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WARNING:pdfminer.pdfpage:The PDF <_io.BufferedReader name='/Volumes/Scratch/Incoming/eg-scratch/6211893.pdf'> contains a metadata field indicating that it should not allow text extraction. Ignoring this field and proceeding. Use the check_extractable if you want to raise an error in this case USER GUIDE ePMP (802.11ac-ax) System Release 4.7 Reservation of Rights Cambium reserves the right to make changes to any products described herein to improve reliability, function, or design, and reserves the right to revise this document and to make changes from time to time in content hereof with no obligation to notify any person of revisions or changes. Cambium recommends reviewing the Cambium Networks website for the latest changes and updates to products. Cambium does not assume any liability arising out of the application or use of any product, software, or circuit described herein; neither does it convey license under its patent rights or the rights of others. It is possible that this publication may contain references to, or information about Cambium products
(machines and programs), programming, or services that are not announced in your country. Such references or information must not be construed to mean that Cambium intends to announce such Cambium products, programming, or services in your country. Copyrights This document, Cambium products, and 3rd Party software products described in this document may include or describe copyrighted Cambium and other 3rd Party supplied computer programs stored in semiconductor memories or other media. Laws in the United States and other countries preserve for Cambium, its licensors, and other 3rd Party supplied software certain exclusive rights for copyrighted material, including the exclusive right to copy, reproduce in any form, distribute and make derivative works of the copyrighted material. Accordingly, any copyrighted material of Cambium, its licensors, or the 3rd Party software supplied material contained in the Cambium products described in this document may not be copied, reproduced, reverse engineered, distributed, merged or modified in any manner without the express written permission of Cambium. Furthermore, the purchase of Cambium products shall not be deemed to grant either directly or by implication, estoppel, or otherwise, any license under the copyrights, patents or patent applications of Cambium or other 3rd Party supplied software, except for the normal non-exclusive, royalty free license to use that arises by operation of law in the sale of a product. Restrictions Software and documentation are copyrighted materials. Making unauthorized copies is prohibited by law. No part of the software or documentation may be reproduced, transmitted, transcribed, stored in a retrieval system, or translated into any language or computer language, in any form or by any means, without prior written permission of Cambium. License Agreements The software described in this document is the property of Cambium and its licensors. It is furnished by express license agreement only and may be used only in accordance with the terms of such an agreement. High Risk Materials Cambium and its supplier(s) specifically disclaim any express or implied warranty of fitness for any high-
risk activities or uses of its products including, but not limited to, the operation of nuclear facilities, aircraft navigation or aircraft communication systems, air traffic control, life support, or weapons systems
(High Risk Use). This product is not restricted in the EU. Any High Risk is unauthorized, is made at your own risk and you shall be responsible for any and all losses, damage or claims arising out of any High-Risk Use. 2022 Cambium Networks Limited. All rights reserved pmp-2461_001v022 November 2022 Contents Contents About This User Guide Problems and warranty Reporting problems Repair and service Warranty Security advice Precautionary statements Warning Federal Communication Commission Interference Statement Attention Note Caring for the environment In EU countries In non-EU countries Chapter 1: Product Description Overview of ePMP Purpose ePMP Portfolio ePMP 3000 ePMP 3000L ePMP MP3000 MicroPoP ePMP 4500 ePMP 4600 ePMP 5/6GHz 4 x 4 sector antenna Force 300-25 Force 300-19 Force 300-19R Force 300-16 Contents 3 14 14 14 14 14 15 15 15 15 16 16 17 17 17 18 18 18 18 20 21 21 22 24 24 25 26 28 3 Force 300-13 Force 300-13L Force 300 CSM Force 300 CSML Force 425 Force 400C Force 4600C ePMP 5/6GHz 2 x 2 dish antenna Force 4525 Force 4525L Force 4625 Typical installation equipment Wireless operation MU-MIMO MIMO Smart beamforming (ePMP 2000/3000 series) Smart antenna key advantages Time-division duplexing OFDM and channel bandwidth Adaptive modulation Radar avoidance Encryption Country codes Further reading on the wireless operation System management Management agent Webserver SNMP Network Time Protocol (NTP) Software upgrade Contents 29 30 30 32 32 33 33 34 34 35 35 36 37 37 37 37 38 38 38 39 39 39 39 40 40 40 41 41 41 41 4 Further reading on system management Chapter 2: System Hardware Site Planning Site installation Grounding and lightning protection Lightning protection zones ePMP 3000 Access Point ePMP 3000 Access Point description ePMP 3000 Access Point part numbers ePMP 3000 Access Point mounting bracket ePMP 3000 Access Point interfaces ePMP 3000 Access Point specifications ePMP 3000 Access Point heater ePMP 3000 Access Point wind loading ePMP 3000 Access Point software packages ePMP 3000L Access Point ePMP 3000L Access Point description ePMP 3000L Access Point part numbers ePMP 3000L Access Point mounting bracket ePMP 3000L Access Point interfaces ePMP 3000L Access Point specifications ePMP 3000L Access Point heater ePMP 3000L Access Point wind loading ePMP 3000L Access Point software packages ePMP 4500 Access Point ePMP 4500 Access Point description ePMP 4500 Access Point part numbers ePMP 4500 Access Point mounting bracket ePMP 4500 Access Point interfaces ePMP 4500 Access Point specifications Contents 42 43 44 44 44 46 47 48 48 49 50 50 51 51 52 52 53 53 54 55 55 56 56 57 58 58 58 60 60 60 5 ePMP 4500 Access Point heater ePMP 4500 Access Point wind loading ePMP 4500 Access Point software packages ePMP 4600 Access Point ePMP 4600 Access Point description ePMP 4600 Access Point part numbers ePMP 4600 Access Point mounting bracket ePMP 4600 Access Point interfaces ePMP 4600 Access Point specifications ePMP 4600 Access Point heater ePMP 4600 Access Point wind loading ePMP 4600 Access Point software packages ePMP 5/6GHz 4 x 4 sector antenna Force 300-25 Force 300-25 integrated description Force 300-25 part numbers Force 300-25 mounting bracket Force 300-25 interfaces Force 300-25 specifications Force 300-25 heater Force 300-25 wind loading Force 300-25 software packages Force 300-25L Force 300-25L integrated description Force 300-25L part numbers Force 300-25L interfaces Force 300-25L specifications Force 300-25L heater Force 300-25L wind loading Force 300-25L software packages Contents 61 62 63 63 63 64 64 64 65 65 66 67 67 67 68 68 69 70 70 71 71 72 72 72 73 75 75 76 76 77 6 Force 300-19 Force 300-19 integrated description Force 300-19 part numbers Force 300-19 mounting bracket Force 300-19 interfaces Force 300-19 specifications Force 300-19 heater Force 300-19 wind loading Force 300-19 software packages Force 300-19R Force 300-19R integrated description Force 300-19R part numbers Force 300-19R mounting bracket Force 300-19R interfaces Force 300-19R specifications Force 300-19R heater Force 300-19R wind loading Force 300-19R software packages Force 300-16 Force 300-16 integrated description Force 300-16 part numbers Force 300-16 interfaces Force 300-16 specifications Force 300-16 heater Force 300-16 wind loading Force 300-16 software packages Force 300-13 Force 300-13 integrated description Force 300-13 part numbers Force 300-13 interfaces Contents 77 77 78 79 79 80 80 81 82 82 82 82 84 84 84 85 85 86 86 86 87 88 88 89 89 90 90 91 91 92 7 Force 300-13 specifications Force 300-13 heater Force 300-13 wind loading Force 300-13 software packages Force 300-13L Force 300-13L integrated description Force 300-13L part numbers Force 300-13L interfaces Force 300-13L specifications Force 300-13L wind loading Force 300-13L LEDs Force 300-13L software packages Force 300 CSM Force 300 CSM Connectorized Subscriber Module description Force 300 CSM part numbers Force 300 CSM interfaces Force 300 CSM specifications Force 300 CSM heater Force 300 CSM wind loading Force 300 CSM software packages Force 300 CSML Force 300 CSML description Force 300 CSML part numbers Force 300 CSML interfaces Force 300 CSML mounting bracket Force 300 CSML specifications Force 300 CSML wind loading Force 300 CSML LEDs Force 300 CSML software packages ePMP MP3000 MicroPoP Contents 93 93 94 94 95 95 95 97 97 98 98 99 99 99 99 101 101 102 102 103 103 103 104 105 105 106 106 107 107 107 8 ePMP MP 3000 integrated description ePMP MP 3000 part numbers ePMP MP 3000 interfaces ePMP MP 3000 specifications ePMP MP 3000 heater ePMP MP 3000 wind loading ePMP MP 3000 software packages Force 425 Force 425 integrated description Force 425 part numbers Force 425 mounting bracket with Range Extender Force 425 interfaces Force 425 specifications Force 425 heater Force 425 wind loading Force 425 software packages Force 400C Force 400C integrated description Force 400C part numbers Force 400C interfaces Force 400C specifications Force 400C heater Force 400C wind loading Force 400C software packages Force 4600C Force 4600C integrated description Force 4600C part numbers Force 4600C interfaces Force 4600C specifications Force 4600C heater Contents 108 108 109 110 110 111 112 112 112 112 114 114 114 115 115 116 116 116 117 118 118 119 119 120 120 120 121 121 121 122 9 Force 4600C wind loading Force 4600C software packages ePMP 5/6GHz 2 x 2 dish antenna Force 4525 Force 4525 integrated description Force 4525 part numbers Force 4525 interfaces Force 4525 specifications Force 4525 heater Force 4525 wind loading Force 4525 software packages Force 4525L Force 4525L integrated description Force 4525L part numbers Force 4525L interfaces Force 4525L specifications Force 4525L heater Force 4525L wind loading Force 4525L software packages Force 4625 Force 4625 integrated description Force 4625 part numbers Force 4625 interfaces Force 4625 specifications Force 4625 heater Force 4625 wind loading Force 4625 software packages Power supply Power supply description Power supply part numbers Contents 122 123 123 123 124 124 125 125 126 126 127 127 128 128 129 129 130 130 131 131 131 132 132 132 133 133 134 134 134 135 10 Power supply interfaces Power supply specifications Power supply location considerations Ethernet cabling Ethernet standards and cable lengths Outdoor Cat5e cable Surge suppression unit Gigabit Ethernet surge suppressor cnPulse sync generator Chapter 3: System Planning Radio spectrum planning General wireless specifications Regulatory limits Conforming to the limits Available spectrum Channel bandwidth Link planning Range and obstacles Path loss Adaptive modulation Data network planning Ethernet interfaces Management VLAN Quality of service for bridged Ethernet traffic Chapter 4: Using the Device Management Interface Preparing for configuration Safety precautions Regulatory compliance Connecting to the unit Configuring the management PC Contents 135 136 137 137 137 138 138 139 140 141 141 141 142 143 143 143 143 143 143 144 144 144 145 145 146 146 146 146 146 147 11 Connecting to the PC and powering up Using the web interface Logging into the web interface Using the installation wizard Access Point Step 1: Main system parameters Step 2: Radio parameters Step 3: Network parameters Step 4: Security parameters Using the installation wizard Subscriber Module Step 1: Main system parameters Step 2: Radio parameters Step 3: Network parameters Installation wizard step 4 Security parameters Using the menu options Status page Installation page Configuration menu Monitor menu Tools menu Chapter 5: Operation and Troubleshooting General Planning for troubleshooting Upgrading device software Testing hardware Checking the power supply LED Power LED is OFF Ethernet LED is OFF Troubleshooting the radio link The module has lost or does not establish radio connectivity Module exhibiting frequent boots or disconnects Link is unreliable or does not achieve the data rates required Contents 147 148 148 149 149 150 151 152 153 153 154 155 156 157 158 160 161 198 215 228 228 229 229 229 229 230 231 231 232 232 12 Resetting ePMP to factory defaults by power cycling Glossary Cambium Networks 232 234 236 Contents 13 About This User Guide This guide describes the planning, installation, configuration, and operation of the Cambium ePMP Series of point-to-multipoint and point-to-point wireless Ethernet systems. It is intended for use by the system designer, system installer, and system administrator. For radio network design, see:
l Product Description l System Hardware l Site Planning l Legal and Reference Information For system configuration, monitoring, and fault finding, see:
l Using the Device Management Interface Problems and warranty Reporting problems At Cambium Networks, we know what it takes to keep a growing network running optimally. We provide multiple layers of support including training, online documentation, technical support, information-
sharing with an experienced community of users, software downloads, warranty services, and repair. Through the Cambium Support Center portal at https://support.cambiumnetworks.com/ you can:
l Submit support requests l Submit RMA request l View support global contact numbers Additional information including field service bulletins, license key information, warranty details, security advisories, Cambium Care program descriptions, regional codes for PTP solutions, and compliance requirements can be viewed at https://www.cambiumnetworks.com/support/. Repair and service If unit failure is suspected, obtain details of the Return Material Authorization (RMA) process from the support website. Warranty For products shipped after October 1st, 2018 Cambiums standard hardware warranty is for three (3) years from the date of shipment from Cambium or a Cambium distributor. Cambium warrants that hardware will conform to the relevant published specifications and will be free from material defects in material and workmanship under normal use and service. Cambium shall within this time, at its own option, either repair or replace the defective product within thirty (30) days of receipt of the defective product. Repaired or replaced products will be subject to the original warranty period but not less than thirty (30) days. To register ePMP products or activate warranties, visit the support website. About This User Guide 14 For warranty assistance, contact the reseller or distributor. Attention Do not open the radio housing for repair or diagnostics; there are no serviceable parts within the housing. Portions of Cambium equipment may be damaged from exposure to electrostatic discharge. Use precautions to prevent damage. Security advice Cambium Networks systems and equipment provide security parameters that can be configured by the operator based on their particular operating environment. Cambium recommends setting and using these parameters following industry-recognized security practices. Security aspects to be considered are protecting the confidentiality, integrity, and availability of information and assets. Assets include the ability to communicate, information about the nature of the communications, and information about the parties involved. In certain instances Cambium makes specific recommendations regarding security practices, however, the implementation of these recommendations and final responsibility for the security of the system lies with the operator of the system. Cambium Networks ePMP equipment is shipped with default web management interface login credentials. It is highly recommended that these usernames and passwords are modified before system installation. Precautionary statements The following describes how precautionary statements are used in this document. Warning Precautionary statements with the Warning tag precede instructions that contain potentially hazardous situations. Warnings are used to alert the reader to possible hazards that could cause loss of life or physical injury. A warning has the following format:
Warning Text and consequence for not following the instructions in the warning. Federal Communication Commission Interference Statement 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 this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one of the following measures:
