44.8
-41.25 3.50
-42.1
-41.25 0.81
-41.8
-41.25 0.50
-42.1
-41.25 0.81
-42.1
-41.25 0.81
-50.0
-53.3
-55.6
-53.3
-53.3
-55.8
-53.3
-55.8 10
-54.1
-56.4
-53.3
-55.8
-53.3
-55.8 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-43.0
-41.25 1.71
-44.2
-41.25 3.00
-46.2
-41.25 4.99
-44.3
-41.25 3.05
-44.3
-41.25 3.05
-42.0
-41.25 0.78
-44.3
-41.25 3.05
-44.3
-41.25 3.05
-49.8
-54.2
-56.6
-53.5
-54.0
-56.1
-54.0
-56.1 10
-58.5
-60.7 7 7
-54.0
-56.1
-54.0
-56.1 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-42.8
-41.25 1.52
-45.2
-41.25 3.94
-46.3
-41.25 5.05
-44.7
-41.25 3.47
-44.7
-41.25 3.47
-46.3
-41.25 5.00
-44.7
-41.25 3.47
-44.7
-41.25 3.47 7 7 7 7 7 7 7 7 7 7 7 7 7 7 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
) z H M
(
y c n e u q e r F 0 0 5 5 Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 39 of 62 Radio Test Report No: EDCS 18429906 0 5 5 5 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 7 7 7 7 7
-50.6
-51.0
-53.2
-50.3
-50.8
-52.9
-50.6
-52.7 10
-53.2
-55.9
-50.6
-52.7
-50.6
-52.7 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-43.6
-41.25 2.31
-41.9
-41.25 0.66
-43.2
-41.25 1.99
-41.7
-41.25 0.41
-41.5
-41.25 0.21
-41.3
-41.25 0.03
-41.5
-41.25 0.21
-41.5
-41.25 0.21
-50.7
-54.0
-56.3 10
-54.0
-56.3 7 7 7
-50.6
-53.9
-56.3
-51.2
-53.3 10
-53.9
-56.3
-51.2
-53.3
-51.2
-53.3 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-43.7
-41.25 2.42
-45.0
-41.25 3.71
-42.0
-41.25 0.71
-43.6
-41.25 2.31
-44.9
-41.25 3.63
-42.1
-41.25 0.82
-41.9
-41.25 0.63
-42.1
-41.25 0.82
-42.1
-41.25 0.82
-51.9
-51.9
-54.6
-50.5
-50.9
-53.2
-50.9
-53.2 10
-54.5
-57.4
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-53.2
-50.9
-53.2 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-44.9
-41.25 3.62
-43.0
-41.25 1.75
-43.3
-41.25 2.05
-41.7
-41.25 0.44
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-41.25 0.44
-42.5
-41.25 1.25
-41.7
-41.25 0.44
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-41.25 0.44
-48.3
-51.2
-53.9
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-50.5
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-53.7
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-54.8 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-41.3
-41.25 0.02
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-41.25 1.05
-41.3
-41.25 0.05
-41.9
-41.25 0.68
-41.9
-41.25 0.68
-41.5
-41.25 0.24
-41.9
-41.25 0.68
-41.9
-41.25 0.68
-50.4
-54.7
-56.3 10
-54.7
-56.3 7 7 7
-50.9
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-52.7
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-43.4
-41.25 2.12
-45.4
-41.25 4.13
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-41.25 1.13
-43.9
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-43.0
-41.25 1.78 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 Page No: 40 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 10
-54.6
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-53.5 0.0 0.0 0.0
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-41.25 0.98
-43.0
-41.25 1.78
-43.0
-41.25 1.78 Radio Test Report No: EDCS 18429906 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 7 7 7 7 7 7 7 7 7 7 7
-49.5
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-54.1
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-54.6
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-52.5 10
-54.4
-55.7 7 7
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-52.5 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-42.5
-41.25 1.21
-42.1
-41.25 0.84
-41.5
-41.25 0.29
-42.9
-41.25 1.64
-41.3
-41.25 0.01
-41.7
-41.25 0.43
-41.3
-41.25 0.01
-41.3
-41.25 0.01 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
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-41.25 1.12
-45.2
-41.25 3.95
-42.2
-41.25 0.95
-42.9
-41.25 1.61
-44.9
-41.25 3.70
-42.4
-41.25 1.15
-41.9
-41.25 0.70
-42.4
-41.25 1.15
-42.4
-41.25 1.15 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 41 of 62 Radio Test Report No: EDCS 18429906 Conducted Spurs Average, 5710 MHz, HT/VHT40, M8 to M15 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 42 of 62
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r u p S d e t c u d n o C l a t o T
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t i m L i
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-34.9
-21.25 13.62
-35.3
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-32.3
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-36.2
-21.25 14.96
-33.1
-21.25 11.81
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-33.1
-21.25 11.81
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(
r e w o P r u p S 3 x T 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Radio Test Report No: EDCS 18429906 Conducted Spurious Emissions Peak Table
) i
) z H M
(
y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps B d
(
i n a G a n n e t n A d e t a s h t a P x T l e r r o C 7 7 1 2
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-41.9
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-45.9
-44.9 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 7 7 7 7 7 7 7 7 7 7 7 7 7 7 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 7 7 7
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-37.6
-21.25 16.31
-35.8
-21.25 14.57
-40.0
-21.25 18.79
-36.4
-21.25 15.14
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-21.25 15.14
-34.1
-21.25 12.87
-36.4
-21.25 15.14
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-21.25 15.14
-43.0
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-47.9
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-46.5
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-50.3
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-36.0
-21.25 14.72
-37.7
-21.25 16.45
-40.1
-21.25 18.85
-36.4
-21.25 15.19
-36.4
-21.25 15.19
-37.2
-21.25 15.99
-36.4
-21.25 15.19
-36.4
-21.25 15.19 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 43 of 62 Radio Test Report No: EDCS 18429906 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 7 7 7 7 7
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-21.25 16.21
-33.7
-21.25 12.49
-36.8
-21.25 15.59
-33.1
-21.25 11.89
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-42.8 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
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-21.25 15.52
-37.2
-21.25 16.00
-34.2
-21.25 13.00
-36.7
-21.25 15.41
-37.2
-21.25 15.98
-33.7
-21.25 12.50
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-40.0
-21.25 18.72
-36.1
-21.25 14.83
-37.9
-21.25 16.65
-34.3
-21.25 13.09
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-21.25 13.72
-36.0
-21.25 14.79
-36.7
-21.25 15.45
-35.9
-21.25 14.65
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-21.25 14.65
-34.8
-21.25 13.54
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-47.3 10
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-47.0 0.0 0.0 0.0 0.0 0.0 0.0
-38.5
-21.25 17.22
-37.8
-21.25 16.52
-34.8
-21.25 13.52
-39.1
-21.25 17.81
-37.2
-21.25 15.98
-36.9
-21.25 15.65 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 7 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 44 of 62 10
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-21.25 15.65 Radio Test Report No: EDCS 18429906 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 7 7 7 7 7 7 7 7 7 7 7
-44.5
-45.8
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-37.5
-21.25 16.21
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-21.25 14.29
-36.7
-21.25 15.49
-36.5
-21.25 15.28
-34.2
-21.25 12.98
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-21.25 13.53
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-21.25 12.98 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
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-21.25 16.52
-38.2
-21.25 16.98
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-21.25 13.98
-37.2
-21.25 15.91
-37.5
-21.25 16.27
-35.9
-21.25 14.62
-34.5
-21.25 13.27
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-35.9
-21.25 14.62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 45 of 62 Radio Test Report No: EDCS 18429906 Conducted Spurs Peak, 5500 MHz, Non HT20 Beam Forming, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 46 of 62 Radio Test Report No: EDCS 18429906 A.6 Conducted Bandedge 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Band Edge Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 47 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging System under Support test equipment Date of testing:
11-Nov-19 - 11-Nov-19 Page No: 48 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Conducted Bandedge Average Table
) i
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(
y c n e u q e r F Mode s h t a P x T Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 i B d
(
n a G a n n e t n A d e t a l e r r o C
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(
l e v e L e g d e d n a B 1
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(
l e v e L e g d e d n a B 2 x T x T
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(
n o i t c e r r o C e l c y C y t u D
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(
l e v e L e g d e d n a B x T l a t o T
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(
t i m L i
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(
n g r a M i 7 7
-51.1
-56.8
-58.6 10
-56.8
-58.6 7 7 7
-50.9
-57.4
-57.2
-54.5
-54.4 10
-57.4
-57.2
-54.5
-54.4
-54.5
-54.4 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0
-44.1
-41.25 2.82
-47.6
-41.25 6.31
-44.6
-41.25 3.31
-43.9
-41.25 2.61
-47.2
-41.25 6.00
-44.4
-41.25 3.15
-44.2
-41.25 3.00
-44.4
-41.25 3.15
-44.4
-41.25 3.15
-49.7
-51.4
-51.9
-51.2
-51.2
-51.8
-51.2
-51.8 10
-55.2
-55.3
-51.2
-51.8
-51.2
-51.8 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-42.7
-41.25 1.41
-41.6
-41.25 0.34
-44.1
-41.25 2.89
-41.4
-41.25 0.17
-41.4
-41.25 0.17
-42.2
-41.25 0.93
-41.4
-41.25 0.17
-41.4
-41.25 0.17
-48.5
-55.0
-54.8
-49.1
-51.7
-51.5
-51.7
-51.5 10
-54.4
-55.2 7 7
-51.7
-51.5
-51.7
-51.5 0.0 0.0 0.2 0.2 0.2 0.2 0.2 0.2
-41.5
-41.25 0.22
-44.9
-41.25 3.61
-41.9
-41.25 0.65
-41.4
-41.25 0.14
-41.4
-41.25 0.14
-41.6
-41.25 0.32
-41.4
-41.25 0.14
-41.4
-41.25 0.14 7 7 7 7 7 7 7 7 7 7 7 7 7 7 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 49 of 62 Radio Test Report No: EDCS 18429906 Conducted Bandedge Average, 5530 MHz, VHT80, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 50 of 62 Radio Test Report No: EDCS 18429906 Conducted Bandedge Peak Table
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-32.7
-25.7
-21.25 4.42
-44.4
-39.6
-31.3
-21.25 10.08 i B d
(
n a G a n n e t n A d e t a l e r r o C 7 7 10
-44.4
-39.6
-28.3
-21.25 7.08 7 7 7
-34.3
-27.3
-21.25 6.01
-44.3
-44.7
-34.4
-21.25 13.19
-41.3
-43.2
-32.1
-21.25 10.84 10
-44.3
-44.7
-31.4
-21.25 10.19 7 7 7 7 7 7 7
-41.3
-43.2
-32.1
-21.25 10.84
-41.3
-43.2
-32.1
-21.25 10.84
-34.7
-27.7
-21.25 6.41
-38.4
-28.9
-21.4
-21.25 0.15
-31.6
-24.5
-21.25 3.29
-31.6
-36.0
-23.2
-21.25 1.95
-31.6
-36.0
-23.2
-21.25 1.95 10
-37.7
-37.3
-24.4
-21.25 3.18 7 7 7 7 7 7 7
-31.6
-36.0
-23.2
-21.25 1.95
-31.6
-36.0
-23.2
-21.25 1.95
-35.4
-28.4
-21.25 7.12
-35.3
-45.1
-27.8
-21.25 6.58
-38.2
-31.0
-21.25 9.75
-38.0
-38.7
-28.1
-21.25 6.88
-38.0
-38.7
-28.1
-21.25 6.88 10
-41.0
-41.4