About This User Guide 15 l Reorient or relocate the receiving antenna. l Increase the separation between the equipment and receiver. l Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. l Consult the dealer or an experienced radio/TV technician for help. Caution Any changes or modifications not expressly approved by the party responsible for compliance could void the users authority to operate this equipment. This device complies with Part 15 of the FCC 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. IMPORTANT NOTE FCC Radiation Exposure Statement This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with minimum distance 20 cm between the radiator and your body. Attention Precautionary statements with the Attention tag precede instructions that are used when there is a possibility of damage to systems, software, or individual items of equipment within a system. However, this damage presents no danger to personnel. An attention statement has the following format:
Attention Text and consequence for not following the instructions. Note Precautionary statements with the Note tag indicate the possibility of an undesirable situation or provide additional information to help the reader understand a topic or concept. A note has the following format:
Note Text. About This User Guide 16 Caring for the environment The following information describes national or regional requirements for the disposal of Cambium Networks supplied equipment and for the approved disposal of surplus packaging. In EU countries The following information is provided to enable regulatory compliance with the European Union (EU) directives identified and any amendments made to these directives when using Cambium equipment in EU countries. Disposal of Cambium equipment European Union (EU) Directive 2002/96/EC Waste Electrical and Electronic Equipment (WEEE). Do not dispose of Cambium equipment in landfill sites. For disposal instructions, see https://support.cambiumnetworks.com Disposal of surplus packaging Do not dispose of surplus packaging in landfill sites. In the EU, it is the individual recipients responsibility to ensure that packaging materials are collected and recycled according to the requirements of EU environmental law. In non-EU countries In non-EU countries, dispose of Cambium equipment and all surplus packaging in accordance with national and regional regulations. About This User Guide 17 Chapter 1: Product Description This chapter provides a high-level description of the ePMP product. It describes the function of the product, the main product variants, and the typical installation. It also describes the main hardware components. The following topics are described in this chapter:
l The key features, typical uses, product variants, and components of the ePMP are explained in the Overview of ePMP. l How the ePMP wireless link is operated, including modulation modes, power control, and security is described under Wireless operation. l The ePMP management system, including the web interface, installation, configuration, alerts, and upgrades is described in System management. Overview of ePMP This section introduces the key features, typical uses, product variants, and components of the ePMP portfolio as a whole (802.11n and 802.11ac products). Purpose ePMP Portfolio Cambium ePMP Series products are designed for Ethernet bridging over point-to-multipoint and point-
to-point microwave links in the unlicensed 2.4 GHz, 2.5 GHz (Brazil only), 5 GHz, and 6 GHz bands. Users must ensure that the ePMP Series complies with local operating regulations. ePMP devices support point-to-point microwave links in the unlicensed 5 GHz and 6 GHz bands. The ePMP Series acts as a transparent bridge between two segments of the operator and customers networks. In this sense, it can be treated as a virtual wired connection between the Access Point (AP) and the Subscriber Module (SM). The ePMP series forwards 802.3 Ethernet packets destined for the other part of the network and filters packets it does not need to forward and can deliver unicast data to unknown destinations as broadcast, similar to a switch functionality. ePMP 3000 The ePMP 3000 is a rugged high-capacity outdoor point-to-multipoint or point-to-point link wireless device in the unlicensed 5 GHz frequency bands with a maximum UDP sector throughput of up to 1+
Gbps (when operating with 80 MHz channel bandwidth). l l It is capable of operating in Line-of-Sight (LoS) and near-LoS conditions and supports Quality of Service (QoS) for traffic prioritization. It is available as a connectorized unit for use with a separate 4x4 MU-MIMO Sector/Dual-Horn/Omni antenna and optional Smart Antenna (for uplink beam steering). l ePMP 3000 supports maximum information rate (MIR) further allowing the operator to manage traffic profiles for end customers. l ePMP 3000 provides Dynamic Frequency Selection (DFS) for North America (FCC) and supports additional DFS tuning balances detection of actual DFS signals vs false detection. Chapter 1: Product Description 18 l ePMP 3000 supports backward and forward compatibility with ePMP 802.11n devices to provide an immediate sector upgrade to 802.11ac Wave 2 performance, and also to support future upgrades of networks operating ePMP 1000/2000 APs. l ePMP 3000 is based on highly integrated wireless semiconductor components designed to meet the IEEE 802.11ac standard, however, the ePMP 3000 device has a proprietary air interface for the main point-to-multipoint or point-to-point link. l ePMP 3000 is powered by standard power-over-Ethernet to a 1000BASE-T port. l Management of the unit is conducted via the same interface as the bridged traffic (in-band Management). An overview of ePMP 3000 is shown in Figure 1. Figure 1: ePMP3000 A summary of the main ePMP 3000 characteristics is listed under Table 1. Table 1 Main characteristics of the ePMP 3000 Series Characteristic Value Topology PMP or PTP Wireless link condition LoS, near LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 10 MHz*, 20 MHz, 40 MHz, 80 MHz Data rate Up to 1+ Gbps Sector Throughput Chapter 1: Product Description 19
* The 10 MHz Channel Bandwidth is only supported with Force 300-19R SM. ePMP 3000L The ePMP 3000L is the third-generation Access Point (AP) that carries on the interference tolerance mechanisms with an emphasis on high-performance in low-density point to multipoint sectors. The ePMP 3000L is a 2x 2 MIMO connectorized AP that can support a wide variety of deployments including 90/120-degree sectors, narrow-sector horns, or even 360-degree Omni coverage. Also, the ePMP 3000L continues interference mitigation techniques with the support of TDD synchronization using GPS and the robust software from the ePMP product line. The ePMP 3000L system consists of the ePMP 3000L AP, an optional 2x2 sector antenna, and a wide variety of subscriber modules with varying form factors and link budgets. ePMP 3000 supports backward and forward compatibility with ePMP 802.11n devices to provide an immediate sector upgrade to 802.11ac Wave 2 performance, and also to support future upgrades of networks operating ePMP 1000/2000 APs. The ePMP 3000L system boasts a high packet per second performance, peak throughput of 600 Mbps, and supports subscriber modules with up to 600 Mbps of peak throughput. An over view of ePMP 3000L is shown in Figure 2 Figure 2: ePMP3000L A summary of the main ePMP 3000L characteristics are listed under Table 2. Table 2 Main characteristics of the ePMP 3000L Series Characteristic Value Topology PMP or PTP Chapter 1: Product Description 20 Characteristic Value Wireless link condition LoS, near LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 1+ Gbps Sector Throughput ePMP MP3000 MicroPoP The ePMP MP 3000 MicroPoP is an integrated AP designed to serve short-range, low-density applications. It uses 802.11ac 2x2 architecture and can interoperate with a Force 300 subscriber module. An overview of ePMP MP 3000 is shown in Figure 3. Figure 3: ePMPMP3000Integrated ePMP 4500 The ePMP 4500 is the third-generation Access Point (AP) that carries on the interference tolerance mechanisms with an emphasis on high-performance in low-density point to multipoint sectors. The ePMP 4500 is a 2x 2 MIMO connectorized AP that can support a wide variety of deployments including 90/120-
degree sectors, narrow-sector horns, or even 360-degree Omni coverage. Also, the ePMP 4500 continues interference mitigation techniques with the support of TDD synchronization using GPS and the robust software from the ePMP product line. The ePMP 4500 system consists of the ePMP 4500 AP, an optional 2x2 sector antenna, and a wide variety of subscriber modules with varying form factors and link budgets. ePMP 3000 supports backward and forward compatibility with ePMP 802.11n devices to provide an immediate sector upgrade to 802.11ac Wave 2 performance, and also to support future upgrades of networks operating ePMP 1000/2000 APs. The ePMP 4500 system boasts a high packet per second performance, peak throughput of 600 Mbps, and supports subscriber modules with up to 600 Mbps of peak throughput. Chapter 1: Product Description 21 An over view of ePMP 4500 is shown in Figure 4 Figure 4: ePMP4500 A summary of the main ePMP 4500 characteristics are listed under Table 2. Table 2 Main characteristics of theePMP 4500 Series Characteristic Value Topology PMP or PTP Wireless link condition LoS, near LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 1+ Gbps Sector Throughput ePMP 4600 The ePMP 4600 is the third-generation Access Point (AP) that carries on the interference tolerance mechanisms with an emphasis on high-performance in low-density point to multipoint sectors. The ePMP 4600 is a 4 x 4 MIMO connectorized AP that can support a wide variety of deployments including 90/120-degree sectors, narrow-sector horns, or even 360-degree Omni coverage. Also, the ePMP 4600 continues interference mitigation techniques with the support of TDD synchronization using GPS and the robust software from the ePMP product line. The ePMP 4600 system consists of the ePMP 4600 AP, an optional 4x4 sector antenna, and a wide variety of subscriber modules with varying form factors and link budgets. ePMP 4600 supports backward and forward compatibility with ePMP 802.11n devices to provide an immediate sector upgrade to 802.11ax 4 x 4 performance, and also to support future upgrades of networks operating ePMP 1000/2000 APs. Chapter 1: Product Description 22 The ePMP 4600 system boasts a high packet per second performance, peak throughput of 4.3 Gbps, and supports subscriber modules with up to 4.3 Gbps of peak throughput. An over view of ePMP 4600 is shown in Figure 5 Figure 5: ePMP4600 A summary of the main ePMP 4600 characteristics are listed under Table 2. Table 2 Main characteristics of theePMP 4600 Series Characteristic Topology Value PTP Wireless link condition LoS, near LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 1+ Gbps Sector Throughput Chapter 1: Product Description 23 ePMP 5/6GHz 4 x 4 sector antenna Figure 6: ePMP5/6GHz4x4sectorantenna Force 300-25 The Force 300-25 is a rugged high-capacity outdoor point-to-multipoint or point-to-point link wireless device in the unlicensed 5 GHz frequency bands with a maximum UDP throughput of 500+ Mbps (when operating with 80 MHz channel bandwidth). It is capable of operating in line-of-sight (LoS) and near-LoS conditions. Force 300-25 is available as an integrated unit with a dual-polarized 25 dBi narrow Beamwidth dish antenna. Force 300-25 is based on highly integrated wireless semiconductor components designed to meet the IEEE 802.11ac standard, however, the Force 300-25 device has a proprietary air interface for the main point-to-point link. Force 300-25 is powered by standard power-over-Ethernet to a 1000BASE-T port. Management of the unit is conducted via the same interface as the bridged traffic (in-band Management). An over view of Force 300-25 is shown in Figure 7 Chapter 1: Product Description 24 Figure 7: Force300-25 A summary of the main Force 300-25 characteristics are listed under Table 3. Table 3 Main characteristics of the Force 300-25 Series Characteristic Value Topology PMP, PTP Wireless link condition LoS, near LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 500+ Mbps Force 300-19 The Force 300-19 is a rugged high-capacity outdoor point-to-multipoint or point-to-point link wireless devices in the unlicensed 5 GHz frequency bands with a maximum UDP throughput of 500+ Mbps (when operating with 80 MHz channel bandwidth). The Force 300-19 is IP55 rated capable of operating in line-
of-sight (LoS) and near-LoS conditions. Management of the unit is conducted via the same interface as the bridged traffic (in-band Management). An over view of Force 300-19 is shown in Figure 8. Chapter 1: Product Description 25 Figure 8: Force300-19 A summary of the main Force 300-19 characteristics are listed under Table 4. Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Table 4 Main characteristics of the Force 300-19 Series Characteristic Value Topology PMP, PTP Wireless link condition LoS, near LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 500+ Mbps Force 300-19R The Force 300-19R is a rugged high-capacity outdoor point-to-multipoint or point-to-point link wireless device in the unlicensed 5 GHz frequency bands with a maximum UDP throughput of 600+ Mbps (when operating with 80 MHz channel bandwidth). The Force 300-19R is IP67 rated capable of operating in line-
of-sight (LoS) and near-LoS conditions. Force 300-19R is available as an integrated unit with a dual-
polarized 19dBi integrated flat-panel antenna. Force 300-19R is based on highly integrated wireless semiconductor components designed to meet the IEEE 802.11ac standard, however, the Force 300-19R device has a proprietary air interface for the main point-to-point link. Force 300-19R is powered by standard power-over-Ethernet to a 1000BASE-T port. Management of the unit is conducted via the same interface as the bridged traffic (in-band Management). An over view of Force 300-19R is shown in Figure 9 Chapter 1: Product Description 26 Figure 9: Force300-19R A summary of the main Force 300-19R characteristics is listed under Table 5. Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Table 5 Main characteristics of the Force 300-19R Series Characteristic Value Topology PMP, PTP Wireless link condition LoS, near LoS Scheduler Connectivity TDD Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 10/20/40/80 MHz Data rate Up to 500+ Mbps Environmental IP67 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-
tight. Temperature
-30C to +60C (-22F to 140F) Chapter 1: Product Description 27 Force 300-16 The Force 300-16 is a rugged high-capacity outdoor point-to-multipoint or point-to-point link wireless device in the unlicensed 5 GHz frequency bands with a maximum UDP throughput of 500+ Mbps (when operating with 80 MHz channel bandwidth). It is capable of operating in line-of-sight (LoS) and near-LoS conditions. Force 300-16 is available as an integrated unit with a dual-polarized 16 dBi integrated antenna. Force 300-16 is based on highly integrated wireless semiconductor components designed to meet the IEEE 802.11ac standard, however, the Force 300-16 device has a proprietary air interface for the main point-to-point link. Force 300-16 is powered by standard power-over-Ethernet to a 1000BASE-T port. Management of the unit is conducted via the same interface as the bridged traffic (in-band Management). An over view of Force 300-16 is shown in Figure 10. Figure 10: Force300-16 A summary of the main Force 300-16 characteristics is listed under Table 6 . Table 6 Main characteristics of the Force 300-16 Series Characteristic Value Topology PMP, PTP Wireless link condition LoS, near LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 500+ Mbps Chapter 1: Product Description 28 Force 300-13 The Force 300-13 is a rugged high-capacity outdoor Point-to-Multipoint or Point-to-Point link wireless device in the unlicensed 5 GHz frequency bands with a maximum UDP throughput of 500+ Mbps (when operating with 80 MHz channel bandwidth). It can operate in line-of-sight (LoS). Force 300-13 is available as an integrated unit with a dual-polarized 13 dBi flat-panel antenna. Force 300-13 is based on highly integrated wireless semiconductor components designed to meet the IEEE 802.11ac standard, however, the Force 300-13 device has a proprietary air interface for the main point-to-point link. Force 300-13 is powered by standard power-over-Ethernet to a 1000BASE-T port. Management of the unit is conducted via the same interface as the bridged traffic (in-band Management). An over view of Force 300-13 is shown in Figure 11 Figure 11: Force300-13 A summary of the main Force 300-13 characteristics are listed under Table 7. Table 7 Main characteristics of the Force 300-13 Series Characteristic Value Topology PMP, PTP Wireless link condition LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 500+ Mbps Chapter 1: Product Description 29 Force 300-13L The Force 300-13L is an affordable subscriber module in the ePMP Force 300 series. The Force 300-13L uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP 3000 and ePMP 3000L APs. It is also backward compatible with the ePMP 2000 using backward compatibility features. The Force 300-13L is powered by standard power-over-Ethernet to a 1000BASE-T port. An over view of Force 300-13L is shown in Figure 12 Figure 12: Force300-13L Note The ePMP Force 300-13L is available in EMEA, CALA, and APAC regions where type approved. It is NOT available in North America. A summary of the main Force 300-13L characteristics is listed under Table 8. Table 8 Main characteristics of the Force 300-13L Series Characteristic Value Topology PMP, PTP Wireless link condition LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 400+ Mbps Force 300 CSM The Force 300 CSM is an IP67 rugged high-capacity outdoor point-to-multipoint or point-to-point link wireless device in the unlicensed 5 GHz frequency bands with a maximum UDP throughput of 600+ Mbps