-28.0
-21.25 6.74 7 7
-38.0
-38.7
-28.1
-21.25 6.88
-38.0
-38.7
-28.1
-21.25 6.88 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 51 of 62 Radio Test Report No: EDCS 18429906 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 7 7
-33.4
-26.4
-21.25 5.12
-42.2
-40.9
-31.5
-21.25 10.21 10
-42.2
-40.9
-28.5
-21.25 7.21 7 7 7
-36.3
-29.3
-21.25 8.01
-42.3
-36.2
-28.2
-21.25 6.95
-34.6
-30.9
-22.3
-21.25 1.06 10
-42.3
-36.2
-25.2
-21.25 3.95 7 7
-34.6
-30.9
-22.3
-21.25 1.06
-34.6
-30.9
-22.3
-21.25 1.06 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 52 of 62 Radio Test Report No: EDCS 18429906 Conducted Bandedge Peak, 5510 MHz, Non HT40, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 53 of 62 Radio Test Report No: EDCS 18429906 Conducted Bandedge Peak, 5700 MHz, HT/VHT20, M8 to M15 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 54 of 62 Radio Test Report No: EDCS 18429906 Appendix B: List of Test Equipment Used to perform the test Equip#
Manufacturer/ Model Description Last Cal Next Due RF Conducted at output antenna port 7329 OMEGA/CT485B Chart Recorder 18 Feb. 2019 18 Feb. 2020 49516 Keysight (Agilent/HP) / N9030A PXA Signal Analyzer, 3Hz to 50GHz 29 Nov. 2019 29 Nov. 2019 55097 Nattional Instruments / PXI-1042 Chassis PXI Cal Not Required Cal Not Required 56089 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 56328 Pasternack / PE5019-1 Torque Wrench 13 Feb. 2019 13 Feb. 2020 57233 Nattional Instruments / PXI-8115 Embedded Controller Cal Not Required Cal Not Required 57253 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 57254 National Instruments / PXI-2799 Switch 1x1 Verify Before Use Verify Before Use 57479 CISCO / ATIL Automation Test Insertion Loss System Verify Before Use Verify Before Use This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 55 of 62 Radio Test Report No: EDCS 18429906 Appendix C: Abbreviation Key and Definitions The following table defines abbreviations used within this test report. Abbreviation Description Abbreviation Description F C Temp Electro Magnetic Compatibility Electro Magnetic Interference Equipment Under Test Information Technology Equipment S/N Qty Test Assessment Schedule emf Electro Static Discharge Electric Fast Transient RMS Qp Engineering Document Control System Configuration Cisco Number (unique identification number for Cisco test equipment) Calibration Av Pk kHz MHz GHz H V dB V kV V A A mS S European Norm International Electro technical Commission International Special Committee on Radio Interference Coupling/Decoupling Network Line Impedance Stabilization Network Protective Earth Ground Line 1 Line2 Line 3 Direct Current Uncorrected measurement value, as indicated by the measuring device Radio Frequency Signal Line Conducted Emissions Measurement distance Not Applicable Power Line Neutral Line Supply EMC EMI EUT ITE TAP ESD EFT EDCS Config CIS#
Cal EN IEC CISPR CDN LISN PE GND L1 L2 L3 DC RAW RF SLCE Meas dist N/A or NA P N S Degrees Fahrenheit Degrees Celsius Temperature Serial Number Quantity Electromotive force Root mean square Quasi Peak Average Peak Kilohertz (1x103) MegaHertz (1x106) Gigahertz (1x109) Horizontal Vertical decibel Volt Kilovolt (1x103) Microvolt (1x10-6) Amp Micro Amp (1x10-6) Milli Second (1x10-3) Micro Second (1x10-6) S m Spec dist SL L R AC Micro Second (1x10-6) Meter Specification distance Signal Line (or Telecom Line) Live Line Return Alternating Current This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 56 of 62 Radio Test Report No: EDCS 18429906 Appendix D: Photographs of Test Setups Title: EUT Pictures Page No: 57 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 58 of 62 Radio Test Report No: EDCS 18429906 Title: Radio Conducted Test Setup Page No: 59 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Appendix E: Software Used to Perform Testing EMIsoft Vasona, version 6.024 Page No: 60 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Appendix F: Test Procedures Measurements were made in accordance with KDB 789033 - D02 General UNII Test Procedures New Rules v02r01 KDB 662911 - MIMO ANSI C63.4 2014 Unintentional Radiators ANSI C63.10 2013 Intentional Radiators Test procedures are summarized below:
FCC 5GHz Test Procedures FCC 5GHz RSE Test Procedures EDCS # 1445048 EDCS # 1511600 Page No: 61 of 62 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429906 Appendix G: Scope of Accreditation (A2LA certificate number 1178-01) The scope of accreditation of Cisco Systems, Inc. can be found on the A2LA web page at:
http://www.a2la.org/scopepdf/1178-01.pdf End This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 62 of 62
1 2 3 4 5 6 | UNI IIC INT 8B | External Photos | 2.88 MiB | September 12 2019 |
Radio Test Report No: EDCS 18429907 Test Report IW-6300H Series Access Point Cisco Industrial Wireless Hazardous Location Access Point FCC ID: LDKESW6300 IC ID: 2461D-ESW6300 5470-5725 MHz Inside Antennas, 8dBi Gain Against the following Specifications:
CFR47 Part 15.407 Cisco Systems 170 West Tasman Drive San Jose, CA 95134 Approved By: Adam Walb Title: MGR. IoT Compliance Revision: 1.0 Author: Julian Land Tested By: Julian Land This report replaces any previously entered test report under EDCS 18429907.This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. Test Report Template EDCS# 11644124. Page No: 1 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 This test report has been electronically authorized and archived using the CISCO Engineering Document Control system. SECTION 1: OVERVIEW ......................................................................................................................................... 3 SECTION2: ASSESSMENT INFORMATION ........................................................................................................ 4 2.1 GENERAL ............................................................................................................................................................. 4 2.2 DATE OF TESTING................................................................................................................................................. 6 2.3 REPORT ISSUE DATE ............................................................................................................................................ 6 2.4 TESTING FACILITIES ............................................................................................................................................. 6 2.5 EQUIPMENT ASSESSED (EUT) .............................................................................................................................. 6 2.6 EUT DESCRIPTION ............................................................................................................................................... 7 SECTION 3: RESULT SUMMARY ........................................................................................................................ 10 3.1 RESULTS SUMMARY TABLE ............................................................................................................................... 10 SECTION 4: SAMPLE DETAILS ........................................................................................................................... 11 4.1 SAMPLE DETAILS ............................................................................................................................................... 11 4.2 SYSTEM DETAILS ............................................................................................................................................... 11 4.3 MODE OF OPERATION DETAILS .......................................................................................................................... 11 APPENDIX A: EMISSION TEST RESULTS ........................................................................................................ 12 CONDUCTED TEST SETUP DIAGRAM ........................................................................................................................ 12 TARGET MAXIMUM CHANNEL POWER .................................................................................................................... 12 A.1 DUTY CYCLE .................................................................................................................................................... 13 A.2 99% AND 26DB BANDWIDTH ............................................................................................................................ 16 A.3 MAXIMUM CONDUCTED OUTPUT POWER ......................................................................................................... 20 A.4 POWER SPECTRAL DENSITY .............................................................................................................................. 28 A.5 CONDUCTED SPURIOUS EMISSIONS ................................................................................................................... 35 A.6 CONDUCTED BANDEDGE ................................................................................................................................... 46 APPENDIX B:
NOT DEFINED. LIST OF TEST EQUIPMENT USED TO PERFORM THE TEST . ERROR! BOOKMARK APPENDIX C: ABBREVIATION KEY AND DEFINITIONS ............................................................................. 54 APPENDIX D:
PHOTOGRAPHS OF TEST SETUPS ................................................................................... 56 APPENDIX E:
SOFTWARE USED TO PERFORM TESTING ................................................................... 59 APPENDIX F:
TEST PROCEDURES ............................................................................................................. 60 APPENDIX G: SCOPE OF ACCREDITATION (A2LA CERTIFICATE NUMBER 1178-01) ........................ 61 Page No: 2 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Section 1: Overview The samples were assessed against the tests detailed in section 3 under the requirements of the following specifications:
Specifications:
CFR47 Part 15.407 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 3 of 61 b) c) d) e) Radio Test Report No: EDCS 18429907 Section2: Assessment Information 2.1 General This report contains an assessment of an apparatus against Electromagnetic Compatibility Standards based upon tests carried out on the samples submitted. The testing was performed by and for the use of Cisco systems Inc:
With regard to this assessment, the following points should be noted:
a) The results contained in this report relate only to the items tested and were obtained in the period between the date of the initial assessment and the date of issue of the report. Manufactured products will not necessarily give identical results due to production and measurement tolerances. The apparatus was set up and exercised using the configuration and modes of operation defined in this report only. Where relevant, the apparatus was only assessed using the susceptibility criteria defined in this report and the Test Assessment Plan (TAP). All testing was performed under the following environmental conditions:
Temperature 15C to 35C (54F to 95F) Atmospheric Pressure 860mbar to 1060mbar (25.4" to 31.3") Humidity 10% to 75*%
All AC testing was performed at one or more of the following supply voltages:
110V 60 Hz (+/-20%) Units of Measurement The units of measurements defined in the appendices are reported in specific terms, which are test dependent. Where radiated measurements are concerned these are defined at a particular distance. Basic voltage measurements are defined in units of [dBuV]
As an example, the basic calculation for all measurements is as follows:
The combinations of correction factors are dependent upon the exact test configurations [see test equipment lists for further details] and may include:-
Emission level [dBuV] = Indicated voltage level [dBuV] + Cable Loss [dB] + Other correction factors [dB]
Antenna Factors, Pre Amplifier Gain, LISN Loss, Pulse Limiter Loss and Filter Insertion Loss Note: to convert the results from dBuV/m to uV/m use the following formula:-
Level in uV/m = Common Antilogarithm [(X dBuV/m)/20] = Y uV/m This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 4 of 61 Radio Test Report No: EDCS 18429907 Measurement Uncertainty Values voltage and power measurements 2 dB conducted EIRP measurements 1.4 dB radiated measurements 3.2 dB frequency measurements 2.4 10-7 temperature measurements humidity measurements 0.54 2.3%
DC and low frequency measurements 2.5%
Where relevant measurement uncertainty levels have been estimated for tests performed on the apparatus. This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2. Radiated emissions (expanded uncertainty, confidence interval 95%) 30 MHz - 300 MHz 300 MHz - 1000 MHz 1 GHz - 10 GHz 10 GHz - 18GHz 18GHz - 26.5GHz 26.5GHz - 40GHz
+/- 3.8 dB
+/- 4.3 dB
+/- 4.0 dB
+/- 8.2 dB
+/- 4.1 dB
+/- 3.9 dB Conducted emissions (expanded uncertainty, confidence interval 95%) A product is considered to comply with a requirement if the nominal measured value is below the limit line. The product is considered to not be in compliance in case the nominal measured value is above the limit line. 30 MHz 40GHz
+/- 0.38 dB This report must not be reproduced except in full, without written approval of Cisco Systems. Page No: 5 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 2.2 Date of testing 11-Nov-19 - 11-Nov-19 2.3 Report Issue Date 11/11/2019 Cisco uses an electronic system to issue, store and control the revision of test reports. This system is called the Engineering Document Control System (EDCS). The actual report issue date is embedded into the original file on EDCS. Any copies of this report, either electronic or paper, that are not on EDCS must be considered uncontrolled. 2.4 Testing facilities This assessment was performed by:
Testing Laboratory Cisco Systems, Inc. 125 West Tasman Drive (Building P) San Jose, CA 95134 USA Headquarters Cisco Systems, Inc., 170 West Tasman Drive San Jose, CA 95134, USA Registration Numbers for Industry Canada Cisco System Site Address Building P, 10m Chamber Building P, 5m Chamber Building I, 5m Chamber 125 West Tasman Dr San Jose, CA 95134 125 West Tasman Dr San Jose, CA 95134 285 W. Tasman Drive San Jose, California 95134 Site Identifier Company #: 2461N-2 Company #: 2461N-1 Company #: 2461M-1 Building 7, 5m Chamber 425 E. Tasman Drive Company #: 2461N-3 San Jose, California 95134 Test Engineers Julian Land 2.5 Equipment Assessed (EUT) IW 6300H Page No: 6 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 2.6 EUT Description The radio supports the following modes of operation. The modes are further defined in the radio Theory of Operation. The modes included in this report represent the worst case data for all modes. 802.11a - Non HT20, Two Antennas, 6 to 54 Mbps, 1ss 802.11a - Non HT20 Beam Forming, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT20, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT20 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT20 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT40, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT40, Two Antennas, 6 to 54 Mbps, 1ss 802.11n/ac - HT/VHT40, One Antenna, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M0 to M7, 1ss 802.11n/ac - HT/VHT40 Beam Forming, Two Antennas, M8 to M15, 2ss 802.11n/ac - HT/VHT40 STBC, Two Antennas, M0 to M7, 2ss 802.11a - Non HT80, One Antenna, 6 to 54 Mbps, 1ss 802.11a - Non HT80, Two Antennas, 6 to 54 Mbps, 1ss 802.11ac - VHT80, One Antenna, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 1ss 802.11ac - VHT80, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 1ss 802.11ac - VHT80 Beam Forming, Two Antennas, M0 to M9 2ss 802.11ac - VHT80 STBC, Two Antennas, M0 to M9 2ss 802.11a - Non HT20, One Antenna, 6 to 54 Mbps, 1ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 7 of 61 Radio Test Report No: EDCS 18429907 Model / PID Differences IW-6300H-AC-x-K9, IW-6300H-DC-x-K9, IW-6300-DCW-x-K9 and ESW-6300-CON-x-K9, all have the same identical components, electronics circuitries, PCB layout and enclosure. The only differences are listed as below:
IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300-DCW-x-K9 ESW-6300-CON-x-K9 Where x can be replaced with another letter to indicate country domain. Domain letters: A, B, C, D, E, F, H, I, L, M, N, Q, R, S, T, Z Where AC is Alternating Current (AC power supply) Where DC is Direct Current (DC power supply), 54V native input Where DCW is Direct Current; wide range 10-36VDC Where K9 is encryption software. Page No: 8 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 The following antennas are supported by this product series. The data included in this report represent the worst case data for all antennas. Frequency Part Number AIR-ANT2450V-N Antenna Type Single Band Omni AIR-ANT2450V-N-HZ Single Band Omni, Hazloc 2.4 GHz AIR-ANT2480V-N AIR-ANT2450HG-N AIR-ANT2450VG-N AIR-ANT2413P2M-N Single Band Omni Horizontal Polarized Omni Vertical Polarized Omni Single Band, Dual Polarized Directional Patch 5 GHz 2.4/5 GHz Single Band Omni Horizontal Polarized Omni AIR-ANT5180V-N AIR-ANT5150HG-N AIR-ANT5150VG-N AIR-ANT5114P2M-N AIR-ANT2547V-N=
AIR-ANT2547VG-N= Dual-band Omni, Gray AIR-ANT2547V-N-HZ= Dual-band Omni, Hazloc Vertical Polarized Omni Dual-band Omni Single Band, Dual Polarized Directional Patch AIR-ANT2568VG-N AIR-ANT2588P3M-N= Dual-band/Dual Polarized Directional, Patch AIR-ANT2513P4M-N Dual-band Polarization Diverse Patch Array Dual-band Omni
>30 degree 5 GHz Antenna Gain
(dBi) NA NA NA NA NA NA
-3
-5
-6 5
-6
-6
-6 3 1
-5 Antenna Gain
(dBi) 5 5 8 5 5 13 8 5 5 13 4 / 7 4 / 7 4 / 7 6 / 8 8 / 8 13 / 13 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 9 of 61 Radio Test Report No: EDCS 18429907 Section 3: Result Summary 3.1 Results Summary Table Conducted emissions Basic Standard FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.407 FCC 15.209 FCC 15.205 Technical Requirements / Details 99% & 26 dB Bandwidth:
The 99% occupied bandwidth is the frequency bandwidth such that, below its lower and above its upper frequency limits, the mean powers are each equal to 0.5% of the total mean power of the given emission. There is no limit for 99% OBW. The 26 dB emission is the width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 26 dB relative to the maximum level measured in the fundamental emission. Output Power:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Power Spectral Density:
15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bandsthe maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Conducted Spurious Emissions / Band-Edge:
15.407 (3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz. Restricted band:
Unwanted emissions falling within the restricted bands, as defined in FCC 15.205 (a) must also comply with the radiated emission limits specified in FCC 15.209 (a). Result Pass Pass Pass Pass Pass Radiated Emissions (General requirements) Basic Standard FCC 15.209 FCC 15.205 FCC 15.207 Technical Requirements / Details TX Spurious Emissions:
Except as provided elsewhere in this subpart, the emissions from an intentional radiator shall not exceed the field strength levels specified in the filed strength limits table in this section. AC conducted Emissions:
Except when the requirements applicable to a given device state otherwise, for any radio apparatus equipped to operate from the public utility AC power supply, either directly or indirectly (such as with a battery charger), the radio frequency voltage of emissions conducted back onto the AC power lines in the frequency range of 0.15 MHz to 30 MHz shall not exceed the limits shown in the table in these sections. The more stringent limit applies at the frequency range boundaries. Result Pass Pass Page No: 10 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Section 4: Sample Details Note: Each sample was evaluated to ensure that its condition was suitable to be used as a test sample prior to the commencement of testing. 4.1 Sample Details Sample No. S01 S02 Equipment Details Manufacturer Hardware Rev. Firmware Rev. Software Rev. Serial Number IW-6300H-DC-B-K9 FSP150-AWAN3 Cisco Systems, Inc. FSP Group Inc. 11
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9.1.8.1 9.0.5.5-W8964 FOC23241G16
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H00000063 4.2 System Details System #
1 EUT and Power Supply 4.3 Mode of Operation Details Mode#
Description Description Samples S01, S02 Comments 1 Continuous Transmitting Continuous Transmitting 98% duty cycle This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 11 of 61 Radio Test Report No: EDCS 18429907 Appendix A: Emission Test Results Conducted Test Setup Diagram Target Maximum Channel Power The following table details the maximum supported Total Channel Power for all operating modes. Operating Mode Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M15 HT/VHT20 Beam Forming, M0 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 HT/VHT40 Beam Forming, M0 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss VHT80 Beam Forming, M0 to M9, M0 to M9 1-2ss VHT80 STBC, M0 to M9 1ss Maximum Channel Power
(dBm) Frequency (MHz) 5500 19 16 19 19 19 5510 17 17 17 17 5530 14 16 16 16 5560 19 15 20 19 19 5550 19 20 20 20 5610 17 20 20 20 5700 18 16 19 19 19 5710 20 21 21 21 5690 18 20 20 20 Page No: 12 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 A.1 Duty Cycle Duty Cycle Test Requirement From KDB 789033 D02 General UNII Test Procedures New Rules v02r01 B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level 1. All measurements are to be performed with the EUT transmitting at 100 percent duty cycle at its maximum power control level; however, if 100 percent duty cycle cannot be achieved, measurements of duty cycle, x, and maximum-power transmission duration, T, are required for each tested mode of operation. Duty Cycle Test Method From KDB 789033 D02 General UNII Test Procedures New Rules v02r01:
B. Duty Cycle (x), Transmission Duration (T), and Maximum Power Control Level The zero-span mode on a spectrum analyzer or EMI receiver, if the response time and spacing between bins on the sweep are sufficient to permit accurate measurements of the on and off times of the transmitted signal. Set the center frequency of the instrument to the center frequency of the transmission. Set RBW EBW if possible; otherwise, set RBW to the largest available value. Set VBW RBW. Set detector = peak or average. The zero-span measurement method shall not be used unless both RBW and VBW are > 50/T, where T is defined in section II.B.1.a), and the number of sweep points across duration T exceeds 100. (For example, if VBW and/or RBW are limited to 3 MHz, then the zero-span method of measuring duty cycle shall not be used if T 16.7 microseconds.) Duty Cycle Test Information Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Date of testing:
11-Nov-19 - 11-Nov-19 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 13 of 61 Radio Test Report No: EDCS 18429907 Duty Cycle Data Table Duty Cycle table and screen captures are shown below for power/psd modes. Frequency Mode Data Rate 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 Duty Cycle correction
(dB) 0.0 0.0 0.0 0.1 0.0 0.2 0.0 0.1 0.0 0.0 0.0 0.2 0.0 0.2 0.0 0.0 0.0 0.1 0.0 0.0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 14 of 61 Radio Test Report No: EDCS 18429907 Duty Cycle Plot, 5530, VHT80, M0 to M9, M0 to M9 1-2ss This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 15 of 61 Radio Test Report No: EDCS 18429907 A.2 99% and 26dB Bandwidth 99% and 26dB Bandwidth Test Requirement There is no requirement for the value of bandwidth. However, the 26dB BW (EBW) is used to calculate the power limits in 15.407 (a) (2). Power measurements are made using the 99% Bandwidth as the integration bandwidth. Band-crossing emissions: For an emission that crosses the boundary between two adjacent U-NII bands, the boundary frequency between the bands serves as one edge for defining the portion of the EBW that falls within a particular U-NII band. However, the -26 dB points are measured relative to the highest point on the contiguous segmentregardless of which band contains that highest point (Figure4). 99% and 26dB Bandwidth Test Procedure Ref. KDB 789033 Section D. 99 Percent Occupied Bandwidth ANSI C63.10: 2013 Section 6.9.3 KDB 662911 99% BW Test Parameters 1. Set center frequency to the nominal EUT channel center frequency. 2. Set span = 1.5 times to 5.0 times the OBW. 3. Set RBW = 1 % to 5 % of the OBW 4. Set VBW 3 RBW 5. Video averaging is not permitted. Where practical, a sample detection and single sweep mode shall be used. Otherwise, peak detection and max hold mode (until the trace stabilizes) shall be used. 6. Use the 99 % power bandwidth function of the instrument (if available). Ref KDB 789033 in Section C. Measurement Bandwidth, Section 1 26 BW Test parameters X dB BW = -26dB (using the OBW function of the spectrum analyzer) Emission Bandwidth (EBW) a) Set RBW = approximately 1% of the emission bandwidth. b) Set the VBW > RBW. c) Detector = Peak. d) Trace mode = max hold. e) Measure the maximum width of the emission that is 26 dB down from the maximum of the emission. Page No: 16 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Compare this with the RBW setting of the analyzer. Readjust RBW and repeat measurement as needed until the RBW/EBW ratio is approximately 1%. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
Start Date to Finish Date here Page No: 17 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 99% and 26dB Bandwidth Table Frequency
(MHz) 5500 5510 5530 5550 5560 5610 5690 5700 5710 5720 Mode Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT80, 6 to 54 Mbps VHT80, M0 to M9, M0 to M9 1-2ss Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M15 Non HT20, 6 to 54 Mbps HT/VHT20, M0 to M15 Data Rate 26dB BW 99% BW
(Mbps)
(MHz) 6 m0 6 m0 6 m0x1 6 m0 6 m0 6 m0x1 6 m0x1 6 m0 6 m0 6 m0 19.9 20.5 41.5 40.6 81.9 82.2 41.2 41.0 19.7 20.2 82.1 82.5 81.9 82.9 19.9 20.1 41.3 41.3 14.9 15.0
(MHz) 16.632 17.638 36.364 36.213 76.366 76.447 36.432 36.214 16.627 17.650 76.309 76.295 76.529 76.450 16.596 17.639 36.412 36.182 13.360 13.850 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 18 of 61 Radio Test Report No: EDCS 18429907 26dB / 99% Bandwidth, 5720 MHz, Non HT20, 6 to 54 Mbps This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 19 of 61 Radio Test Report No: EDCS 18429907 A.3 Maximum Conducted Output Power Maximum Conducted Output Power Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Maximum Conducted Output Power Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 ANSI C63.10: 2013 Maximum Conducted Output Power Test Procedure 1. Set the radio in the continuous transmitting mode at full power 2. Compute power by integrating the spectrum across the EBW (or alternatively entire 99% OBW) of the signal using the instruments band power measurement function. The integration shall be performed using the spectrum analyzer band-power measurement function with band limits set equal to the EBW or the OBW band edges. Page No: 20 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 3. Capture graphs and record pertinent measurement data. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Measurement using a Spectrum Analyzer or EMI Receiver (SA), (d) Method SA-2 Maximum Conducted Output Power Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support List Samples here List Samples here System under Support test equipment Date of testing:
Start Date to Finish Date here Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix C for list of test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 21 of 61 Radio Test Report No: EDCS 18429907 Maximum Output Power
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n g r a M i Non HT20, 6 to 54 Mbps 1 8 19.1 0.0 19.1 Non HT20, 6 to 54 Mbps 2 8 12.9 12.4 0.0 15.7 Non HT20 Beam Forming, 6 to 54 Mbps 2 11 12.9 12.4 0.0 15.7 HT/VHT20, M0 to M7 1 8 19.1 0.0 19.1 HT/VHT20, M0 to M7 2 8 12.9 12.4 0.0 15.7 HT/VHT20, M8 to M15 2 8 16.4 15.8 0.0 19.2 HT/VHT20 Beam Forming, M0 to M7 2 11 12.9 12.4 0.0 15.7 HT/VHT20 Beam Forming, M8 to M15 2 8 16.4 15.8 0.0 19.2 HT/VHT20 STBC, M0 to M7 2 8 16.4 15.8 0.0 19.2 Non HT40, 6 to 54 Mbps 1 8 15.7 0.0 15.7 Non HT40, 6 to 54 Mbps 2 8 14.7 14.1 0.0 17.5 HT/VHT40, M0 to M7 1 8 15.6 0.1 15.7 HT/VHT40, M0 to M7 2 8 14.4 14.0 0.1 17.3 HT/VHT40, M8 to M15 2 8 14.4 14.0 0.1 17.3 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 2 2 11 8 11.4 14.4 11.0 14.0 0.1 0.1 14.3 17.3 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. Page No: 22 of 61 0 1 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 2.87 6.30 3.30 2.86 6.29 2.84 3.29 2.84 2.84 6.26 4.54 6.34 4.73 4.73 4.73 4.73 Radio Test Report No: EDCS 18429907 HT/VHT40 STBC, M0 to M7 2 8 14.4 14.0 0.1 17.3 0 22. 0 Non HT80, 6 to 54 Mbps 1 8 13.6 0.0 13.6 Non HT80, 6 to 54 Mbps 2 8 11.6 11.0 0.0 14.4 VHT80, M0 to M9 1ss 1 8 14.0 0.2 14.2 VHT80, M0 to M9 1ss 2 8 13.1 12.5 0.2 16.0 0 3 5 5 VHT80, M0 to M9 2ss 2 8 13.1 12.5 0.2 16.0 VHT80 Beam Forming, M0 to M9 1ss 2 11 11.1 10.6 0.2 14.1 VHT80 Beam Forming, M0 to M9 2ss 2 8 13.1 12.5 0.2 16.0 VHT80 STBC, M0 to M9 1ss 2 8 13.1 12.5 0.2 16.0 Non HT40, 6 to 54 Mbps 1 8 18.9 0.0 18.9 Non HT40, 6 to 54 Mbps 2 8 15.6 14.9 0.0 18.3 HT/VHT40, M0 to M7 1 8 20.0 0.1 20.1 HT/VHT40, M0 to M7 2 8 15.6 15.0 0.1 18.4 0 5 5 5 HT/VHT40, M8 to M15 2 8 17.1 16.6 0.1 19.9 HT/VHT40 Beam Forming, M0 to M7 2 11 11.4 10.9 0.1 14.2 HT/VHT40 Beam Forming, M8 to M15 2 8 17.1 16.6 0.1 19.9 HT/VHT40 STBC, M0 to M7 2 8 17.1 16.6 0.1 19.9 Non HT20, 6 to 54 Mbps 1 8 19.4 0.0 19.4 Non HT20, 6 to 54 Mbps 2 8 13.0 12.7 0.0 15.9 Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 2 1 11 8 12.0 19.6 11.8 0.0 0.0 14.9 19.6 22. 0 22. 0 19. 0 22. Page No: 23 of 61 0 6 5 5 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 4.73 8.37 7.65 7.80 5.98 5.98 4.94 5.98 5.98 3.06 3.68 1.94 3.62 2.08 4.78 2.08 2.08 2.57 6.10 4.06 2.36 Radio Test Report No: EDCS 18429907 HT/VHT20, M0 to M7 2 8 13.1 12.9 0.0 16.1 HT/VHT20, M8 to M15 2 8 16.3 16.4 0.0 19.4 HT/VHT20 Beam Forming, M0 to M7 2 11 12.1 12.0 0.0 15.1 HT/VHT20 Beam Forming, M8 to M15 2 8 16.3 16.4 0.0 19.4 HT/VHT20 STBC, M0 to M7 2 8 16.3 16.4 0.0 19.4 Non HT80, 6 to 54 Mbps 1 8 14.4 0.0 14.4 Non HT80, 6 to 54 Mbps 2 8 14.4 13.6 0.0 17.1 VHT80, M0 to M9 1ss 1 8 19.6 0.2 19.8 VHT80, M0 to M9 1ss 2 8 16.1 16.6 0.2 19.6 0 1 6 5 VHT80, M0 to M9 2ss 2 8 16.1 16.6 0.2 19.6 VHT80 Beam Forming, M0 to M9 1ss 2 11 16.1 15.3 0.2 18.9 VHT80 Beam Forming, M0 to M9 2ss 2 8 16.1 16.6 0.2 19.6 VHT80 STBC, M0 to M9 1ss 2 8 16.1 16.6 0.2 19.6 Non HT80, 6 to 54 Mbps 1 8 15.3 0.0 15.3 Non HT80, 6 to 54 Mbps 2 8 15.3 14.5 0.0 18.0 VHT80, M0 to M9 1ss 1 8 19.4 0.2 19.6 VHT80, M0 to M9 1ss 2 8 17.1 16.3 0.2 19.9 0 9 6 5 VHT80, M0 to M9 2ss 2 8 17.1 16.3 0.2 19.9 VHT80 Beam Forming, M0 to M9 1ss 2 11 13.4 13.1 0.2 16.5 VHT80 Beam Forming, M0 to M9 2ss 2 8 17.1 16.3 0.2 19.9 VHT80 STBC, M0 to M9 1ss 2 8 17.1 16.3 0.2 19.9 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 24 of 61 0 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 5.95 2.60 3.90 2.60 2.60 7.57 4.94 2.20 2.44 2.44 0.07 2.44 2.44 6.67 4.04 2.40 2.07 2.07 2.54 2.07 2.07 Radio Test Report No: EDCS 18429907 Non HT20, 6 to 54 Mbps 1 8 18.0 0.0 18.0 Non HT20, 6 to 54 Mbps 2 8 12.3 13.2 0.0 15.8 Non HT20 Beam Forming, 6 to 54 Mbps 2 11 12.3 13.2 0.0 15.8 HT/VHT20, M0 to M7 1 8 17.2 0.0 17.2 0 0 7 5 HT/VHT20, M0 to M7 2 8 12.4 13.4 0.0 16.0 HT/VHT20, M8 to M15 2 8 15.4 16.6 0.0 19.1 HT/VHT20 Beam Forming, M0 to M7 2 11 12.4 13.4 0.0 16.0 HT/VHT20 Beam Forming, M8 to M15 2 8 15.4 16.6 0.0 19.1 HT/VHT20 STBC, M0 to M7 2 8 15.4 16.6 0.0 19.1 Non HT40, 6 to 54 Mbps 1 8 19.7 0.0 19.7 Non HT40, 6 to 54 Mbps 2 8 15.6 16.1 0.0 18.9 HT/VHT40, M0 to M7 1 8 19.6 0.1 19.7 HT/VHT40, M0 to M7 2 8 15.7 16.2 0.1 19.0 0 1 7 5 HT/VHT40, M8 to M15 2 8 17.3 17.9 0.1 20.7 HT/VHT40 Beam Forming, M0 to M7 2 11 12.6 13.1 0.1 15.9 HT/VHT40 Beam Forming, M8 to M15 2 8 17.3 17.9 0.1 20.7 HT/VHT40 STBC, M0 to M7 57 20 Non HT20, 6 to 54 Mbps 2 8 17.3 17.9 0.1 20.7 1 8 18.5 0.0 18.5 Non HT20, 6 to 54 Mbps 2 8 11.8 12.8 0.0 15.4 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 25 of 61 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 22. 0 22. 0 3.97 6.18 3.18 4.76 6.02 2.91 3.02 2.91 2.91 2.26 3.09 2.34 2.98 1.32 3.08 1.32 1.32 3.47 6.63 Radio Test Report No: EDCS 18429907 Non HT20 Beam Forming, 6 to 54 Mbps 2 11 11.8 12.8 0.0 15.4 HT/VHT20, M0 to M7 1 8 18.7 0.0 18.7 HT/VHT20, M0 to M7 2 8 11.7 12.8 0.0 15.3 HT/VHT20, M8 to M15 2 8 14.7 16.0 0.0 18.5 HT/VHT20 Beam Forming, M0 to M7 2 11 11.7 12.8 0.0 15.3 HT/VHT20 Beam Forming, M8 to M15 2 8 14.7 16.0 0.0 18.5 HT/VHT20 STBC, M0 to M7 2 8 14.7 16.0 0.0 18.5 19. 0 22. 0 22. 0 22. 0 19. 0 22. 0 22. 0 3.63 3.26 6.66 3.55 3.66 3.55 3.55 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 26 of 61 Radio Test Report No: EDCS 18429907 Maximum Transmit Output Power, 5610 MHz, VHT80 Beam Forming, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 27 of 61 Radio Test Report No: EDCS 18429907 A.4 Power Spectral Density Power Spectral Density Test Requirement 15.407 (2) For the 5.25-5.35 GHz and 5.47-5.725 GHz bands, the maximum conducted output power over the frequency bands of operation shall not exceed the lesser of 250 mW or 11 dBm + 10 log B, where B is the 26 dB emission bandwidth in megahertz. In addition, the maximum power spectral density shall not exceed 11 dBm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dBi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in dB that the directional gain of the antenna exceeds 6 dBi. Band-Crossing Signals When measuring the portion of the maximum conducted output power within a single U-NII band, the power shall be integrated across only the portion of the EBW that falls within that band. That is, if an EBW extends across the boundary between two adjacent bands, the boundary frequency between the bands serves as one edge of the frequency range to be integrated. Integration across an entire U-NII band without regard to 26 dB points is also acceptable for determining conducted output power within that band. Power Spectral Density Test Procedure Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test Procedure The rules requires maximum power spectral density measurements where the intent is to measure the maximum value of the time average of the power spectral density measured during a period of continuous transmission. 