(when operating with 80 MHz channel bandwidth). It can operate in line-of-sight (LoS). Force 300 CMS is Chapter 1: Product Description 30 a Connectorized device with support for RF Element Twistport adaptors. The Force 300 CSM device is based on highly integrated wireless semiconductor components designed to meet the IEEE 802.11ac standard. Management of the unit is conducted via the same interface as the bridged traffic (in-band Management). An over view of Force 300 CSM is shown in Figure 13. Figure 13: Force300CSM A summary of the main Force 300 CSM characteristics are listed under Table 10 . Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be raintight. Table 10 Main characteristics of the Force 300 CSM Characteristic Value Topology PMP, PTP Wireless link condition LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 600+ Mbps Chapter 1: Product Description 31 Force 300 CSML The Force 300CSML is an affordable subscriber module in the ePMP Force 300 series. The Force 300 CSML uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP 3000 and ePMP 3000L APs. It is also backward compatible with the ePMP 2000 using backward compatibility features. The Force 300 CSML is powered by standard power-over-Ethernet to a 1000BASE-T port. An over view of Force 300 CSML is shown in Figure 14. Figure 14: Force300CSML Note The ePMP Force 300 CSML is available in EMEA, CALA, and APAC regions where type approved. It is NOT available in North America. A summary of the main Force 300 CSML characteristics is listed under Table 11. Table 11 Main characteristics of the Force 300 CSML Series Characteristic Value Topology PMP, PTP Wireless link condition LoS Scheduler TDD Connectivity Ethernet Operating frequencies Unlicensed bands, 5 GHz Channel Bandwidth 20 MHz, 40 MHz, 80 MHz Data rate Up to 400+ Mbps Force 425 The Force 425 device is a self-contained transceiver unit that houses bothradio and networking electronics. An overview of Force 425 is shown in Figure 15. Chapter 1: Product Description 32 Figure 15: Force425Integrated Force 400C The Force 400C device is a self-contained transceiver unit that houses both radio and networking electronics. An overview of Force 400C is shown in Figure 16. Figure 16: Force400CIntegrated Force 4600C The Force 4600C device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 4600C uses 802.11ax technology and supports MU-MIMO . The Force 4600C is powered by standard power-over-Ethernet to a 1000BASE-T port. An overview of Force 4600C is shown in Figure 17. Chapter 1: Product Description 33 Figure 17: Force4600CIntegrated ePMP 5/6GHz 2 x 2 dish antenna Figure 18: ePMP5/6GHz2x2dishantenna Force 4525 The Force 4525 device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 4525 uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP XXXX and ePMP XXXX APs. It is also backward compatible with the ePMP XXXX using backward compatibility features. The Force 4525 is powered by standard power-over-Ethernet to a 1000BASE-T port. An overview of Force 4525 is shown in Figure 19. Chapter 1: Product Description 34 Figure 19: Force4525Integrated Force 4525L The Force 4525L device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 4525L uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP XXXX and ePMP XXXX APs. It is also backward compatible with the ePMP XXXX using backward compatibility features. The Force 4525L is powered by standard power-over-Ethernet to a 1000BASE-T port. An overview of Force 4525L is shown in Figure 20. Figure 20: Force4525LIntegrated Force 4625 The Force 4625 device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 4625 uses 802.11ax technology and supports MU-MIMO and other features. The Force 4625 is powered by standard power-over-Ethernet to a 1000BASE-T port. Chapter 1: Product Description 35 An overview of Force 4625 is shown in Figure 21. Figure 21: Force4625Integrated Typical installation equipment The ePMP is a solution consisting of integrated outdoor units, indoor power supply units / LAN injectors, cabling, and surge suppression equipment. The main hardware components of an ePMP installation are as follows:
l ePMP 3000 Access Point: A connectorized outdoor transceiver unit containing all the radio, networking, and surge suppression electronics. l ePMP 3000L Access Point: A connectorized *IP67 outdoor transceiver unit containing all the radio, networking, and surge suppression electronics. l ePMP 3000/3000L Access Point Power Supply: An indoor power supply module providing Power-over-Ethernet (PoE) supply and 1000 / 100 Base-TX to the AP. l ePMP 3000/3000L Access Point Radio Cabling and Lightning Protection: Shielded Cat5e cables, grounding cables, surge suppressors, and connectors. l ePMP Smart Antenna and cabling (optional): For Smart Beamforming, dynamically creates a narrow, targeted beam to each subscriber l Force 300-25/Force 300-19/Force 300-19R/Force 300-16/Force 300-13/Force 300 CSM Radio:
Integrated outdoor transceiver units containing all the radio, networking, and surge suppression electronics. l Force 300-25/Force 300-19/Force 300-19R/Force 300-16/Force 300-13/Force 300 CSM Power Supply: An indoor power supply module providing Power-over-Ethernet (PoE) supply and 100/1000 BASE-T to the Force 300-25 device. l Force 300-25/Force 300-19/Force 300-19R/Force 300-16/Force 300-13/Force 300 CSM Radio Cabling and Lightning Protection: Shielded Cat5e cables, grounding cables, surge suppressors, and connectors. Chapter 1: Product Description 36 l ePMP 4x4 MU-MIMO Sector Antenna/ePMP 4x4 MU-MIMO Dual-Horn Antenna/ePMP 4x4 MU-
MIMO Omni Antenna: External Antennas for the ePMP 3000 AP. For more information about these components, including interfaces, specifications, and Cambium part numbers, see Chapter 2: System Hardware. Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Wireless operation This section describes how the ePMP wireless link is operated, including modulation modes, power control, and security. MU-MIMO The ePMP 3000 MU-MIMO AP is equipped with either a sector antenna array or a pseudo-Omni antenna. Antenna diversity allows simultaneous DL transmissions for two subscriber modules for MU-MIMO. As such, the ePMP 3000 APs DL throughput capacity is significantly increased vs. the ePMP 1000/2000 APs. This is a contrast to a traditional wireless system, where two subscribers cannot communicate on the same channel to the same AP at the same time without causing significant self-interference and degrading the overall wireless network performance. MIMO The Multiple-Input Multiple-Output (MIMO) technique protects against fading and increases the probability of a received decoded signal being usable. Smart beamforming (ePMP 2000/3000 series) Powered by Hypure technology, ePMP series APs feature Smart Beamforming. This powerful addition to your network creates narrow, targeted beams to each subscriber, rather than relying on a traditional wide beam, blocking out multiple sources of interference to keep performance high. The System learns the locations of each served Subscriber Module and forms a narrow beam towards the desired Subscriber Module while that radio is transmitting in the uplink. This reduces the gain on the uplink for on-channel interferers that are transmitting at an azimuth angle different than the Subscriber Module, delivering performance gains never seen before. Chapter 1: Product Description 37 Figure 22: Smartbeamforming Smart antenna key advantages l Eliminate Uplink Interference: Smart Beamforming delivers dramatic performance improvements when dealing with strong co-channel uplink interference, maximizing network performance. l Consistent Performance in High Interference: By mitigating significant sources of interference, packet loss and retransmissions are kept to a minimum, keeping your network applications working at their best. l l Improvement in Uplink and Downlink Performance: By eliminating packet loss and retransmissions resulting from co-channel uplink interference, TCP retransmissions are greatly reduced. Other applications also show significant performance benefits. Intelligent Filtering improves both receive and transmit performance. It protects the network from off-channel interferers with a filter that dynamically moves around the channel. On the transmit side, it protects the RF environment by reducing off-channel transmission noise. Time-division duplexing TDD cycle ePMP links operate using Time Division Duplexing (TDD). The links employ a TDD cycle in which the AP determines which Subscriber Modules may transmit and when based on the configured downlink/uplink ratio (duty cycle). Three fixed Downlink/Uplink frame ratios are available 75/25, 50/50, and 30/70. OFDM and channel bandwidth ePMP 3000 transmits using Orthogonal Frequency Division Multiplexing (OFDM). This wideband signal consists of many equally spaced sub-carriers. Although each subcarrier is modulated at a low rate using conventional modulation schemes, the resultant data rate from all the sub-carriers is high. The channel bandwidth of the OFDM signal is 20 MHz, 40 MHz, or 80 MHz, based on operator configuration. Each channel is offset in center frequency from its neighboring channel by 5MHz. Chapter 1: Product Description 38 Adaptive modulation ePMP 3000 can transport data over the wireless link using several different modulation modes ranging from 256-QAM to QPSK. For a given channel bandwidth and TDD frame structure, each modulation mode transports data at a fixed rate. Also, the receiver requires a given signal-to-noise ratio to successfully demodulate a given modulation mode. Although the more complex modulations such as 256-QAM will transport data at a much higher rate than the less complex modulation modes, the receiver requires a much higher signal-to-noise ratio. ePMP 3000 provides an adaptive modulation scheme where the receiver constantly monitors the quality of the received signal and notifies the far end of the link of the optimum modulation mode with which to transmit. In this way, optimum capacity is achieved at all times. Radar avoidance In regions where the protection of radars is part of the local regulations, ePMP must detect interference from radar-like systems and avoid co-channel operation with these systems. To meet this requirement, ePMP implements the following features:
l The equipment can only transmit on available channels, of which there are none at initial power-
up. The radar detection algorithm will always scan a usable channel for 60 seconds for radar interference before making the channel an available channel. l This compulsory channel scan will mean that there is at least 60 seconds service outage every time radar is detected, and that the installation time is extended by at least 60 seconds even if there is found to be no radar on the channel. There is a secondary requirement for bands requiring radar avoidance. Regulators have mandated that products provide a uniform loading of the spectrum across all devices. In general, this prevents operation with fixed frequency allocations. However:
l ETSI regulations do allow frequency planning of networks (as that has the same effect of spreading the load across the spectrum). l The FCC does allow channels to be avoided if there is actual interference on them. Note When operating in a region that requires DFS, ensure that the AP is configured with alternate frequencies and that the SM is configured to scan for these frequencies to avoid long outages. Encryption ePMP supports optional encryption for data transmitted over the wireless link. The encryption algorithm used is the Advanced Encryption Standard (AES) with a 128-bit key size. AES is a symmetric encryption algorithm approved by U.S. Government organizations (and others) to protect sensitive information. Country codes Some aspects of the wireless operation are controlled, enforced, or restricted according to a country code. ePMP country codes represent individual countries (for example Denmark) or regulatory regions
(for example FCC or ETSI). Country codes affect the following aspects of wireless operation:
Chapter 1: Product Description 39 l Maximum transmit power l Radar avoidance (future release) l Frequency range Attention To avoid possible enforcement action by the country regulator, always operate links in accordance with local regulations Further reading on the wireless operation For information on planning wireless operation, see:
l The regulatory restrictions that affect radio spectrum usages, such as frequency range and radar avoidance are described under Radio spectrum planning. l The factors to be taken into account when planning links such as range, path loss, and data throughput are described under Link planning. l The safety specifications against which the ePMP has been tested are listed under Compliance with safety standards . It also describes how to keep RF exposure within safe limits. l How ePMP complies with the radio regulations that are enforced in various countries is explained in Compliance with radio regulations. For more information on configuring and operating the wireless link, see:
l The configuration parameters of the ePMP devices are described under Using the menu options. l Post-installation procedures and troubleshooting tips are explained under Chapter 5: Operation and Troubleshooting. System management This section introduces the ePMP management system, including the web interface, installation, alerts, and upgrades, configuration, and management software. Management agent ePMP equipment is managed through an embedded management agent. Management workstations, network management systems, or PCs can be connected to this agent using the modules Ethernet port, SFP port, over the air (Subscriber Module connection via AP), or by using the device Wi-Fi management interface. The management agent supports the following interfaces:
l Hypertext Transfer Protocol (HTTP) l Hypertext Transfer Protocol Secure (HTTPs) l Simple Network Management Protocol (SNMP) l Network Time Protocol (NTP) l System logging (Syslog) Chapter 1: Product Description 40 l cnMaestro Cloud-based or On-premises Management System l Dynamic Host Configuration Protocol (DHCP) Webserver The ePMP management agent contains a web server. The web server supports access via the HTTP and HTTPs interfaces. Web-based management offers a convenient way to manage the ePMP equipment from a locally connected computer or from a network management workstation connected through a management network, without requiring any special management software. The web-based interfaces are the only interfaces supported for the installation of ePMP, and the majority of ePMP configuration management tasks. Identity-based user accounts When identity-based user accounts are configured, a security officer can define from one to four user accounts, each of which may have one of the four possible roles:
l ADMINISTRATOR (default username/password admin), who has full read and write permission. l INSTALLER (default username/password installer), who has permission to read and write parameters applicable to unit installation and monitoring. l HOME (default username/password home), who has permission only to access pertinent information for support purposes l READONLY (default username/password readonly), who has permission to only view the Monitor page. SNMP The management agent supports fault and performance management utilizing an SNMP interface. The management agent is compatible with SNMP v2c using one Management Information Base (MIB) file which is available for download from the Cambium Networks support site:
https://support.cambiumnetworks.com/files/epmp. Network Time Protocol (NTP) The clock supplies accurate date and time information to the system. It can be set to run with or without a connection to a network time server (NTP). It can be configured to display local time by setting the time zone and daylight saving on the Time web page. If an NTP server connection is available, the clock can be set to synchronize with the server time at regular intervals. ePMP devices may receive NTP data from a CMM module or an NTP server configured in the systems management network. The Time Zone option is configurable on the Configure > System page and may be used to offset the received NTP time to match the operators local time zone. Software upgrade Software upgrades may be issued via the radio web interface (Tools > Software Upgrade) or cnMaestro
(cloud.cambiumnetworks.com). For software upgrades, see https://support.cambiumnetworks.com/files/epmp. Chapter 1: Product Description 41 Further reading on system management For more information on system management, see Operation and Troubleshooting. Chapter 1: Product Description 42 Chapter 2: System Hardware This chapter describes the site planning and hardware components of an ePMP link. The following topics are described in this chapter:
l Factors to be considered when planning the proposed network is described under Site planning. l The ePMP 3000 Access Point hardware, part numbers, mounting equipment, and specifications are described under ePMP 3000 Access Point. l The ePMP 3000L Access Point hardware, part numbers, mounting equipment, and specifications are described under ePMP 3000L Access Point. l The ePMP 4500 Access Point hardware, part numbers, mounting equipment, and specifications are described under ePMP 4500 Access Point. l The ePMP 4600 Access Point hardware, part numbers, mounting equipment, and specifications are described under ePMP 4600 Access Point. l The ePMP 6GHz 4 x 4 sector antenna hardware, part numbers, mounting equipment, and specifications are described under ePMP 6GHz 4 x 4 sector antenna. l The ePMP 6GHz 2 x 2 dish antenna hardware, part numbers, mounting equipment, and specifications are described under ePMP 6GHz 2 x 2 dish antenna. l The Force 300-25 module hardware, part numbers, mounting equipment, and specifications are described under Force 300-25 . l The Force 300-25L module hardware, part numbers, mounting equipment, and specifications are described under Force 300-25L. l The Force 300-19 module hardware, part numbers, mounting equipment, and specifications are described under Force 300-19. l The Force 300-19R module hardware, part numbers, mounting equipment, and specifications are described under Force 300-19R . l The Force 300-16 module hardware, part numbers, mounting equipment, and specifications are described under Force 300-16. l The Force 300-13 module hardware, part numbers, mounting equipment, and specifications are described under Force 300-13 . l The Force 300-13L module hardware, part numbers, mounting equipment, and specifications are described under Force 300-13L . l The Force 300 CSM module hardware, part numbers, mounting equipment, and specifications are described under Force 300 CSM . l The Force 300 CSML module hardware, part numbers, mounting equipment, and specifications are described under Force 300 CSML. l The ePMP MP 3000 MicroPOP module hardware, part numbers, mounting equipment, and specifications are described under ePMP MP3000 MicroPoP. Chapter 2: System Hardware 43 l The Force 425 module hardware, integrated description, part numbers, mounting equipment, and specifications are described under Force 425. l The Force 400C module hardware, integrated description, part numbers, mounting equipment, and specifications are described under Force 400C. l The Force 4600C module hardware, integrated description, part numbers, mounting equipment, and specifications are described under Force 4600C. l The Force 4525 module hardware, integrated description, part numbers, mounting equipment, and specifications are described under Force 4525. l The Force 4525L module hardware, integrated description, part numbers, mounting equipment, and specifications are described under Force 4525L. l The Force 4625 module hardware, integrated description, part numbers, mounting equipment, and specifications are described under Force 4625. l The power supply hardware, part numbers, and specifications are described under Power supply. l Cable standards and lengths are described under Ethernet cabling. l Surge suppression requirements and recommendations are described under the Surge suppression unit. l GPS synchronization generation information are described under the cnPulse sync generator. Site Planning Conduct a site survey to ensure that the proposed sites meet the requirements defined in this section. Site installation An ePMP site typically consists of a high supporting structure such as a mast, tower, or building for the devices. Find a location for the device that meets the following requirements:
l The equipment is high enough to achieve the best radio path. l People can be kept a safe distance away from the equipment when it is radiating. The safe separation distances are defined in Calculated distances and power compliance margins. l The equipment is lower than the top of the supporting structure (tower, mast, or building) or its lightning air terminal. l There is one Ethernet interface, a copper Cat5e connection from the device to the power supply, and network terminating equipment. Grounding and lightning protection Structures, equipment, and people must be protected against power surges (typically caused by lightning) by conducting the surge current to the ground via a separate preferential solid path. The actual degree of protection required depends on local conditions and applicable local regulations. To adequately protect an ePMP installation, both ground bonding and transient voltage surge suppression are required. Chapter 2: System Hardware 44 Warning Electro-magnetic discharge (lightning) damage is not covered under warranty. The recommendations in this guide, when followed correctly, give the user the best protection from the harmful effects of EMD. However, 100% protection is neither implied nor possible. Details of lightning protection methods and requirements can be found in the international standards IEC 61024-1 and IEC 61312-1, the U.S. National Electric Code ANSI/NFPA No. 70-1984, or section 54 of the Canadian Electric Code. Note International and national standards take precedence over the requirements in this guide. Figure 23: AccessPointinstallationdiagram Chapter 2: System Hardware 45 Figure 24: Subscriber/Point-to-Pointinstallationdiagram Lightning protection zones Use the rolling sphere method (Figure 25) to determine where it is safe to mount equipment. An imaginary sphere, typically 50 meters in radius, is rolled over the structure. Where the sphere rests against the ground and a strike termination device (such as a finial or ground bar), all the space under the sphere is considered to be in the zone of protection (Zone B). Similarly, where the sphere rests on two finials, the space under the sphere is considered to be in the zone of protection. Chapter 2: System Hardware 46 Figure 25: Rollingspheremethodtodeterminethelightningprotectionzones Assess locations on masts, towers, and buildings to determine if the location is in Zone A or Zone B:
l Zone A: In this zone a direct lightning strike is possible. Do not mount equipment in this zone. l Zone B: In this zone, direct EMD (lightning) effects are still possible, but mounting in this zone significantly reduces the possibility of a direct strike. Mount equipment in this zone. Warning Do not mount equipment in Zone A which can put the equipment, structures, and life at risk. ePMP 3000 Access Point For details of the ePMP 3000 Access Point hardware, see:
l ePMP 3000 Access Point description l ePMP 3000 Access Point part numbers l ePMP 3000 Access Point mounting bracket l ePMP 3000 Access Point interfaces l ePMP 3000 Access Point specifications l ePMP 3000 Access Point heater l ePMP 3000 Access Point wind loading l ePMP 3000 Access Point software packages Chapter 2: System Hardware 47 ePMP 3000 Access Point description The ePMP 3000 AP is a self-contained transceiver unit that houses both radio and networking electronics. It is available as a connectorized unit for use with a separate 4x4 MU-MIMO Sector/Dual-Horn/Omni antenna and an optional Smart Antenna (for uplink beam steering). An overview of ePMP 3000 is shown in Figure 26. Figure 26: ePMP3000AccessPoint ePMP 3000 Access Point part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 12 and Table 13 includes the following items:
l One connectorized unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 12 ePMP 3000 Access Point part numbers Cambium description Cambium part number ePMP 3000 5 GHz Access Point Radio (FCC) (US cord) C058910A102A ePMP 3000 5 GHz Access Point Radio (IC) (Canada/US cord) C050910A104A ePMP 3000 5 GHz Access Point Radio (EU) (EU cord) C050910A203A ePMP 3000 5 GHz Access Point Radio (EU) (UK cord) C050910A303A ePMP 3000 5 GHz Access Point Radio (ROW) (no cord) C050910A001A ePMP 3000 5 GHz Access Point Radio (ROW) (US cord) C050910A101A ePMP 3000 5 GHz Access Point Radio (ROW) (EU cord) C050910A201A ePMP 3000 5 GHz Access Point Radio (ROW) (UK cord) C050910A301A ePMP 3000 5 GHz Access Point Radio (ROW) (India cord) C050910A401A ePMP 3000 5GHz Access Point Radio (India) (India Cord) C050910A402A Chapter 2: System Hardware 48 Cambium description Cambium part number ePMP 3000 5 GHz Access Point Radio (ROW) (China cord) C050910A501A ePMP 3000 5 GHz Access Point Radio (ROW) (Brazil cord) C050910A601A ePMP 3000 5 GHz Access Point Radio (ROW) (Argentina cord) C050910A701A ePMP 3000 5 GHz Access Point Radio (ROW) (ANZ cord) C050910A801A ePMP 3000 5 GHz Access Point Radio (ROW) (South Africa cord) C050910A901A ePMP 3000 5 GHz Access Point Radio (ROW) (No PSU) C050910AZ01A ePMP 4x4 MU-MIMO Sector Antenna (for ePMP3000AP) C050910D301A ePMP 4x4 MU-MIMO Dual-Horn Antenna (for ePMP3000AP) C050900D025A ePMP 4x4 MU-MIMO Omni Antenna (for ePMP3000AP) n KP-5QSOMNI-13 (available directly from KP Performance) Table 13 ePMP 3000 accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 ePMP 3000 Access Point mounting bracket The ePMP 3000 AP module is designed to be mounted with a sector antenna or pole-mounted using the mounting bracket provided in the box with the radio. An overview of ePMP 3000 AP mounting bracket is shown in Figure 27. Chapter 2: System Hardware 49 Figure 27: ePMP3000AccessPointmodulemountingbracket ePMP 3000 Access Point interfaces The Ethernet port is located at the bottom of the unit. This interface is described in Table 14. Table 14 ePMP 3000 Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE) Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings 100/1000BASE-T Ethernet Data SFP SFP Optical or Copper Gigabit Ethernet Management and/or data ePMP 3000 Access Point specifications The ePMP 3000 connectorized module conforms to the specifications listed in Table 15 and Table 16. The connectorized module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Chapter 2: System Hardware 50 Table 15 ePMP 3000 Access Point physical specifications Category Specification Dimensions (Length x Width x Height) 22.2 cm x 12.4 cm x 4.5 cm (8.75 in x 4.9 in x 1.75 in) without brackets Weight 0.7 kg (1.5 lbs) without brackets Table 16 ePMP 3000 Access Point environmental specifications Category Specification Temperature
-30C (-22F) to +55C (131F) Wind loading 124 mph (200 kph) maximum. See ePMP 3000 Access Point wind loading for a full description. Humidity 95% condensing Environmental IP55 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. ePMP 3000 Access Point heater At startup, if the ePMP 3000 AP module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 17. Table 17 ePMP 3000 AP startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds ePMP 3000 Access Point wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 200kph
(124mph). Chapter 2: System Hardware 51 Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A V the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 18 and Table 19. Table 18 ePMP 3000 Access Point wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 40 50 60 ePMP 3000 AP with Sector Antenna 0.13 21.74 Kg 33.96 Kg 48.91 Kg Table 19 ePMP 3000 Access Point wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) ePMP 3000 AP with Sector Antenna 1.4 37.63 lb 58.80 lb 84.67 lb 80 100 120 ePMP 3000 Access Point software packages ePMP 3000 AP devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) ePMP 3000L Access Point For details of the ePMP 3000L Access Point hardware, see:
l ePMP 3000L Access Point description l ePMP 3000L Access Point part numbers l ePMP 3000L Access Point mounting bracket Chapter 2: System Hardware 52 l ePMP 3000L Access Point interfaces l ePMP 3000L Access Point specifications l ePMP 3000L Access Point heater l ePMP 3000L Access Point wind loading l ePMP 3000L Access Point software packages ePMP 3000L Access Point description The ePMP 3000L device is a self-contained transceiver unit that houses both radio and networking electronics. An overview of ePMP 3000L is shown in Figure 28. Figure 28: ePMP3000LAccessPoint ePMP 3000L Access Point part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 20-and Table 21 includes the following items:
l One connectorized unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 20 ePMP 3000L Access Point part numbers Cambium description Cambium part number ePMP 3000L 5 GHz Access Point Radio (FCC) (US cord) C058910A122A ePMP 3000L 5 GHz Access Point Radio (IC) (Canada/US cord) C050910A124A Chapter 2: System Hardware 53 Cambium description Cambium part number ePMP 3000L 5 GHz Access Point Radio (EU) (EU cord) C050910A223A ePMP 3000L 5 GHz Access Point Radio (EU) (UK cord) C050910A323A ePMP 3000L 5 GHz Access Point Radio (ROW) (no cord) C050910A021A ePMP 3000L 5 GHz Access Point Radio (ROW) (US cord) C050910A121A ePMP 3000L 5 GHz Access Point Radio (ROW) (EU cord) C050910A221A ePMP 3000L 5 GHz Access Point Radio (ROW) (UK cord) C050910A321A ePMP 3000L 5 GHz Access Point Radio (ROW) (India cord) C050910A421A ePMP 3000L 5GHz Access Point Radio (India) (India Cord) C050910A422A ePMP 3000L 5 GHz Access Point Radio (ROW) (China cord) C050910A521A ePMP 3000L 5 GHz Access Point Radio (ROW) (Brazil cord) C050910A621A ePMP 3000L 5 GHz Access Point Radio (ROW) (Argentina cord) C050910A721A ePMP 3000L 5 GHz Access Point Radio (ROW) (ANZ cord) C050910A821A ePMP 3000L 5 GHz Access Point Radio (ROW) (South Africa cord) C050910A921A ePMP 3000L 5 GHz Access Point Radio (ROW) (No PSU) C050910AZ21A Table 21 ePMP 3000L accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 ePMP 3000L Access Point mounting bracket The ePMP 3000L AP module is designed to be mounted with a sector antenna or pole-mounted using the mounting bracket provided in the box with the radio. An overview of ePMP 3000L Access Point mounting bracket is shown in Figure 29 Chapter 2: System Hardware 54 Figure 29: ePMP3000LAccessPointmodulemountingbracket ePMP 3000L Access Point interfaces The Ethernet port is located at the bottom of the unit. This interface is described in Table 22. Table 22 ePMP 3000 Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data SFP SFP Optical or Copper Gigabit Ethernet Management and/or data ePMP 3000L Access Point specifications The ePMP 3000L connectorized module conforms to the specifications listed in Table 23 and Table 24. The connectorized module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Chapter 2: System Hardware 55 Table 23 ePMP 3000L Access Point physical specifications Category Specification Dimensions (Length x Width x Height) 22.2 cm x 12.4 cm x 4.5 cm (8.75 in x 4.9 in x 1.75 in) without brackets Weight 0.7 kg (1.5 lbs) without brackets Table 24 ePMP 3000L Access Point environmental specifications Category Specification Temperature
-30C (-22F) to +55C (131F) Wind loading 124 mph (200 kph) maximum. See ePMP 3000 Access Point wind loading (Kg) for a full description. Humidity 95% condensing Environmental IP67. Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. ePMP 3000L Access Point heater At startup, if the ePMP 3000L AP module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 25. Table 25 ePMP 3000L Access Point startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds ePMP 3000L Access Point wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 200kph
(124mph). Chapter 2: System Hardware 56 Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A V the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 26 and Table 27. Table 26 ePMP 3000L Access Point wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 40 50 60 ePMP 3000L Access Point with Sector Antenna 0.13 21.74 Kg 33.96 48.91 Kg Kg Table 27 ePMP 3000L Access Point wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) ePMP 3000L Access Point with Sector Antenna 1.4 80 100 120 37.63 lb 58.80 lb 84.67 lb ePMP 3000L Access Point software packages ePMP 3000L AP devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Chapter 2: System Hardware 57 ePMP 4500 Access Point For details of the ePMP 4500 Access Point hardware, see:
l ePMP 4500 Access Point description l ePMP 4500 Access Point part numbers l ePMP 4500 Access Point mounting bracket l ePMP 4500 Access Point interfaces l ePMP 4500 Access Point specifications l ePMP 4500 Access Point heater l ePMP 4500 Access Point wind loading l ePMP 4500 Access Point software packages ePMP 4500 Access Point description The ePMP 4500 device is a self-contained transceiver unit that houses both radio and networking electronics. It is available with 8 X 8 MU-MIMO integrated antenna. An overview of ePMP 4500 is shown in Figure 30. Figure 30: ePMP4500AccessPoint ePMP 4500 Access Point part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 20 and Table 21 includes the following items:
l One connectorized unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Chapter 2: System Hardware 58 Table 20 ePMP 4500 Access Point part numbers Cambium description Cambium part number ePMP 4500 5 GHz Access Point Radio (FCC) (US cord) C058910A122A ePMP 4500 5 GHz Access Point Radio (IC) (Canada/US cord) C050910A124A ePMP 4500 5 GHz Access Point Radio (EU) (EU cord) C050910A223A ePMP 4500 5 GHz Access Point Radio (EU) (UK cord) C050910A323A ePMP 4500 5 GHz Access Point Radio (ROW) (no cord) C050910A021A ePMP 4500 5 GHz Access Point Radio (ROW) (US cord) C050910A121A ePMP 4500 5 GHz Access Point Radio (ROW) (EU cord) C050910A221A ePMP 4500 5 GHz Access Point Radio (ROW) (UK cord) C050910A321A ePMP 4500 5 GHz Access Point Radio (ROW) (India cord) C050910A421A ePMP 4500 5GHz Access Point Radio (India) (India Cord) C050910A422A ePMP 4500 5 GHz Access Point Radio (ROW) (China cord) C050910A521A ePMP 4500 5 GHz Access Point Radio (ROW) (Brazil cord) C050910A621A ePMP 4500 5 GHz Access Point Radio (ROW) (Argentina cord) C050910A721A ePMP 4500 5 GHz Access Point Radio (ROW) (ANZ cord) C050910A821A ePMP 4500 5 GHz Access Point Radio (ROW) (South Africa cord) C050910A921A ePMP 4500 5 GHz Access Point Radio (ROW) (No PSU) C050910AZ21A Table 21 ePMP 4500 accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 Chapter 2: System Hardware 59 ePMP 4500 Access Point mounting bracket The ePMP 4500 AP module is designed to be mounted with a sector antenna or pole-mounted using the mounting bracket provided in the box with the radio. An overview of ePMP 4500 AP mounting bracket is shown in Figure 31 Figure 31: ePMP4500AccessPointmodulemountingbracket ePMP 4500 Access Point interfaces The Ethernet port is located at the bottom of the unit. This interface is described in Table 22. Table 22 ePMP 4500 Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data SFP SFP Optical or Copper Gigabit Ethernet Management and/or data ePMP 4500 Access Point specifications The ePMP 4500 connectorized module conforms to the specifications listed in Table 23 and Table 24. Chapter 2: System Hardware 60 The connectorized module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 23 ePMP 4500 Access Point physical specifications Category Specification Dimensions (Length x Width x Height) 22.2 cm x 12.4 cm x 4.5 cm (8.75 in x 4.9 in x 1.75 in) without brackets Weight 12.5 kg (27.56 lbs) without brackets 14.66 kg (32.32 lbs) with brackets Table 24 ePMP 4500 Access Point environmental specifications Category Specification Temperature
-30C (-22F) to +55C (131F). Wind loading 124 mph (200 kph) maximum. See ePMP 4500 Access Point wind loading (Kg) for a full description. Humidity 95% condensing. Environmental IP67. Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. ePMP 4500 Access Point heater At startup, if the ePMP 4500 AP module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can begin the operation successfully. The units heater is only activated when the unit is powered ON and does not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), then the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 25. Table 25 ePMP 4500 Access Point startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Chapter 2: System Hardware 61 ePMP 4500 Access Point wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 200kph
(124mph). Wind blowing on the device subjects the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A V the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 26 and Table 27. Table 26 ePMP 4500 Access Point wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 40 50 60 ePMP 4500 Access Point with Sector Antenna 0.13 21.74 Kg 33.96 Kg 48.91 Kg Table 27 ePMP 4500 Access Point wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) ePMP 4500 Access Point with Sector Antenna 1.4 80 100 120 37.63 lb 58.80 lb 84.67 lb Chapter 2: System Hardware 62 ePMP 4500 Access Point software packages ePMP 4500 AP devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro.The software packages applicable to ePMP integrated radios are named:
l ePMP-AX-v5.x.x.img (or higher version number) ePMP 4600 Access Point For details of the ePMP 4600 Access Point hardware, see:
l ePMP 4600 Access Point description l ePMP 4600 Access Point part numbers l ePMP 4600 Access Point mounting bracket l ePMP 4600 Access Point interfaces l ePMP 4600 Access Point specifications l ePMP 4600 Access Point heater l ePMP 4600 Access Point wind loading l ePMP 4600 Access Point software packages ePMP 4600 Access Point description The ePMP 4600 device is a self-contained transceiver unit that houses both radio and networking electronics. It is available with 4 X 4 MU-MIMO connectorized antenna. An overview of ePMP 4600 is shown in Figure 32. Chapter 2: System Hardware 63 Figure 32: ePMP4600AccessPoint ePMP 4600 Access Point part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 20 and Table 21 includes the following items:
l One connectorized unit l One power supply 1000/100 BASE-TX LAN injector l One line cord ePMP 4600 Access Point mounting bracket The ePMP 4600 AP module is designed to be mounted with a sector antenna or pole-mounted using the mounting bracket provided in the box with the radio. An overview of ePMP 4600 AP mounting bracket is shown in Figure 33 Figure 33: ePMP4600AccessPointmodulemountingbracket ePMP 4600 Access Point interfaces The Ethernet port is located at the bottom of the unit. This interface is described in Table 22. Table 22 ePMP 4600 Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Note Chapter 2: System Hardware 64 Port name Connector Interface Description All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data SFP SFP Optical or Copper Gigabit Ethernet Management and/or data ePMP 4600 Access Point specifications The ePMP 4600 connectorized module conforms to the specifications listed in Table 23and Table 24. The connectorized module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 23 ePMP 4600 Access Point physical specifications Category Specification Dimensions (Length x Width x Height) 22.2 cm x 12.4 cm x 4.5 cm (8.75 in x 4.9 in x 1.75 in) without brackets Weight 12.5 kg (27.56 lbs) without brackets 14.66 kg (32.32 lbs) with brackets Table 24 ePMP 4600 Access Point environmental specifications Category Specification Temperature
-30C (-22F) to +55C (131F) Wind loading 124 mph (200 kph) maximum. See ePMP 4500 Access Point wind loading (Kg) for a full description Humidity 95% condensing Environmental IP67 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. ePMP 4600 Access Point heater At startup, if the ePMP 4600 AP module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated Chapter 2: System Hardware 65 when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 25. Table 25 ePMP 4600 Access Point startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds ePMP 4600 Access Point wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 200kph
(124mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A V the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 26 and Table 27. Table 26 ePMP 4600 Access Point wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 40 50 60 ePMP 4500 Access Point with Sector Antenna 0.13 21.74 Kg 33.96 48.91 Kg Kg Chapter 2: System Hardware 66 Table 27 ePMP 4600 Access Point wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) ePMP 4500 Access Point with Sector Antenna 1.4 80 100 120 37.63 lb 58.80 lb 84.67 lb ePMP 4600 Access Point software packages ePMP 4600 AP devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AX-v5.x.x.img (or higher version number) ePMP 5/6GHz 4 x 4 sector antenna Figure 34: ePMP5/6GHz4x4sectorantenna Force 300-25 For details of the Force 300-25 hardware, see:
l Force 300-25 integrated description l Force 300-25 part numbers l Force 300-25 mounting bracket l Force 300-25 interfaces l Force 300-25 interfaces l Force 300-25 heater Chapter 2: System Hardware 67 l Force 300-25 wind loading l Force 300-25 software packages Force 300-25 integrated description The Force 300-25 device is a self-contained transceiver unit that houses both radio and networking electronics. An overview of ePMP 3000 is shown in Figure 35. Figure 35: Force300-25Integrated Force 300-25 part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 28 and Table 29 includes the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 28 Force 300-25 part numbers Cambium description Cambium part number ePMP Force 300-25-25 5 GHz High Gain Radio (FCC) (US Cord) C058910C102A ePMP Force 300-25-25 5 GHz High Gain Radio (IC) (Canada/US Cord) C050910C104A ePMP Force 300-25-25 5 GHz High Gain Radio (EU) (EU Cord) C050910C203A ePMP Force 300-25-25 5 GHz High Gain Radio (EU) (UK Cord) C050910C303A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (no Cord) C050910C001A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (US Cord) C050910C101A Chapter 2: System Hardware 68 Cambium description Cambium part number ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (EU Cord) C050910C201A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (UK Cord) C050910C301A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (India Cord) C050910C401A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (China Cord) C050910C501A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (Brazil Cord) C050910C601A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (Argentina Cord) C050910C701A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (ANZ Cord) C050910C801A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (South Africa Cord) C050910C901A ePMP Force 300-25-25 5 GHz High Gain Radio (RoW) (No PSU) C050910CZ01A Table 29 Force 300-25 accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US Force 300-25 mounting bracket N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 The Force 300-25 module is designed to be pole-mounted using the mounting bracket provided in the box with the radio. An overview of Force 300-25 mounting bracket is shown in Figure 36. Chapter 2: System Hardware 69 Figure 36: Force300-25modulemountingbracket Force 300-25 interfaces The Ethernet port is located on the rear of the integrated unit. This interface is described in Table 30. Table 30 Force 300-25 Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data Force 300-25 specifications The Force 300-25 integrated module conforms to the specifications listed in Table 31 and Table 32. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 31 Force 300-25 physical specifications Category Specification Dimensions (Diameter x Depth) 47 cm x 31 cm (18.5 in x 12.2 in) Weight 2.4 kg (5.2 lbs) Table 32 Force 300-25 environmental specifications Category Specification Temperature
-30C (-22F) to +55C (131F) Wind loading 124 mph (200 kph) maximum. See Force 300-25 wind loading for a full description. Humidity 95% condensing Environmental IP55 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Chapter 2: System Hardware 70 Force 300-25 heater At startup, if the Force 300-25 module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 33 Table 33 Force 300-25 startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 300-25 wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 200kph
(124mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 34 and Table 35. Chapter 2: System Hardware 71 Table 34 Force 300-25 wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 40 50 60 Force 300-25 Integrated 0.15 25.08 Kg 39.2 Kg 56.43 Kg Table 35 Force 300-25 wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) Force 300-25 Integrated 1.61 43.28 lb 67.62 lb 97.37 lb 80 100 120 Force 300-25 software packages Force 300-25 devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Force 300-25L For details of the Force 300-25L hardware, see:
l Force 300 CSM Connectorized Subscriber Module description l Force 300-25L key features l Force 300-25L part numbers l Force 300-25L interfaces l Force 300-25L specifications l Force 300-25L heater l Force 300-25L wind loading l Force 300-25L software packages Force 300-25L integrated description The Force 300-25L is an integrated 802.11ac Wave2 based Subscriber Module with an integrated 25 dBi dish. The radio supports PTP and ePTP protocols and is compatible with PMP applications with ePMP 3000, ePMP 3000L, and ePMP 2000 APs. An overview of Force 300-25L is shown in Figure 37. Chapter 2: System Hardware 72 Figure 37: Force300-25L Force 300-25L key features n Supports up to 400 Mbps usable throughput n Frequency Range from 4.9 to 6.4 GHz n Up to 26 dBm Tx Power n Network management: HTTPS, SNMPv2c, SSH, cnMaestro n Channel Size: 20 / 40 / 80 MHz Force 300-25L part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 36 and Table 37 includes the following items:
l One unit l One Dish l One Fixed Mounting Bracket l One unit l Two Hose Clamps l One PoE injector l One Line Cord Note An Optional Tilt Mount Bracket is available separately (N000900L063A). Table 36 Force 300-25L part numbers Cambium description Cambium part number ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (no cord) C050910M071A Chapter 2: System Hardware 73 Cambium description Cambium part number ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (US cord) C050910M171A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (EU cord) C050910M271A ePMP 5 GHz Force 300-25L SM Bulk Packaging (EU) (EU cord) C050910M273A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (UK cord) C050910M371A ePMP 5 GHz Force 300-25L SM Bulk Packaging (EU) (UK cord) C050910M373A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (India cord) C050910M471A ePMP 5 GHz Force 300-25L SM Bulk Packaging (India) (India Cord) C050910M472A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (China cord) C050910M571A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (Brazil cord) C050910M671A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (Argentina cord) C050910M771A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (ANZ cord) C050910M871A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (South Africa cord) C050910CM71A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (No PSU) C050910MZ71A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (no cord) C050910C071A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (US cord) C050910C171A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (EU cord) C050910C271A ePMP 5 GHz Force 300-25L SM Bulk Packaging (EU) (EU cord) C050910C273A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (UK cord) C050910C371A ePMP 5 GHz Force 300-25L SM Bulk Packaging (EU) (UK cord) C050910C373A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (India cord) C050910C471A ePMP 5 GHz Force 300-25L SM Bulk Packaging (India) (India Cord) C050910C472A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (China cord) C050910C571A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (Brazil cord) C050910C671A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (Argentina cord) C050910C771A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (ANZ cord) C050910C871A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (South Africa cord) C050910C971A ePMP 5 GHz Force 300-25L SM Bulk Packaging (ROW) (No PSU) C050910CZ71A Table 37 Force 300-25L accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 Chapter 2: System Hardware 74 Cambium description Cambium part number CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US Force 300-25L interfaces The Ethernet port is located on the rear of the unit. Table 38 Force 300-25L rear interfaces N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). 100/1000BASE-T Ethernet Data Force 300-25L specifications The Force 300-25L integrated module conforms to the specifications listed in Table 39 and Table 40. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 39 Force 300-25L physical specifications Category Specification Dimensions (Diameter x Depth) TBDmm x TBDmm x TBDmm (TBDin x TBDin x TBDin) Weight Antenna TBD Integrated dish, 25 dBi, Pole Diameter Range 3.8 cm 6.4 cm (1.5 in 2.5 in) Power Consumption 12 W Maximum, 9 W Typical Input Voltage 30 V Passive PoE (14-30V DC input) Chapter 2: System Hardware 75 Table 40 Force 300-25L environmental specifications Category Specification Temperature
-30C to +55C (-22F to +122F) ambient op temp Wind Survival 200 km/hour (124 mi/hour) Environmental IP55 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Force 300-25L heater At start-up, if the Force 300-25L module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its start-up sequence. The effect on device startup time at various temperatures is defined in Table 41. Table 41 Force 300-25L startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 300-25L wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180kph
(124mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Chapter 2: System Hardware 76 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 42 and Table 43. Table 42 Force 300-25L wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 30 40 50 Force 300-25L Integrated 0.03 2.82 Kg 5.02 Kg 7.84 Kg Table 43 Force 300-25L wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) Force 300-25L 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Force 300-25L software packages Force 300-25L devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Force 300-19 For details of the Force 300-19 hardware, see:
l Force 300-19 integrated description l Force 300-19 part numbers l Force 300-19 mounting bracket l Force 300-19 interfaces l Force 300-19 specifications l Force 300-19 heater l Force 300-19 wind loading l Force 300-19 software packages Force 300-19 integrated description The Force 300-19 device is a self-contained transceiver unit that houses both radio and networking electronics.