1. Create an average power spectrum for the EUT operating mode being tested by following the instructions in section II.E.2. for measuring maximum conducted output power using a spectrum analyzer or EMI receiver: select the Page No: 28 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 appropriate test method (SA-1, SA-2, SA-3, or alternatives to each) and apply it up to, but not including, the step labeled, Compute power. (This procedure is required even if the maximum conducted output power measurement was performed using a power meter, method PM.) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. b) If Method SA-3 Alternative was used and the linear mode was used in step II.E.2.g)(viii), add 1 dB to the final result to compensate for the difference between linear averaging and power averaging. 4. The result is the Maximum PSD over 1 MHz reference bandwidth. Ref. KDB 789033 D02 General UNII Test Procedures New Rules v02r01, F. Maximum Power Spectral Density ANSI C63.10: 2013 Peak Power Spectral Density 12.5, 12.3.2.4 Method SA-2 Power Spectral Density Test parameters Method SA-2 (trace averaging across on and off times of the EUT transmissions, followed by duty cycle correction).
(i) Measure the duty cycle, x, of the transmitter output signal as described in section II.B.
(ii) Set span to encompass the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal.
(iii) Set RBW = 1 MHz.
(iv) Set VBW 3 MHz.
(v) Number of points in sweep 2 Span / RBW. (This ensures that bin-to-bin spacing is RBW/2, so that narrowband signals are not lost between frequency bins.)
(vi) Sweep time = auto.
(vii) Detector = RMS (i.e., power averaging), if available. Otherwise, use sample detector mode.
(viii) Do not use sweep triggering. Allow the sweep to free run.
(ix) Trace average at least 100 traces in power averaging (i.e., RMS) mode; however, the number of traces to be averaged shall be increased above 100 as needed to ensure that the average accurately represents the true average over the on and off periods of the transmitter.
(x) Compute power by integrating the spectrum across the EBW (or, alternatively, the entire 99% occupied bandwidth) of the signal using the instruments band power measurement function with band limits set equal to the EBW (or occupied bandwidth) F. Maximum Power Spectral Density (PSD) 2. Use the peak search function on the instrument to find the peak of the spectrum and record its value. 3. Make the following adjustments to the peak value of the spectrum, if applicable: a) If Method SA-2 or SA-2 Alternative was used, add 10 log(1/x), where x is the duty cycle, to the peak of the spectrum. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. ANSI C63.10 section 14.3.2.2 Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 System under Support test equipment This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 29 of 61 Radio Test Report No: EDCS 18429907 Tested By :
Test Engineer Test Result : PASS Test Equipment See Appendix B for list of test equipment Date of testing:
Start Date to Finish Date here Page No: 30 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Power Spectral Density
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-2.8 3.1 3.1 2.9 2.9 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 5.4 4.7 5.9 4.7 6.1 0.4 6.1 6.1 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 8 11 11 8 11 8 11 8 8 8.7 2.4 1.1 8.9 2.4 5.6 1.5 5.6 5.6 2.1 1.2 2.5 5.4 1.0 5.4 5.4 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 8.7 5.3 4.2 8.9 5.5 8.6 4.3 8.6 8.6 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 1 2 1 2 2 2 2 2 8 11 8 11 8 11 8 8
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-1.0 2.7 2.7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 1 2 2 1 2 2 8 11 11 8 11 8 7.7 1.7 1.7 6.3 1.6 4.6 2.8 2.8 2.8 5.6 0.0 0.0 0.0 0.0 0.0 0.0 7.7 5.3 5.3 6.3 5.3 8.2 9.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 6.0 9.0 6.0 9.0 3.56 1.29 3.14 1.27 2.93 5.63 2.93 2.93 0.27 0.70 1.81 0.06 0.50 0.45 1.69 0.45 0.45 11.27 5.73 6.50 3.93 6.93 4.57 6.93 6.93 10.07 4.66 6.60 3.33 6.33 7.04 6.33 6.33 1.27 0.67 0.67 2.66 0.71 0.82 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 32 of 61 0 0 7 5 Radio Test Report No: EDCS 18429907 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 11 8 8 1.6 4.6 4.6 2.8 5.6 5.6 0.0 0.0 0.0 5.3 8.2 8.2 8 11 8 11 8 11 8 8 6.1 2.2 5.8 2.1 3.5 2.8 2.4 3.9
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-0.7 3.5 3.5 3.9 3.9 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1 6.1 5.6 5.9 5.3 6.8 2.1 6.8 6.8 8 11 11 8 11 8 11 8 8 8.9 1.8 1.8 8.7 2.2 5.0 2.2 5.0 5.0 3.7 3.7 2.9 6.4 2.9 6.4 6.4 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 8.9 5.9 5.9 8.7 5.6 8.8 5.6 8.8 8.8 6.0 9.0 9.0 9.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 9.0 6.0 6.0 9.0 6.0 9.0 6.0 9.0 9.0 0.71 0.82 0.82 2.86 0.44 3.14 0.68 2.23 3.88 2.23 2.23 0.07 0.10 0.10 0.26 0.38 0.19 0.38 0.19 0.19 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 33 of 61 Radio Test Report No: EDCS 18429907 Power Spectral Density, 5560 MHz, HT/VHT20, M0 to M7 Antenna A This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 34 of 61 Radio Test Report No: EDCS 18429907 A.5 Conducted Spurious Emissions Conducted Spurious Emissions Test Requirement 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Spurious Emissions Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 35 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Add the max antenna gain + ground reflection factor (4.7 dB for frequencies between 30 MHz and 1000 MHz, and 0 dB for frequencies > 1000 MHz). Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment System under Support test equipment Date of testing:
11-Nov-19 - 11-Nov-19 Page No: 36 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Conducted Spurs Average Upper Conducted Spurs Peak Upper This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 37 of 61
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-44.3
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-43.1
-41.25 1.81
-44.4
-41.25 3.16
-41.4
-41.25 0.18
-41.4
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-41.25 0.18 Radio Test Report No: EDCS 18429907 Conducted Spurious Average Table
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-51.0
-54.3
-56.7 Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps s h t a P x T 1 2 Non HT20 Beam Forming, 6 to 54 Mbps 2 11
-54.3
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y c n e u q e r F 0 0 5 5 8 8 8
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-53.3 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 8 8 8 8 8 8 8 8 8 8 8 8 8 8 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2
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-42.0
-41.25 0.71
-43.6
-41.25 2.32
-45.2
-41.25 3.99
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-41.9
-41.25 0.62
-44.2
-41.25 2.94
-45.8
-41.25 4.55
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-45.7
-41.25 4.44
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-41.25 2.52 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 38 of 61 Radio Test Report No: EDCS 18429907 0 5 5 5 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 8 8 8 8 8
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-42.6
-41.25 1.31
-43.1
-41.25 1.87
-42.2
-41.25 0.99
-43.3
-41.25 2.03
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-41.25 1.42
-44.2
-41.25 2.94
-41.6
-41.25 0.37
-42.6
-41.25 1.31
-44.1
-41.25 2.90
-41.4
-41.25 0.12
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-41.25 2.62
-42.0
-41.25 0.75
-42.3
-41.25 1.05
-42.1
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-45.1
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-41.25 1.81 Radio Test Report No: EDCS 18429907 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 7 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 2 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 8 8 8 8 8 8 8 8 8 8 8
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-41.25 1.57 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 40 of 61 Radio Test Report No: EDCS 18429907 Conducted Spurs Average, 5500 MHz, Non HT20 Beam Forming, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 41 of 61 Radio Test Report No: EDCS 18429907 Conducted Spurious Emissions Peak Table
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y c n e u q e r F Mode Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss B d
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-21.25 15.20 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 8 8 8 8 8 8 8 8 8 8 8 8 8 8 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 42 of 61 Radio Test Report No: EDCS 18429907 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 5 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 6 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 1 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 9 6 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 0 0 7 5 1 2 1 2 2 2 2 2 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 2 1 2 2 8 8 8 8 8
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-44.2
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-47.7
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-48.2 8 8
-47.7
-47.3
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-47.3 0.0 0.0 0.1 0.1 0.1 0.1 0.1 0.1
-36.5
-21.25 15.21
-35.8
-21.25 14.53
-37.7
-21.25 16.49
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-21.25 14.73
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-21.25 14.28
-33.8
-21.25 12.58
-35.5
-21.25 14.28
-35.5
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-37.5
-21.25 16.22
-37.4
-21.25 16.15
-34.4
-21.25 13.15
-36.2
-21.25 14.91
-37.7
-21.25 16.50
-36.4
-21.25 15.19
-34.7
-21.25 13.50
-36.4
-21.25 15.19
-36.4
-21.25 15.19 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 44 of 61 Radio Test Report No: EDCS 18429907 Conducted Spurs Peak, 5500 MHz, HT/VHT20, M8 to M15 Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 45 of 61 Radio Test Report No: EDCS 18429907 A.6 Conducted Bandedge 15.407(b) Undesirable emission limits. Except as shown in paragraph (b)(7) of this section, the maximum emissions outside of the frequency bands of operation shall be attenuated in accordance with the following limits:
(3) For transmitters operating in the 5.47-5.725 GHz band: All emissions outside of the 5.47-5.725 GHz band shall not exceed an e.i.r.p. of 27 dBm/MHz..