(FCCID:Z8H89FT0048 | IC:109W-0048) Chapter 2: System Hardware 77 An overview of Force 300-19 is shown in Figure 38. Figure 38: Force300-19AccessPoint Force 300-19 part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 44 and Table 45 include the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 44 Force 300-19 part numbers Cambium description Cambium part number ePMP 5 GHz Force 300-19 SM (FCC) (US cord) C058900C801A ePMP 5 GHz Force 300-19 SM (IC) (Canada/US cord) C050900C801A ePMP 5 GHz Force 300-19 SM (EU) (EU cord) C050900C802A ePMP 5 GHz Force 300-19 SM (EU) (UK cord) C050900C803A ePMP 5 GHz Force 300-19 SM (ROW) (no cord) C050900C804A ePMP 5 GHz Force 300-19 SM (ROW) (US cord) C050900C805A ePMP 5 GHz Force 300-19 SM (ROW) (EU cord) C050900C806A ePMP 5 GHz Force 300-19 SM (ROW) (UK cord) C050900C807A ePMP 5 GHz Force 300-19 SM (ROW) (India cord) C050900C808A ePMP 5 GHz Force 300-19 SM (India) (India cord) C050900C809A ePMP 5 GHz Force 300-19 SM (ROW) (China cord) C050900C810A ePMP 5 GHz Force 300-19 SM (ROW) (Brazil cord) C050900C811A ePMP 5 GHz Force 300-19 SM (ROW) (Argentina cord) C050900C812A ePMP 5 GHz Force 300-19 SM (ROW) (ANZ cord) C050900C813A ePMP 5 GHz Force 300-19 SM (ROW) (South Africa cord) C050900C814A ePMP 5 GHz Force 300-19 SM (ROW) (No PSU) C050900C815A Chapter 2: System Hardware 78 Table 45 Force 300-19 accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US Force 300-19 mounting bracket N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 The Force 300-19 module is designed to be pole-mounted using the mounting bracket provided in the box with the radio. An overview of Force 300-19 mounting bracket is shown in Figure 39 Figure 39: Force300-19modulemountingbracket Force 300-19 interfaces The Ethernet port is located on the rear of the integrated unit. This interface is described in Table 46 Table 46 Force 300-19 Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Chapter 2: System Hardware 79 Port name Connector Interface Description Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data Force 300-19 specifications The Force 300-19 integrated module conforms to the specifications listed in Table 47and Table 48. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 47 Force 300-19 physical specifications Category Specification Dimensions 27.8 cm x 27.8 cm x 4.5cm (10.9 in x 10.9 in x 1.8 in) Weight 1.45 kg (3.2 lbs) (Including mounting bracket) Antenna Gain 19 dBi Table 48 Force 300-19 environmental specifications Category Specification Temperature
-30C (-22F) to +60C (140F) Wind loading 113 mph (180 kph) maximum. See Force 300-19 wind loading for a full description. Humidity 95% condensing Environmental IP55 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Force 300-19 heater At startup, if the Force 300-19 module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 49. Chapter 2: System Hardware 80 Table 49 Force 300-19 startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 300-19 wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180kph (113mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 50and Table 51. Table 50 Force 300-19 wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 40 50 60 Force 300-19 Integrated 0.08 13.4 Kg 20.9 Kg 30. 1Kg Table 51 Force 300-19 wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) Force 300-19 Integrated 0.8281 22.3 lb 34.8 lb 50.1 lb 80 100 120 Chapter 2: System Hardware 81 Force 300-19 software packages Force 300-19 devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Force 300-19R For details of the Force 300-19R hardware, see:
l Force 300-19R integrated description l Force 300-19R part numbers l Force 300-19R mounting bracket l Force 300-19R interfaces l Force 300-19R specifications l Force 300-19R heater l Force 300-19R wind loading l Force 300-19R software packages Force 300-19R integrated description The Force 300-19R device is a self-contained transceiver unit that houses both radio and networking electronics. (FCCID: Z8H89FT0048 | IC:109W-0048) Force 300-19R part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 52 and Table 53 include the following items:
Figure 40: Force300-19R l One integrated unit Chapter 2: System Hardware 82 l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 52 Force 300-19R part numbers Cambium description Cambium part number ePMP 5 GHz Force 300-19R SM (FCC) (US cord) C058900C901A ePMP 5 GHz Force 300-19R SM (IC) (Canada/US cord) C050900C901A ePMP 5 GHz Force 300-19R SM (EU) (EU cord) C050900C902A ePMP 5 GHz Force 300-19R SM (EU) (UK cord) C050900C903A ePMP 5 GHz Force 300-19R SM (ROW) (no cord) C050900C904A ePMP 5 GHz Force 300-19R SM (ROW) (US cord) C050900C905A ePMP 5 GHz Force 300-19R SM (ROW) (EU cord) C050900C906A ePMP 5 GHz Force 300-19R SM (ROW) (UK cord) C050900C907A ePMP 5 GHz Force 300-19R SM (ROW) (India cord) C050900C908A ePMP 5 GHz Force 300-19R SM (India) (India cord) C050900C909A ePMP 5 GHz Force 300-19R SM (ROW) (China cord) C050900C910A ePMP 5 GHz Force 300-19R SM (ROW) (Brazil cord) C050900C911A ePMP 5 GHz Force 300-19R SM (ROW) (Argentina cord) C050900C912A ePMP 5 GHz Force 300-19R SM (ROW) (ANZ cord) C050900C913A ePMP 5 GHz Force 300-19R SM (ROW) (South Africa cord) C050900C914A ePMP 5 GHz Force 300-19R SM (ROW) (No PSU) C050900C915A Table 53 Force 300-19R accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 Chapter 2: System Hardware 83 Force 300-19R mounting bracket The Force 300-19R module is designed to be pole-mounted using the mounting bracket provided in the box with the radio. An overview of Force 300-19R mounting bracket is shown in Figure 41 Figure 41: Force300-19Rmodulemountingbracket Force 300-19R interfaces The Ethernet port is located on the rear of the integrated unit. This interface is described in Table 54. Table 54 Force 300-19R Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). 100/1000BASE-T Ethernet Data Force 300-19R specifications The Force 300-19R integrated module conforms to the specifications listed in Table 55 and Table 56. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 55 Force 300-19R physical specifications Category Specification Dimensions 27.8 cm x 27.8 cm x 4.5cm (10.9 in x 10.9 in x 1.8 in) Weight 1.45 kg (3.2 lbs) (Including mounting bracket) Antenna Gain 19 dBi Chapter 2: System Hardware 84 Table 56 Force 300-19R environmental specifications Category Specification Temperature
-30C (-22F) to +60C (140F) Wind loading 113 mph (180 kph) maximum. See Force 300-25 wind loading for a full description. Humidity 95% condensing Environmental IP67 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Force 300-19R heater At startup, if the Force 300-19R module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 57. Table 57 Force 300-19R startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 300-19R wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180kph (113mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Chapter 2: System Hardware 85 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 58-and Table 59. Table 58 Force 300-19R wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 40 50 60 Force 300-19 Integrated 0.08 13.4Kg 20.9Kg 30.1Kg Table 59 Force 300-19R wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) Force 300-19 Integrated 0.8281 22.3 lb 34.8 lb 50.1 lb 80 100 120 Force 300-19R software packages Force 300-19R devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Force 300-16 For details of the Force 300-16 hardware, see:
l Force 300-16 integrated description l Force 300-16 part numbers l Force 300-16 interfaces l Force 300-16 specifications l Force 300-16 heater l Force 300-16 wind loading l Force 300-16 software packages Force 300-16 integrated description The Force 300-16 device is a self-contained transceiver unit that houses both radio and networking electronics. An overview of Force 300-16 is shown in Figure 42. Chapter 2: System Hardware 86 Figure 42: Force300-16Integrated Force 300-16 part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 60 and Table 61 include the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 60 Force 300-16 part numbers Cambium description Cambium part number ePMP 5 GHz Force 300-16 Radio (FCC) (US cord) C058910C112A ePMP 5 GHz Force 300-16 Radio (IC) (Canada/US cord) C050910C114A ePMP 5 GHz Force 300-16 Radio (EU) (EU cord) C050910C213A ePMP 5 GHz Force 300-16 Radio (EU) (UK cord) C050910C313A ePMP 5 GHz Force 300-16 Radio (ROW) (no cord) C050910C011A ePMP 5 GHz Force 300-16 Radio (ROW) (US cord) C050910C111A ePMP 5 GHz Force 300-16 Radio (ROW) (EU cord) C050910C211A ePMP 5 GHz Force 300-16 Radio (ROW) (UK cord) C050910C311A ePMP 5 GHz Force 300-16 Radio (ROW) (India cord) C050910C411A ePMP 5 GHz Force 300-16 Radio (India) (India cord) C050910C412A ePMP 5 GHz Force 300-16 Radio (ROW) (China cord) C050910C511A ePMP 5 GHz Force 300-16 Radio (ROW) (Brazil cord) C050910C611A ePMP 5 GHz Force 300-16 Radio (ROW) (Argentina cord) C050910C711A ePMP 5 GHz Force 300-16 Radio (ROW) (ANZ cord) C050910C811A Chapter 2: System Hardware 87 Cambium description Cambium part number ePMP 5 GHz Force 300-16 Radio (ROW) (South Africa cord) C050910C911A ePMP 5 GHz Force 300-16 Radio (ROW) (No PSU) C050910CZ11A Table 61 Force 300-16 accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 Force 300-16 interfaces The Ethernet port is located on the rear of the integrated unit. Table 62 Force 300-16 Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data Force 300-16 specifications The Force 300-16 integrated module conforms to the specifications listed in Table 63 and Table 64. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Chapter 2: System Hardware 88 Table 63 Force 300-16 physical specifications Category Specification Dimensions (Diameter x Depth) 12.4 cm x 25.1 cm x 11.9 cm (4.9 in x 9.9 in x 4.7 in) with mounting bracket Weight 0.5 kg (1.1 lbs) with mounting bracket Table 64 Force 300-16 environmental specifications Category Specification Temperature
-30C (-22F) to +60C (140F) Wind loading 112 mph (180 kph) maximum. See Force 300-16 wind loading for a full description. Environmental IP55 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Force 300-16 heater At startup, if the Force 300-16 module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 65. Table 65 Force 300-16 startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 300-16 wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180kph
(124mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Chapter 2: System Hardware 89 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 66 and Table 67. Table 66 Force 300-16 wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 30 40 50 Force 300-16 Integrated 0.03 2.8 Kg 5 Kg 7.8 Kg Table 67 Force 300-16 wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) Force 300-16 Integrated 0.34 9.1 lb 14.3 lb 20.6 lb 80 100 120 Force 300-16 software packages Force 300-16 devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Force 300-13 For details of the Force 300-13 hardware, see:
l Force 300-13 integrated description l Force 300-13 part numbers l Force 300-13 interfaces l Force 300-13 specifications l Force 300-13 heater l Force 300-13 wind loading l Force 300-13 software packages Chapter 2: System Hardware 90 Force 300-13 integrated description The Force 300-13 device is a self-contained transceiver unit that houses both radio and networking electronics.
(FCCID:Z8H89FT0048 | IC:109W-0048). An overview of Force 300-13 is shown in Figure 43. Figure 43: Force300-13Integratedradio Force 300-13 part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 68 and Table 69 include the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 68 Force 300-13 part numbers Cambium description Cambium part number ePMP 5GHz Force 300-13 SM (FCC) (US cord) C058900C701A ePMP 5GHz Force 300-13 SM (IC) (Canada/US cord) C050900C701A ePMP 5GHz Force 300-13 SM (EU) (EU cord) C050900C702A ePMP 5GHz Force 300-13 SM (EU) (UK cord) C050900C703A ePMP 5GHz Force 300-13 SM (ROW) (no cord) C050900C704A ePMP 5GHz Force 300-13 SM (ROW) (US cord) C050900C705A ePMP 5GHz Force 300-13 SM (ROW) (EU cord) C050900C706A ePMP 5GHz Force 300-13 SM (ROW) (UK cord) C050900C707A ePMP 5GHz Force 300-13 SM (ROW) (India cord) C050900C708A Chapter 2: System Hardware 91 Cambium description Cambium part number ePMP 5GHz Force 300-13 SM (India) (India cord) C050900C709A ePMP 5GHz Force 300-13 SM (ROW) (China cord) C050900C710A ePMP 5GHz Force 300-13 SM (ROW) (Brazil cord) C050900C711A ePMP 5GHz Force 300-13 SM (ROW) (Argentina cord) C050900C712A ePMP 5GHz Force 300-13 SM (ROW) (ANZ cord) C050900C713A ePMP 5GHz Force 300-13 SM (ROW) (South Africa cord) C050900C714A ePMP 5GHz Force 300-13 SM (ROW) (No PSU) C050900C715A Table 69 Force 300-13 accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 Force 300-13 interfaces The Ethernet port is located on the rear of the integrated unit. Table 70 Force 300-13 Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data Chapter 2: System Hardware 92 Force 300-13 specifications The Force 300-13 integrated module conforms to the specifications listed in Table 71 and Table 72. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 71 Force 300-13 physical specifications Category Specification Dimensions (Diameter x Depth) 12.4 cm x 25.1 cm x 11.9 cm (4.9 in x 9.9 in x 4.7 in) with mounting bracket Weight 0.5 kg (1.1 lbs) with mounting bracket Antenna Gain 13 dBi Table 72 Force 300-13 environmental specifications Category Specification Temperature
-30C (-22F) to +60C (140F) Wind loading 112 mph (180 kph) maximum. See Force 300-16 wind loading for a full description. Environmental IP55 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Force 300-13 heater At startup, if the Force 300-13 module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 73. Table 73 Force 300-13 startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Chapter 2: System Hardware 93 Force 300-13 wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180kph
(124mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 74 and Table 75. Table 74 Force 300-13 wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 30 40 50 Force 300-13 Integrated 0.03 2.82 Kg 5.02 Kg 7.84 Kg Table 75 Force 300-13 wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) Force 300-13 Integrated 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Force 300-13 software packages Force 300-16 devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Chapter 2: System Hardware 94 Force 300-13L For details of the Force 300-13L hardware, see:
l Force 300-13L integrated description l Force 300-13L part numbers l Force 300-13L interfaces l Force 300-13L specifications l Force 300-13L wind loading l Force 300-13L LEDs l Force 300-13L software packages Force 300-13L integrated description The Force 300-13L device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 300-13L uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP 3000 and ePMP 3000L APs. It is also backward compatible with the ePMP 2000 using backward compatibility features. An overview of Force 300-13L is shown in Figure 44. Figure 44: Force300-13LIntegrated Force 300-13L part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 76 and Table 77 include the following items:
Chapter 2: System Hardware 95 l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One-line cord Table 76Force 300-13L part numbers Cambium description Cambium part number ePMP 5 GHz Force 300-13L SM (ROW) (no cord) ePMP 5 GHz Force 300-13L SM (ROW) (US cord) ePMP 5 GHz Force 300-13L SM (ROW) (EU cord) ePMP 5 GHz Force 300-13L SM (EU) (EU cord) ePMP 5 GHz Force 300-13L SM (ROW) (UK cord) ePMP 5 GHz Force 300-13L SM (EU) (UK cord) ePMP 5 GHz Force 300-13L SM (ROW) (India cord) ePMP 5 GHz Force 300-13L SM (India) (India Cord) ePMP 5 GHz Force 300-13L SM (ROW) (China cord) ePMP 5 GHz Force 300-13L SM (ROW) (Brazil cord) C050910C031A C050910C131A C050910C231A C050910C233A C050910C331A C050910C333A C050910C431A C050910C432A C050910C531A C050910C631A ePMP 5 GHz Force 300-13L SM (ROW) (Argentina cord) C050910C731A ePMP 5 GHz Force 300-13L SM (ROW) (ANZ cord) C050910C831A ePMP 5 GHz Force 300-13L SM (ROW) (South Africa cord) C050910C931A ePMP 5 GHz Force 300-13L SM (ROW) (No PSU) C050910CZ31A Table 77Force 300-13L accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 Chapter 2: System Hardware 96 Force 300-13L interfaces The Ethernet port is located on the rear of the integrated unit. Figure 45: RearInterfaces Table 78 Force 300-13L Series rear interfaces Port name Connector Interface Description Ethernet RJ45 Reset Button Physical button 24V PoE input 100 BASE-
TX Ethernet N/A 10/100 BASE-T Management and data For resetting the radio and for setting the radio back to its factory default configuration. See Using the device external reset button. Force 300-13L specifications The Force 300-13L integrated module conforms to the specifications listed in Table 79 and Table 80. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 79 Force 300-13L physical specifications Category Specification Dimensions (Diameter x Depth) 235 x 77 x 58 mm Weight 0.35 kg (0.88 lbs) Antenna Gain 13 dBi Chapter 2: System Hardware 97 Table 80 Force 300-13L environmental specifications Category Specification Temperature
-30C to +55C (-22F to +122F) Wind loading 125 km/hour (78 mi/hour) Environmental IP55 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be raintight. Force 300-13L wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 125kph (78mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and surface area. Force 300-13L LEDs Table 81 Force 300-13L LED Functions LED Function POWER Green: Power is applied to the device Unlit: No power is applied to the device or improper power source WiFi LAN XXX XXX Radio scanning: LEDs light in an ascending sequence to indicate that the radio is scanning Radio registered: LEDs light to indicate the RSSI level at the device. RSSI
-70 dBm
-80 dBm RSSI
> -60 dBm
< RSSI
< RSSI
-80 dBm
-60 dBm
-70 dBm Chapter 2: System Hardware 98 Force 300-13L software packages Force 300-13L devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP- NonGPS_Synced-[version].tar.gz (or higher version number) Force 300 CSM For details of the Force 300 CSM hardware, see:
l Force 300 CSM Connectorized Subscriber Module description l Force 300 CSM part numbers l Force 300 CSM interfaces l Force 300 CSM specifications l Force 300 CSM heater l Force 300 CSM wind loading l Force 300 CSM software packages Force 300 CSM Connectorized Subscriber Module description The Force 300 CSM device is a connectorized Subscriber Module transceiver unit that houses both radio and networking electronics. An overview of Force 300 CSM is shown in Figure 46. Figure 46: Force300CSM Force 300 CSM part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 82 and Table 83 includes the following items:
Chapter 2: System Hardware 99 l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 82 Force 300 CSM part numbers Cambium description Cambium part number ePMP 5 GHz Force 300 CSM SM (FCC) (US cord) C058910C122A ePMP 5 GHz Force 300 CSM SM (IC) (Canada/US cord) C050910C124A ePMP 5 GHz Force 300 CSM SM (EU) (EU cord) C050910C223A ePMP 5 GHz Force 300 CSM SM (EU) (UK cord) C050910C323A ePMP 5 GHz Force 300 CSM SM (ROW) (no cord) C050910C021A ePMP 5 GHz Force 300 CSM SM (ROW) (US cord) C050910C121A ePMP 5 GHz Force 300 CSM SM (ROW) (EU cord) C050910C221A ePMP 5 GHz Force 300 CSM SM (ROW) (UK cord) C050910C321A ePMP 5 GHz Force 300 CSM SM (ROW) (India cord) C050910C421A ePMP 5 GHz Force 300 CSM SM (India) (India cord) C050910C422A ePMP 5 GHz Force 300 CSM SM (ROW) (China cord) C050910C521A ePMP 5 GHz Force 300 CSM SM (ROW) (Brazil cord) C050910C621A ePMP 5 GHz Force 300 CSM SM (ROW) (Argentina cord) C050910C721A ePMP 5 GHz Force 300 CSM SM (ROW) (ANZ cord) C050910C821A ePMP 5 GHz Force 300 CSM SM (ROW) (South Africa cord) C050910C921A ePMP 5 GHz Force 300 CSM SM (ROW) (No PSU) C050910CZ21A Table 83 Force 300 CSM accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 Chapter 2: System Hardware 100 Force 300 CSM interfaces The Ethernet port is located on the rear of the unit. Table 84 Force 300 CSM Series rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data Force 300 CSM specifications The Force 300 CSM connectorized module conforms to the specifications listed in Table 85 and Table 86. The module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 85 Force 300 CSM physical specifications Category Specification Dimensions (Diameter x Depth) 220mm x 80mm x 25mm (8.7in x 3.15in x 1.0in) Weight 0.5 kg (1.1 lbs) with mounting bracket Table 86 Force 300 CSM environmental specifications Category Specification Temperature
-30C (-22F) to +60C (140F) Wind loading 112 mph (180 kph) maximum. See Force 300-16 wind loading for a full description. Environmental IP67 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Chapter 2: System Hardware 101 Force 300 CSM heater At startup, if the Force 300 CSM module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 87. Table 87 Force 300 CSM startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 300 CSM wind loading Ensure that the device and the structure on which it is mounted can withstand the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180kph
(124mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 88 and Table 89. Table 88 Force 300 CSM wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 30 40 50 Force 300 CSM Connectorized 0.03 2.82 Kg 5.02 Kg 7.84 Kg Chapter 2: System Hardware 102 Table 89 Force 300 CSM wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) Force 300 CSM Connectorized 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Force 300 CSM software packages The Force 300 CSM devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro.The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Force 300 CSML For details of the Force 300 CSML hardware, see:
l Force 300 CSML description l Force 300 CSML part numbers l Force 300 CSML interfaces l Force 300 CSML mounting bracket l Force 300 CSML specifications l Force 300 CSML wind loading l Force 300 CSML LEDs l Force 300 CSML software packages Force 300 CSML description The Force 300 CSML device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 300 CSML uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP 3000 and ePMP 3000L APs. It is also backward compatible with the ePMP 2000 using backward compatibility features. An overview of Force 300 CSML is shown in Figure 47. Chapter 2: System Hardware 103 Figure 47: Force300CSML Force 300 CSML part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 90 and Table 91 include the following items:
l One Connectorized unit l One power supply 1000/100 BASE-TX LAN injector l One-line cord Table 90 Force 300 CSML part numbers Cambium description Cambium part number ePMP 5 GHz Force 300 CSML SM (ROW) (no cord) ePMP 5 GHz Force 300 CSML SM (ROW) (US cord) ePMP 5 GHz Force 300 CSML SM (ROW) (EU cord) ePMP 5 GHz Force 300 CSML SM (EU) (EU cord) ePMP 5 GHz Force 300 CSML SM (ROW) (UK cord) ePMP 5 GHz Force 300 CSML SM (EU) (UK cord) C050910C061A C050910C161A C050910C261A C050910C263A C050910C361A C050910C363A ePMP 5 GHz Force 300 CSML SM (ROW) (India cord) C050910C461A ePMP 5 GHz Force 300 CSML SM (India) (India Cord) C050910C462A ePMP 5 GHz Force 300 CSML SM (ROW) (China cord) C050910C561A ePMP 5 GHz Force 300 CSML SM (ROW) (Brazil cord) C050910C661A ePMP 5 GHz Force 300 CSML SM (ROW) (Argentina cord) C050910C761A ePMP 5 GHz Force 300 CSML SM Bulk Packaging (ROW) (ANZ cord) C050910C861A ePMP 5 GHz Force 300 CSML SM (ROW) (South Africa cord) C050910C961A ePMP 5 GHz Force 300 CSML SM (ROW) (No PSU) C050910CZ61A Table 91 Force 300 CSML accessories part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU N000900L011 N000900L010 N000900L015 N000900L008 Chapter 2: System Hardware 104 Force 300 CSML interfaces The Ethernet port is located on the rear of the connectorized unit. Figure 48: Rearinterfaces Table 92 Force 300 CSML Series Rear interfaces Port name Connector Interface Description Ethernet RJ45 24V PoE input 10/100BASE-T 100 BASE-TX Ethernet Management and data Reset Button Physical button N/A For resetting the radio and for setting the radio back to its factory default configuration. Force 300 CSML mounting bracket The Force 300 CSML module is designed to be pole-mounted using the mounting bracket provided in the box with the radio. An overview of Force 300 CSML mounting bracket is shown in Figure 49. Chapter 2: System Hardware 105 Figure 49: Force300CSMLmodulemountingbracket Force 300 CSML specifications The Force 300 CSML module conforms to the specifications listed in Table 93 and Table 94. The connectorized module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 93 Force 300 CSML physical specifications Category Specification Dimensions (Diameter x Depth) 227 x 88 x 33 mm Weight 0.521 kg (1.15 lbs) without antenna Table 94 Force 300 CSML environmental specifications Category Specification Temperature
-30C to +55C (-22F to +122F) Wind loading 125 km/hour (78 mi/hour) Environmental IP55 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Force 300 CSML wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting brackets are capable of withstanding wind speeds of up to 125kph
(78mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and surface area. Chapter 2: System Hardware 106 Force 300 CSML LEDs Table 95 Force 300 CSML LED functions LED Function POWER Green: Power is applied to the device Unlit: No power is applied to the device or improper power source WiFi LAN XXX XXX Radio scanning: LEDs light in an ascending sequence to indicate that the radio is scanning Radio registered: LEDs light to indicate the RSSI level at the device. RSSI
-70 dBm
-80 dBm RSSI
> -60 dBm
< RSSI
< RSSI
-80 dBm
-60 dBm
-70 dBm Force 300 CSML software packages Force 300 CSML devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-F300-[Radio Model]-[version].tar.gz (or higher version number) ePMP MP3000 MicroPoP For details of the Force 300 CSM hardware, see:
l ePMP MP 3000 integrated description l ePMP MP 3000 part numbers l ePMP MP 3000 interfaces l ePMP MP 3000 specifications l ePMP MP 3000 heater Chapter 2: System Hardware 107 l ePMP MP 3000 wind loading l ePMP MP 3000 software packages ePMP MP 3000 integrated description The ePMP MP 3000 MicroPoP is an integrated AP designed to serve short-range, low-density applications. It uses 802.11ac 2x2 architecture and can interoperate with a Force 300 subscriber module. An overview of ePMP MP 3000 is shown in Figure 50. Figure 50: ePMPMP3000Integrated ePMP MP 3000 part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 96 and Table 97 includes the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 96 ePMP MP 3000 part numbers Cambium description Cambium part number ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (no cord) C050910A031A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (US cord) C050910A131A ePMP 5 GHz MP 3000 MicroPOP Radio (IC) (Canada/US cord) C058910A134A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (EU cord) C050910A231A ePMP 5 GHz MP 3000 MicroPOP Radio (EU) (EU cord) C050910A233A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (UK cord) C050910A331A Chapter 2: System Hardware 108 Cambium description Cambium part number ePMP 5 GHz MP 3000 MicroPOP Radio (EU) (UK cord) C050910A333A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (India cord) C050910A431A ePMP 5 GHz MP 3000 MicroPOP Radio (India) (India Cord) C050910A432A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (China cord) C050910A531A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (Brazil cord) C050910A631A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (Argentina cord) C050910A731A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (ANZ cord) C050910A831A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (South Africa cord) C050910A931A ePMP 5 GHz MP 3000 MicroPOP Radio (ROW) (No PSU) C050910AZ31A ePMP 5 GHz MP 3000 MicroPOP Radio (FCC) (US cord) C058910A132A Table 97 ePMP MP 3000 accessory part numbers Cambium description Cambium part number PoE Gigabit DC Injector, 15W Output at 30V, Energy Level 6 Supply N000900L001 CABLE, UL POWER SUPPLY CORD SET, ARGENTINA N000900L013 CABLE, UL POWER SUPPLY CORD SET, AUS/NZ CABLE, UL POWER SUPPLY CORD SET, Brazil CABLE, UL POWER SUPPLY CORD SET, CHINA CABLE, UL POWER SUPPLY CORD SET, EU CABLE, UL POWER SUPPLY CORD SET, INDIA CABLE, UL POWER SUPPLY CORD SET, UK CABLE, UL POWER SUPPLY CORD SET, US N000900L011 N000900L010 N000900L015 N000900L008 N000900L012 N000900L009 N000900L007 ePMP MP 3000 interfaces The Ethernet port is located on the rear of the integrated unit. Table 98 ePMP MP 3000 rear interfaces Port name Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). Note Chapter 2: System Hardware 109 Port name Connector Interface Description All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. 100/1000BASE-T Ethernet Data ePMP MP 3000 specifications The ePMP MP 3000 integrated module conforms to the specifications listed in Table 99 and Table 100. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 99 ePMP MP 3000 physical specifications Category Specification Dimensions (Diameter x Depth) 220mm x 80mm x 25mm (8.7in x 3.15in x 1.0in) Weight Antenna 0.5 kg (1.1 lbs) with mounting bracket Integrated dual-polarized, Omni-direction 8dBi Table 100 ePMP MP 3000 environmental specifications Category Specification Temperature