(6) Unwanted emissions below 1 GHz must comply with the general field strength limits set forth in 15.209.
(7) The provisions of 15.205 apply to intentional radiators operating under this section.
(8) When measuring the emission limits, the nominal carrier frequency shall be adjusted as close to the upper and lower frequency band edges as the design of the equipment permits 15.205 / 15.209 - Radiated emissions which fall in the restricted bands, as defined in Section 15.205(a), must also comply with the radiated emission limits specified in Section 15.209(a) (see Section 15.205(c)). Use formula below to substitute conducted measurements in place of radiated measurements E[dBV/m] = EIRP[dBm] - 20 log(d[meters]) + 104.77, where E = field strength and d = 3 meter 1) Average Plot, Limit= -41.25 dBm eirp 2) Peak plot, Limit = -21.25 dBm eirp KDB 789033 D02 General UNII Test Procedures New Rules v02r01 2. Unwanted Emissions that fall Outside of the Restricted Bands a) For all measurements, follow the requirements in II.G.3. General Requirements for Unwanted Emissions Measurements. b) At frequencies below 1000 MHz, use the procedure described in II.G.4. Procedure for Unwanted Emissions Measurements Below 1000 MHz. c) At frequencies above 1000 MHz, use the procedure for maximum emissions described in II.G.5., Procedure for Unwanted Emissions Measurements Above 1000 MHz.
(i) Sections 15.407(b)(1-3) specifies the unwanted emissions limit for the U-NII-1 and U-NII-2 bands. As specified, emissions above 1000 MHz that are outside of the restricted bands are subject to a peak emission limit of 27 dBm/MHz.3 Conducted Band Edge Test Procedure KDB 789033 D02 General UNII Test Procedures New Rules v02r01 Ref. ANSI C63.10: 2013 Conducted Spurious Emissions Test Procedure 1. Connect the antenna port(s) to the spectrum analyzer input. 2. Place the radio in continuous transmit mode 3. Configure Spectrum analyzer as per test parameters below (be sure to enter all losses between the transmitter output and the spectrum analyzer). 4. Use the peak marker function to determine the maximum spurs amplitude level. 5. The measure-and-sum technique is used for measuring in-band transmit power of a device. In the measure-and-sum approach, the conducted emission level is measured at each antenna port. The measured results at the various antenna ports are then summed mathematically to determine the total emission level from the device. Summing is performed in linear power units. The worst case output is recorded. (see ANSI C63.10:2013 section 14.3.2.2) Page No: 46 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 6. Capture graphs and record pertinent measurement data. Ref. ANSI C63.10: 2013 section 12.7.6 (Peak) and 12.7.7.2 (Average) KDB 789033 D02 General UNII Test Procedures New Rules v02r01, Sec. 5 (Peak), Sec. 6 (Average Method AD) Conducted Spurious Emissions Test parameters Peak RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = Peak Trace = Max Hold. Samples, Systems, and Modes System Number Description Samples 1 EUT Support S01 S02 Tested By :
Julian Land Test Result : PASS Test Equipment See Appendix B for list of test equipment Average RBW = 1 MHz VBW 3 MHz Sweep = Auto Detector = RMS Power Averaging System under Support test equipment Date of testing:
11-Nov-19 - 11-Nov-19 Page No: 47 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Conducted Bandedge Average Table
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y c n e u q e r F Mode s h t a P x T Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 5 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 Non HT40, 6 to 54 Mbps Non HT40, 6 to 54 Mbps HT/VHT40, M0 to M7 HT/VHT40, M0 to M7 HT/VHT40, M8 to M15 0 1 5 5 HT/VHT40 Beam Forming, M0 to M7 HT/VHT40 Beam Forming, M8 to M15 HT/VHT40 STBC, M0 to M7 Non HT80, 6 to 54 Mbps Non HT80, 6 to 54 Mbps VHT80, M0 to M9 1ss VHT80, M0 to M9 1ss VHT80, M0 to M9 2ss 0 3 5 5 VHT80 Beam Forming, M0 to M9 1ss VHT80 Beam Forming, M0 to M9 2ss VHT80 STBC, M0 to M9 1ss 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 i B d
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-52.9
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-58.1
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-44.9
-41.25 3.62
-47.1
-41.25 5.85
-44.1
-41.25 2.85
-45.2
-41.25 3.91
-47.2
-41.25 5.99
-43.8
-41.25 2.54
-44.2
-41.25 2.99
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-41.25 2.54
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-59.9
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-41.7
-41.25 0.41
-43.0
-41.25 1.77
-43.1
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-42.0
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-41.25 0.78
-45.8
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-42.0
-41.25 0.78
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-42.7
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-43.5
-41.25 2.25
-41.4
-41.25 0.14
-41.4
-41.25 0.14
-42.2
-41.25 0.97
-41.4
-41.25 0.14
-41.4
-41.25 0.14 8 8 8 8 8 8 8 8 8 8 8 8 8 8 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 48 of 61 Radio Test Report No: EDCS 18429907 Conducted Bandedge Average, 5530 MHz, VHT80, M0 to M9 1ss Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 49 of 61 Radio Test Report No: EDCS 18429907 Conducted Bandedge Peak Table
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-44.0
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-32.5
-21.25 11.28
-41.4
-43.5
-31.3
-21.25 10.02 11
-44.0
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-29.5
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-41.4
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-31.3
-21.25 10.02
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-21.25 10.02
-34.7
-26.7
-21.25 5.41
-37.8
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-21.25 0.47
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-34.7
-33.0
-22.7
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-21.25 1.45 11
-39.7
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-34.7
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-35.3
-45.1
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-21.25 5.58
-38.0
-29.8
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-41.5
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-41.5
-40.3
-29.7
-21.25 8.40 s h t a P x T 1 2 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 1 2 2 2 2 2 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 50 of 61 Radio Test Report No: EDCS 18429907 Non HT20, 6 to 54 Mbps Non HT20, 6 to 54 Mbps Non HT20 Beam Forming, 6 to 54 Mbps 0 0 7 5 HT/VHT20, M0 to M7 HT/VHT20, M0 to M7 HT/VHT20, M8 to M15 HT/VHT20 Beam Forming, M0 to M7 HT/VHT20 Beam Forming, M8 to M15 HT/VHT20 STBC, M0 to M7 1 2 2 1 2 2 2 2 2 8 8
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-21.25 4.08 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 51 of 61 Radio Test Report No: EDCS 18429907 Conducted Bandedge Peak, 5510 MHz, Non HT40, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 52 of 61 Radio Test Report No: EDCS 18429907 Conducted Bandedge Peak, 5700 MHz, Non HT20 Beam Forming, 6 to 54 Mbps Antenna A Antenna B This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 53 of 61 Radio Test Report No: EDCS 18429907 Appendix B: List of Test Equipment Used to perform the test Equip#
Manufacturer/ Model Description Last Cal Next Due 7329 OMEGA/CT485B Chart Recorder 18 Feb. 2019 18 Feb. 2020 RF Conducted at output antenna port 49516 Keysight (Agilent/HP) / N9030A PXA Signal Analyzer, 3Hz to 50GHz 29 Nov. 2019 29 Nov. 2019 55097 Nattional Instruments / PXI-1042 Chassis PXI Cal Not Required Cal Not Required 56089 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 56328 Pasternack / PE5019-1 Torque Wrench 13 Feb. 2019 13 Feb. 2020 57233 Nattional Instruments / PXI-8115 Embedded Controller Cal Not Required Cal Not Required 57253 National Instruments / PXI-2796 40GHz Dual 6x1 Multiplexer
(SP6T) Verify Before Use Verify Before Use 57254 National Instruments / PXI-2799 Switch 1x1 Verify Before Use Verify Before Use 57479 CISCO / ATIL Automation Test Insertion Loss System Verify Before Use Verify Before Use This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 54 of 61 Radio Test Report No: EDCS 18429907 Appendix C: Abbreviation Key and Definitions The following table defines abbreviations used within this test report. Abbreviation Description Abbreviation Description F C Temp Electro Magnetic Compatibility Electro Magnetic Interference Equipment Under Test Information Technology Equipment S/N Qty Test Assessment Schedule emf Electro Static Discharge Electric Fast Transient RMS Qp Engineering Document Control System Configuration Cisco Number (unique identification number for Cisco test equipment) Calibration Av Pk kHz MHz GHz H V dB V kV V A A mS S European Norm International Electro technical Commission International Special Committee on Radio Interference Coupling/Decoupling Network Line Impedance Stabilization Network Protective Earth Ground Line 1 Line2 Line 3 Direct Current Uncorrected measurement value, as indicated by the measuring device Radio Frequency Signal Line Conducted Emissions Measurement distance Not Applicable Power Line Neutral Line Supply EMC EMI EUT ITE TAP ESD EFT EDCS Config CIS#
Cal EN IEC CISPR CDN LISN PE GND L1 L2 L3 DC RAW RF SLCE Meas dist N/A or NA P N S Degrees Fahrenheit Degrees Celsius Temperature Serial Number Quantity Electromotive force Root mean square Quasi Peak Average Peak Kilohertz (1x103) MegaHertz (1x106) Gigahertz (1x109) Horizontal Vertical decibel Volt Kilovolt (1x103) Microvolt (1x10-6) Amp Micro Amp (1x10-6) Milli Second (1x10-3) Micro Second (1x10-6) S m Spec dist SL L R AC Micro Second (1x10-6) Meter Specification distance Signal Line (or Telecom Line) Live Line Return Alternating Current This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 55 of 61 Radio Test Report No: EDCS 18429907 Appendix D: Photographs of Test Setups Title: EUT Pictures Page No: 56 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 57 of 61 Radio Test Report No: EDCS 18429907 Title: Radio Conducted Test Setup Page No: 58 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Appendix E: Software Used to Perform Testing EMIsoft Vasona, version 6.024 Page No: 59 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Appendix F: Test Procedures Measurements were made in accordance with KDB 789033 - D02 General UNII Test Procedures New Rules v02r01 KDB 662911 - MIMO ANSI C63.4 2014 Unintentional Radiators ANSI C63.10 2013 Intentional Radiators Test procedures are summarized below:
FCC 5GHz Test Procedures FCC 5GHz RSE Test Procedures EDCS # 1445048 EDCS # 1511600 Page No: 60 of 61 This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Radio Test Report No: EDCS 18429907 Appendix G: Scope of Accreditation (A2LA certificate number 1178-01) The scope of accreditation of Cisco Systems, Inc. can be found on the A2LA web page at:
http://www.a2la.org/scopepdf/1178-01.pdf End This document is uncontrolled. Please refer to the electronic copy within EDCS for the most up to date version. Cisco Systems, Inc. Company Confidential Page No: 61 of 61
1 2 3 4 5 6 | Label and Location | ID Label/Location Info | 307.61 KiB | June 30 2020 |
Engineering Drawing of where the compliance labels go. Label placement and blown up version. MODEL: ESW-6300-CON-B-K9
1 2 3 4 5 6 | Labels | ID Label/Location Info | 589.44 KiB | September 12 2019 |
Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 LDKESW6300 2461N-ESW6300 Drawings of the compliance label on the module Engineering Drawing of where the compliance labels go. Label placement and blown up version. The label is printed on demand so the FCC and IC ID numbers are filled in during printing The printed text is controlled by our product mapping file MODEL: ESW-6300-CON FCC ID: LDKESW6300 IC ID: 2461N-ESW6300 IW-6300H-AC-x-K9 IW-6300H-DC-x-K9 IW-6300H-DCW-x-K9
1 2 3 4 5 6 | Full Module Cover | Cover Letter(s) | 104.86 KiB | June 30 2020 |
Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 The intent of this cover letter is to provide notification of permissive class II changes for converting existing Limited Modular Grant of device with FCC ID: LDKESW6300 into full single module 11th June 2020 Dear Regulatory Authority, Sincerely yours,
Adam Walb / Manager, Compliance Cisco Systems Inc Tel: 408-526-4124 E-mail: awalb@cisco.com
1 2 3 4 5 6 | Prof Installation Cover | Cover Letter(s) | 261.51 KiB | June 30 2020 |
Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 The intent of this cover letter is to provide notification of professional installation as per KDB 353028 for device with FCC ID: LDKESW6300 18th June 2020 Dear Regulatory Authority, Sincerely yours,
Adam Walb / Manager, Compliance Cisco Systems Inc Tel: 408-526-4124 E-mail: awalb@cisco.com
1 2 3 4 5 6 | Confid | Cover Letter(s) | 80.14 KiB | September 12 2019 |
Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 Pursuant to the provisions of sections 0.457 and 0.459 of the commission rules of CFR 47, we request the commission to withhold the following attachments as confidential documents from public disclosure indefinitely Above mentioned documents contain details of system and equipment descriptions are considered as proprietary information in operation of the equipment. The public disclosure of above documents might be harmful to our company and would give competitor an unfair advantage in the market Nov 21, 2019 Subject: Request for Confidentiality FCCID: LDKESW6300 Dear Regulatory Authority, Schematics Block Diagram Operational Description Antenna Specification Software Theory of Operation Software Security Sincerely yours,
Adam Walb / Manager, Compliance Cisco Systems Inc Tel: 408-526-4124 E-mail: awalb@cisco.com
1 2 3 4 5 6 | LMA Cover | Cover Letter(s) | 397.28 KiB | September 12 2019 |
Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 Dec 2, 2019 Dear FCC Examiner, We are applying for FCC Limited Modular Approval (LMA) of a 2.4&5GHz WiFi Access Point under the FCC ID: LDKESW6300. This electrical identical AP has been certified as end-product under FCC-ID: LDK102103 on 12/09/2016. Due to documented equality we intend to leverage test results from the the following test reports as filed for the initial approval under FCC-ID: LDK102103:
#EDCS-11386281, 20-August-16 (DFS test report);
#EDCS- 11386277, (MPE report);
We confirm that the leveraged test results from the above reports are representative for the same radio being part of the new LMA. All conducted measurement has been repeated with the original radio, as approved under FCC-ID: LDK102103, being part of a new host design. The reason for this request is because the LDK102103 was granted as a system and Cisco intends to separate just the radio from LDK102103 to be used as a module in three different new Cisco products. The three new products are identical to each other except for how they are powered, AC, DC, and wide range DC. In this case, the radio from LDK102103 is the same Cisco part number and same firmware as what we will use with LDKESW6300. There are no radio module changes to the hardware, the same software runs on both of these IDs, they both use the same power table (this is an SDR), and the supported antenna table is identical. We are applying for expedited DFS review due to the confirmed and documented equality of the initial end-product approval and the LMA in all relevant parts including antennas and gains. Conducted Reports:
The new product that directly re-uses the radio portion from LDK102103 breaks the reports up by UNII bands and by whether the internal or the external antennas are being tested. In this case, external these are the physically located outer antennas and the internal: are the ones physically located to the center of the bottom of the chassis. The next page provides pictures with descriptions. Please note that actually all antennas are external and there are no internal (inside the device) antennas. Here is the picture of the radio module that we are requesting LMA grant under FCC ID:
LDKESW6300:
Here is the picture of the radio module with the antenna descriptions that are described in the conducted measurement reports:
This is the module that we are working on the LMA for. I have underlined the Antenna A, B, C, D ports Here are the pictures covering how these antenna ports are connected from this module to the outside of our new product. Note the descriptions for internal and external. A, B = External (the outside ones) C, D = Internal (the inner two) External A Internal C D B For any further questions, please feel free to contact me per below given phone number or email. Sincerely yours,
Adam Walb / Manager, Compliance Cisco Systems Inc Tel: 408-526-4124 E-mail: awalb@cisco.com
1 2 3 4 5 6 | Modular Approval Letter | Cover Letter(s) | 100.82 KiB | September 12 2019 |
Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 Subject: Modular Approval Statement Date: November 26, 2019 FCC ID: LDKESW6300 TO WHOM IT MAY CONCERN Pursuant to Paragraphs part 15.212, we herewith declare for our module.
(please provide explanation in related comment fields supporting the answer) Modular approval requirement a. The radio elements must have the radio frequency circuitry shielded. Physical components and tuning capacitor(s) may be located external to the shield, but must be on the module assembly;
b. The module must have buffered modulation/data inputs to ensure that the device will comply with Part 15 requirements with any type of input signal;
c. The module must contain power supply regulation on the module;
yes d. The module must contain a permanently attached antenna, or contain a unique antenna connector, and be marketed and operated only with specific antenna(s), per Sections 15.203, 15.204(b), 15.204(c), 15.212(a), 2.929(b);
comment:
e. The module must demonstrate compliance in a stand-alone configuration;
no f. The module must be labelled with its permanently affixed FCC ID label, or use an electronic display (See KDB Publication 784748 about labelling requirements);
comment:
comment:
comment:
comment:
yes yes yes yes Cisco Systems, Inc 170 West Tasman Drive San Jose, CA 95134 g. The module must comply with all specific rules applicable to the transmitter including all the conditions to be provided to the installer in the integration instructions;
comment:
h. The module must comply with RF exposure requirements;
yes yes comment:
comment:
Sincerely yours,
Adam Walb / Manager, Compliance Cisco Systems Inc Tel: 408-526-4124 E-mail: awalb@cisco.com
1 2 3 4 5 6 | Cover Letter | Cover Letter(s) | 63.82 KiB | August 08 2019 |
CiscoSystems,Inc 170WestTasmanDrive SanJose,CA95134 August,5,2019 DearRegulatoryAuthority, ThisChangeofIdentificationrequestappliesforanewFCCIDasestablishedin47CFR2.933(b) foracurrentlyapproveddevice.ThisapplicationbyCiscoSystemswillestablishanewFCCID:
LDKESW6300underCiscoSystemsgranteecodeforpurposeofmarketing.Theoriginalgrantto Ciscowillremainineffect. Per2.933(b) 1. TheoriginalidentificationisLDK102104 2. Theoriginalgrantdatesare a. DTS:10/25/2016 b. UNII:10/25/2016 different. 3. Theequipmentiselectricallyidentical.OnlythemodelnameandFCCIDnumberare 4. Theoriginaltestresultsareapplicableandrepresentativeofthischangeddevice 5. ThepurposeofthechangeofIDistoaddanewmodelthatwillbemarketedfor industrialandhazardouslocations.AC2PCwillbefiledoncethischangeofIDhasbeen grantedtomodifythisgranttoincludethephysicalmodifications. 6. Externalphotos,labels,andthiscoverletterareincludedinthisapplication. 7. Additionalattestationdocumentswillbeprovidedasneeded. Note:TheoriginalFCCIDandgrantandthenewFCCIDandgrantbelongtothesamegrantee, CiscoSystemsandthegranteeretainsfullresponsibilityforsecurityandconfigurationcontrol forbothFCCIDsandgrants. Ifyouhaveanyquestionsregardingthisapplication,pleasefeelfreetocontactme. Sincerely yours,
-----------------------------------
Adam Walb / Manager, Compliance Cisco Systems Inc Tel: 408-526-4124 E-mail: awalb@cisco.com
frequency | equipment class | purpose | ||
---|---|---|---|---|
1 | 2020-06-30 | 2412 ~ 2462 | DTS - Digital Transmission System | Class II Permissive Change |
2 | 5745 ~ 5825 | NII - Unlicensed National Information Infrastructure TX | ||
3 | 2019-12-13 | 2412 ~ 2462 | DTS - Digital Transmission System | Original Equipment |
4 | 5745 ~ 5825 | NII - Unlicensed National Information Infrastructure TX | ||
5 | 2019-08-08 | 2412 ~ 2462 | DTS - Digital Transmission System | Change in Identification |
6 | 5180 ~ 5240 | NII - Unlicensed National Information Infrastructure TX |
app s | Applicant Information | |||||
---|---|---|---|---|---|---|
1 2 3 4 5 6 | Effective |
2020-06-30
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1 2 3 4 5 6 |
2019-12-13
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1 2 3 4 5 6 |
2019-08-08
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1 2 3 4 5 6 | Applicant's complete, legal business name |
Cisco Systems Inc
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1 2 3 4 5 6 | FCC Registration Number (FRN) |
0004968939
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1 2 3 4 5 6 | Physical Address |
125 West Tasman Drive
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1 2 3 4 5 6 |
San Jose
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1 2 3 4 5 6 |
United States
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app s | TCB Information | |||||
1 2 3 4 5 6 | TCB Application Email Address |
t******@tuv.com
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1 2 3 4 5 6 | TCB Scope |
A4: UNII devices & low power transmitters using spread spectrum techniques
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app s | FCC ID | |||||
1 2 3 4 5 6 | Grantee Code |
LDK
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1 2 3 4 5 6 | Equipment Product Code |
ESW6300
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app s | Person at the applicant's address to receive grant or for contact | |||||
1 2 3 4 5 6 | Name |
G****** T******
|
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1 2 3 4 5 6 | Title |
Manager, Engineering
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1 2 3 4 5 6 | Telephone Number |
408-5********
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1 2 3 4 5 6 | Fax Number |
408-5********
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1 2 3 4 5 6 |
g******@cisco.com
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app s | Technical Contact | |||||
1 2 3 4 5 6 | Firm Name |
Cisco Systems
|
||||
1 2 3 4 5 6 | Name |
A**** W****
|
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1 2 3 4 5 6 | Physical Address |
560 McCarthy Blvd
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1 2 3 4 5 6 |
Milpitas, California 95035
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1 2 3 4 5 6 |
Milpitas, 95035
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1 2 3 4 5 6 |
United States
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1 2 3 4 5 6 | Telephone Number |
408 5********
|
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1 2 3 4 5 6 |
a******@cisco.com
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app s | Non Technical Contact | |||||
n/a | ||||||
app s | Confidentiality (long or short term) | |||||
1 2 3 4 5 6 | Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?: | No | ||||
1 2 3 4 5 6 | Yes | |||||
1 2 3 4 5 6 | Long-Term Confidentiality Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?: | No | ||||
if no date is supplied, the release date will be set to 45 calendar days past the date of grant. | ||||||
app s | Cognitive Radio & Software Defined Radio, Class, etc | |||||
1 2 3 4 5 6 | Is this application for software defined/cognitive radio authorization? | No | ||||
1 2 3 4 5 6 | Equipment Class | DTS - Digital Transmission System | ||||
1 2 3 4 5 6 | NII - Unlicensed National Information Infrastructure TX | |||||
1 2 3 4 5 6 | Description of product as it is marketed: (NOTE: This text will appear below the equipment class on the grant) | CISCO 6300 Series Embedded Access Point | ||||
1 2 3 4 5 6 | 802.11ac Dual Band Outdoor Access Point | |||||
1 2 3 4 5 6 | Related OET KnowledgeDataBase Inquiry: Is there a KDB inquiry associated with this application? | No | ||||
1 2 3 4 5 6 | Yes | |||||
1 2 3 4 5 6 | Modular Equipment Type | Single Modular Approval | ||||
1 2 3 4 5 6 | Limited Single Modular Approval | |||||
1 2 3 4 5 6 | Does not apply | |||||
1 2 3 4 5 6 | Purpose / Application is for | Class II Permissive Change | ||||
1 2 3 4 5 6 | Original Equipment | |||||
1 2 3 4 5 6 | Change in Identification | |||||
1 2 3 4 5 6 | Composite Equipment: Is the equipment in this application a composite device subject to an additional equipment authorization? | Yes | ||||
1 2 3 4 5 6 | Related Equipment: Is the equipment in this application part of a system that operates with, or is marketed with, another device that requires an equipment authorization? | No | ||||
1 2 3 4 5 6 | Grant Comments | This device has 20 MHz, 40 MHz and 80 MHz bandwidth modes. This device is capable of 2x2 MIMO operation. Output power is maximum combined conducted power. The documented antennas with 8dBi and more gain used for this transmitter must be installed to provide a separation distance of at least 60 cm from all persons, those with less than 8dBi at least 25 cm. The specified antennas must not be co-located or operating in conjunction with any other antenna or transmitter. Users and installers must be provided with antenna installation instructions and transmitter operating conditions for satisfying RF exposure compliance. | ||||
1 2 3 4 5 6 | This device has 20 MHz, 40 MHz and 80 MHz bandwidth modes. This device is capable of 2x2 MIMO operation. Output power is maximum combined conducted power. The documented antennas with 8dBi and more gain used for this transmitter must be installed to provide a separation distance of at least 60 cm from all persons, those with less than 8dBi at least 25 cm. The specified antennas must not be co-located or operating in conjunction with any other antenna or transmitter. Users and installers must be provided with antenna installation instructions and transmitter operating conditions for satisfying RF exposure compliance | |||||
1 2 3 4 5 6 | This module is limited to Cisco System products only and host enclosures and antenna arrangements that are similar to the reference device. This device has 20 MHz, 40 MHz and 80 MHz bandwidth modes. This device is capable of 2x2 MIMO operation. Output power is maximum combined conducted power. The documented antennas with 8dBi and more gain used for this transmitter must be installed to provide a separation distance of at least 60 cm from all persons, those with less than 8dBi at least 25 cm. The specified antennas must not be co-located or operating in conjunction with any other antenna or transmitter. Users and installers must be provided with antenna installation instructions and transmitter operating conditions for satisfying RF exposure compliance. | |||||
1 2 3 4 5 6 | Output power is maximum combined EiRP. This device is capable of 3x3 MIMO operation. The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 60 cm from all persons and must not be co-located or operating in conjunction with any other antenna or transmitter. Users and installers must be provided with antenna installation instructions and transmitter operating conditions for satisfying RF exposure compliance. | |||||
1 2 3 4 5 6 | This device has 20 MHz, 40 MHz and 80 MHz bandwidth modes. This device is capable of 3x3 MIMO operation. Output power is maximum combined conducted power. The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 60 cm from all persons and must not be co-located or operating in conjunction with any other antenna or transmitter. Users and installers must be provided with antenna installation instructions and transmitter operating conditions for satisfying RF exposure compliance. | |||||
1 2 3 4 5 6 | Is there an equipment authorization waiver associated with this application? | No | ||||
1 2 3 4 5 6 | If there is an equipment authorization waiver associated with this application, has the associated waiver been approved and all information uploaded? | No | ||||
app s | Test Firm Name and Contact Information | |||||
1 2 3 4 5 6 | Firm Name |
TUV Rheinland of North America Inc.
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1 2 3 4 5 6 |
Cisco Systems, Inc.
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1 2 3 4 5 6 |
TUV SUD America Inc.
|
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1 2 3 4 5 6 | Name |
D******** S********
|
||||
1 2 3 4 5 6 |
G****** T********
|
|||||
1 2 3 4 5 6 |
M****** E********
|
|||||
1 2 3 4 5 6 | Telephone Number |
(925)********
|
||||
1 2 3 4 5 6 |
408-5********
|
|||||
1 2 3 4 5 6 |
813-2********
|
|||||
1 2 3 4 5 6 | Fax Number |
925 2********
|
||||
1 2 3 4 5 6 |
40852********
|
|||||
1 2 3 4 5 6 |
978 9********
|
|||||
1 2 3 4 5 6 |
d******@us.tuv.com
|
|||||
1 2 3 4 5 6 |
g******@cisco.com
|
|||||
1 2 3 4 5 6 |
W******@tuvsud.com
|
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Equipment Specifications | |||||||||||||||||||||||||||||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
1 | 1 | 15C | 36 CC MO | 2412.00000000 | 2462.00000000 | 0.6000000 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
2 | 1 | 15E | 36 CC MO | 5180 | 5240 | 0.479 | |||||||||||||||||||||||||||||||||||
2 | 2 | 15E | 36 CC MO | 5260 | 5320 | 0.229 | |||||||||||||||||||||||||||||||||||
2 | 3 | 15E | 36 CC MO | 5550 | 5720 | 0.246 | |||||||||||||||||||||||||||||||||||
2 | 4 | 15E | 36 CC MO | 5745 | 5825 | 0.49 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
3 | 1 | 15C | 36 CC MO | 2412.00000000 | 2462.00000000 | 0.6000000 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
4 | 1 | 15E | 36 CC MO ND | 5180 | 5240 | 0.479 | |||||||||||||||||||||||||||||||||||
4 | 2 | 15E | 36 CC MO ND | 5260 | 5320 | 0.229 | |||||||||||||||||||||||||||||||||||
4 | 3 | 15E | 36 CC MO ND | 5550 | 5720 | 0.246 | |||||||||||||||||||||||||||||||||||
4 | 4 | 15E | 36 CC MO ND | 5745 | 5825 | 0.49 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
5 | 1 | 15C | CC MO | 2412.00000000 | 2462.00000000 | 3.8950000 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
6 | 1 | 15E | CC MO ND | 5180 | 5240 | 0.0741 | |||||||||||||||||||||||||||||||||||
6 | 2 | 15E | CC MO ND | 5260 | 5320 | 0.2188 | |||||||||||||||||||||||||||||||||||
6 | 3 | 15E | CC MO ND | 5550 | 5720 | 0.2455 | |||||||||||||||||||||||||||||||||||
6 | 4 | 15E | CC MO ND | 5745 | 5825 | 0.7943 |
some individual PII (Personally Identifiable Information) available on the public forms may be redacted, original source may include additional details
This product uses the FCC Data API but is not endorsed or certified by the FCC