-40C (-40F) to +65C (149F) ambient op temp Wind loading 224 kph 320mm x 215mm x 65mm 1100g Environmental IP67 Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. ePMP MP 3000 heater At startup, if the ePMP MP 3000 module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 101. Chapter 2: System Hardware 110 Table 101 ePMP MP 3000 startup times based on ambient temperature Initial Temperature Startup time (from power on to operational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds ePMP MP 3000 wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180kph
(124mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 102 and Table 103. Table 102 ePMP MP 3000 wind loading (Kg) Type of ePMP device Largest surface area (square meters) Wind speed (meters per second) 30 40 50 ePMP MP 3000 Integrated 0.03 2.82 Kg 5.02 Kg 7.84 Kg Table 103 ePMP MP 3000 wind loading (lb) Type of ePMP device Largest surface area (square feet) Wind speed (miles per hour) ePMP MP 3000 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Chapter 2: System Hardware 111 ePMP MP 3000 software packages ePMP MP 3000 devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AC-v4.5-GA.img (or higher version number) Force 425 For details of the Force 425 hardware, see:
l Force 425 integrated description l Force 425 part numbers l Force 425 mounting bracket with Range Extender l Force 425 interfaces l Force 425 specifications l Force 425 heater l Force 425 software packages Force 425 integrated description The Force 425 device is a self-contained transceiver unit that houses bothradio and networking electronics. An overview of Force 425 is shown in Figure 51. Figure 51: Force425Integrated Force 425 part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed in Table 102 includes the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector Chapter 2: System Hardware 112 l One line cord Table 102 ePMP Force 425 part numbers Cambium description Cambium part number ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (no cord) - Priced per radio C050940M001A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (US cord) - Priced per radio C050940M101A ePMP 5 GHz Force 425 SM 2-pack packaging (IC) (Canada/US cord) - Priced per radio C058940M104A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (EU cord) - Priced per radio C050940M201A ePMP 5 GHz Force 425 SM 2-pack packaging (EU) (EU cord) - Priced per radio C050940M203A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (UK cord) - Priced per radio C050940M301A ePMP 5 GHz Force 425 SM 2-pack packaging (EU) (UK cord) - Priced per radio C050940M303A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (India cord) - Priced per radio C050940M401A ePMP 5 GHz Force 425 SM 2-pack packaging (India) (India Cord) - Priced per radio C050940M402A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (China cord) - Priced per radio C050940M501A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (Brazil cord) - Priced per radio C050940M601A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (Argentina cord) - Priced per radio C050940M701A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (ANZ cord) - Priced per radio C050940M801A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (South Africa cord) - Priced per radio C050940M901A ePMP 5 GHz Force 425 SM 2-pack packaging (ROW) (No PSU) - Priced per radio C050940MZ01A ePMP 5 GHz Force 425 SM 2-pack packaging (FCC) (US Cord) - Priced per radio C058940M102A Table 103 Force 425 accessory part numbers Cambiumdescription Cambium partnumber ePMP Force 425 Range Extender Dish Accessory 4-Pack Packaging, priced per unit N000900L062A Chapter 2: System Hardware 113 Force 425 mounting bracket with Range Extender The Force 425 module is designed to be pole-mounted using the mounting bracket provided in the box with the radio. An overview of Force 425 mounting bracket is shown in Figure 52 Figure 52: Force425modulemountingbracketwithRangeExtender Force 425 interfaces The Ethernet port is located on the rear of the integrated unit. This interface is described in Table 104. Table 104 Force 425 Series rear interfaces Portname Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE). 100/1000BASE-T Ethernet Data SFP 10 Gigabit cage Optional 10 Gigabit SFP cage for SFP module Force 425 specifications The Force 425 integrated module conforms to the specifications listed in Table 105 and Table 106. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 105 Force 425 physical specifications Category Specification Dimensions (Diameter x Depth) 470 mm diameter x 285 mm depth (18.5 in diameter x 11.2 in depth) Weight 4.8 kg (10.6 lbs.) Chapter 2: System Hardware 114 Table 106 Force 425 environmental specifications Category Specification Temperature
-30C to 65C (-22F to 149F) Wind loading 200 km/hour (124 mph) Humidity 95% condensing Environmental IPx0 Force 425 heater At startup, if the Force 425 module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated, and the unit continues its startup sequence. The effect on device startup time at various temperatures is defined in Table 107. Table 107 Force 425 startup times based on ambient temperature InitialTemperature Startuptime(frompowerontooperational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 425 wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the dominant wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 200 kph (124 mph). Wind blowing on the device subjects the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
Chapter 2: System Hardware 115 A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 108 and Table 109. Table 108 Force 425 wind loading (Kg) TypeofePMPdevice Largest surfacearea(squaremeters) Wind speed (meters per second) Force 425 Integrated 0.15 25.08 Kg 39.2 Kg 56.43 Kg 40 50 60 Table 109 Force 425 wind loading (lb) TypeofePMPdevice Largest surfacearea(squarefeet) Wind speed (miles per hour) Force 425 Integrated 1.61 43.28 lb 67.62 lb 97.37 lb 80 100 120 Force 425 software packages Force 425 devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named:
l ePMP-AX-v5.0.img (or higher version number) Force 400C For details of the Force 400C hardware, see:
l Force 400C integrated description l Force 400C part numbers l Force 400C interfaces l Force 400C specifications l Force 400C heater l Force 400C wind loading l Force 400C software packages Force 400C integrated description The Force 400C device is a self-contained transceiver unit that houses both radio and networking electronics. An overview of Force 400C is shown in Figure 53. Chapter 2: System Hardware 116 Figure 53: Force400CIntegrated Force 400C part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed includes the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 110 Force 400C part numbers Cambiumdescription Cambium partnumber ePMP 5 GHz Force 400C (ROW) (no cord) C050940C021A ePMP 5 GHz Force 400C (ROW) (US cord) C050940C121A ePMP 5 GHz Force 400C (IC) (Canada/US cord) C058940C124A ePMP 5 GHz Force 400C (ROW) (EU cord) C050940C221A ePMP 5 GHz Force 400C (EU) (EU cord) C050940C223A ePMP 5 GHz Force 400C (ROW) (UK cord) C050940C321A ePMP 5 GHz Force 400C (EU) (UK cord) C050940C323A ePMP 5 GHz Force 400C (ROW) (India cord) C050940C421A ePMP 5 GHz Force 400C (India) (India Cord) C050940C422A ePMP 5 GHz Force 400C (ROW) (China cord) C050940C521A Chapter 2: System Hardware 117 Cambiumdescription Cambium partnumber ePMP 5 GHz Force 400C (ROW) (Brazil cord) C050940C621A ePMP 5 GHz Force 400C (ROW) (Argentina cord) C050940C721A ePMP 5 GHz Force 400C (ROW) (ANZ cord) C050940C821A ePMP 5 GHz Force 400C (ROW) (South Africa cord) C050940C921A ePMP 5 GHz Force 400C (ROW) (No PSU) C050940CZ21A ePMP 5 GHz Force 400C (FCC) (US Cord) C058940C122A Table 111 Force 400C accessory part numbers Cambiumdescription Cambiumpartnumber ePMP Force 400 spares kit N000900L061A Force 400C interfaces The Ethernet port is located on the rear of the integrated unit. Table 112 Force 400C series rear interfaces Portname Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE) 100/1000BASE-T Ethernet Data SFP 10 Gigabit cage Optional 10 Gigabit SFP cage for SFP module Force 400C specifications The Force 400C integrated module conforms to the specifications listed in Table 113 and Table 114. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 113 Force 400C physical specifications Category Specification Dimensions (Diameter x Depth) 256 mm x 125 mm x 46 mm (10.1 in x 4.9 in. x 1.8 in.) Weight 1.3 kg (2.9 lbs.) Table 114 Force 400C environmental specifications Category Specification Temperature
-30C to 65C (-22F to 149F) Chapter 2: System Hardware 118 Category Specification Wind loading 200 km/hour (124 mph) Environmental IPx0 Force 400C heater At startup, if the Force 400C module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated and the unit continues its start-up sequence. The effect on device startup time at various temperatures is defined in Table 115. Table 115 Force 400C startup times based on ambient temperature InitialTemperature Startuptime(frompowerontooperational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 400C wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180 kph (124 mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 116 and Table 117. Chapter 2: System Hardware 119 Table 116 Force 400C wind loading (Kg) TypeofePMPdevice Largest surfacearea(squaremeters) Wind speed (meters per second) Force 400C Integrated 0.03 2.82 Kg 5.02 Kg 7.84 Kg 30 40 50 Table 117 Force 400C wind loading (lb) TypeofePMPdevice Largest surfacearea(squarefeet) Wind speed (miles per hour) Force 400C Integrated 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Force 400C software packages Force 400C devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named. l ePMP-AX-v5.x.x.img (or higher version number) Force 4600C For details of the Force 4600C hardware, see:
l Force 4600C integrated description l Force 4600C part numbers l Force 4600C interfaces l Force 4600C specifications l Force 4600C heater l Force 4600C wind loading l Force 4600C software packages Force 4600C integrated description The Force 4600C device is a self-contained transceiver unit that houses both radio and networking electronics. An overview of Force 4600C is shown in Figure 54. Chapter 2: System Hardware 120 Figure 54: Force4600Cconnectorized Force 4600C part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed includes the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Force 4600C interfaces The Ethernet port is located on the rear of the integrated unit. Table 112 Force 4600C series rear interfaces Portname Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE) 100/1000BASE-T Ethernet Data SFP 10 Gigabit cage Optional 10 Gigabit SFP cage for SFP module Force 4600C specifications The Force 4600C integrated module conforms to the specifications listed in Table 113 and Table 114. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Chapter 2: System Hardware 121 Table 113 Force 4600C physical specifications Category Specification Dimensions (Diameter x Depth) 256 mm x 125 mm x 46 mm (10.1 in x 4.9 in. x 1.8 in.) Weight 1.3 kg (2.9 lbs.) Table 114 Force 4600C environmental specifications Category Specification Temperature
-30C to 65C (-22F to 149F) Wind loading 200 km/hour (124 mph) Environmental IPx0 Force 4600C heater At startup, if the Force 4600C module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated and the unit continues its start-up sequence. The effect on device startup time at various temperatures is defined in Table 115. Table 115 Force 4600C startup times based on ambient temperature InitialTemperature Startuptime(frompowerontooperational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 4600C wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180 kph (124 mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Chapter 2: System Hardware 122 Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 116 and Table 117. Table 116 Force 4600C wind loading (Kg) TypeofePMPdevice Largest surfacearea(squaremeters) Wind speed (meters per second) Force 4600C Integrated 0.03 2.82 Kg 5.02 Kg 7.84 Kg 30 40 50 Table 117 Force 4600C wind loading (lb) TypeofePMPdevice Largest surfacearea(squarefeet) Wind speed (miles per hour) Force 4600C Integrated 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Force 4600C software packages Force 4600C devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named. l ePMP-AX-v5.x.x.img (or higher version number) ePMP 5/6GHz 2 x 2 dish antenna Figure 55: ePMP5/6GHz2x2dishantenna Force 4525 For details of the Force 4525 hardware, see:
Chapter 2: System Hardware 123 l Force 4525 integrated description l Force 4525 part numbers l Force 4525 interfaces l Force 4525 specifications l Force 4525 heater l Force 4525 wind loading l Force 4525 software packages Force 4525 integrated description The Force 4525 device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 4525 uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP XXXXX and ePMP XXXXX APs. It is also backward compatible with the ePMP XXXX using backward compatibility features. An overview of Force 4525 is shown in Figure 56. Figure 56: Force4525connectorized Force 4525 part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed includes the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 110 Force 4525 part numbers Cambiumdescription Cambium partnumber ePMP 6 GHz Force 4600C SM Radio (ROW) (no cord) C060940C021A ePMP 6 GHz Force 4600C SM Radio (ROW) (US cord) C060940C121A Chapter 2: System Hardware 124 Cambiumdescription Cambium partnumber ePMP 6 GHz Force 4600C SM Radio (IC) (Canada/US cord) C068940C124A ePMP 6 GHz Force 4600C SM Radio (ROW) (EU cord) C060940C221A ePMP 6 GHz Force 4600C SM Radio (EU) (EU cord) C060940C223A ePMP 6 GHz Force 4600C SM Radio (ROW) (UK cord) C060940C321A ePMP 6 GHz Force 4600C SM Radio (EU) (UK cord) C060940C323A ePMP 6 GHz Force 4600C SM Radio (ROW) (India cord) C060940C421A ePMP 6 GHz Force 4600C SM Radio (India) (India Cord) C060940C425A ePMP 6 GHz Force 4600C SM Radio (ROW) (China cord) C060940C521A ePMP 6 GHz Force 4600C SM Radio (ROW) (Brazil cord) C060940C621A ePMP 6 GHz Force 4600C SM Radio (ROW) (Argentina cord) C060940C721A ePMP 6 GHz Force 4600C SM Radio (ROW) (ANZ cord) C060940C821A ePMP 6 GHz Force 4600C SM Radio (ROW) (South Africa cord) C060940C921A ePMP 6 GHz Force 4600C SM Radio (ROW) (No PSU) C060940CZ21A ePMP 6 GHz Force 4600C SM Radio (FCC) (US Cord) C068940C122B ePMP 6 GHz Force 4600C SM Radio (Indonesia) (EU Cord) C060940C226A Table 111 Force 4525 accessory part numbers Cambiumdescription Cambiumpartnumber ePMP Force 4525 spares kit XXXXXXXXXXXX Force 4525 interfaces The Ethernet port is located on the rear of the integrated unit. Table 112 Force 4525 series rear interfaces Portname Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE) 100/1000BASE-T Ethernet Data SFP 10 Gigabit cage Optional 10 Gigabit SFP cage for SFP module Force 4525 specifications The Force 4525 integrated module conforms to the specifications listed in Table 113 and Table 114. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Chapter 2: System Hardware 125 Table 113 Force 4525 physical specifications Category Specification Dimensions (Diameter x Depth) 256 mm x 125 mm x 46 mm (10.1 in x 4.9 in. x 1.8 in.) Weight 1.3 kg (2.9 lbs.) Table 114 Force 4525 environmental specifications Category Specification Temperature
-30C to 65C (-22F to 149F) Wind loading 200 km/hour (124 mph) Environmental IPx0 Force 4525 heater At startup, if the Force 4525 module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated and the unit continues its start-up sequence. The effect on device startup time at various temperatures is defined in Table 115. Table 115 Force 4525 startup times based on ambient temperature InitialTemperature Startuptime(frompowerontooperational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 4525 wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180 kph (124 mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Chapter 2: System Hardware 126 Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 116 and Table 117. Table 116 Force 4525 wind loading (Kg) TypeofePMPdevice Largest surfacearea(squaremeters) Wind speed (meters per second) Force 4525 Integrated 0.03 2.82 Kg 5.02 Kg 7.84 Kg 30 40 50 Table 117 Force 4525 wind loading (lb) TypeofePMPdevice Largest surfacearea(squarefeet) Wind speed (miles per hour) Force 4525 Integrated 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Force 4525 software packages Force 4525 devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named. l ePMP-AX-v5.x.x.img (or higher version number) Force 4525L For details of the Force 4525L hardware, see:
l Force 4525L integrated description l Force 4525L part numbers l Force 4525L interfaces l Force 4525L specifications l Force 4525L heater l Force 4525L wind loading l Force 4525L software packages Chapter 2: System Hardware 127 Force 4525L integrated description The Force 4525L device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 4525L uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP XXXXX and ePMP XXXXX APs. It is also backward compatible with the ePMP XXXX using backward compatibility features. An overview of Force 4525L is shown in Figure 57. Figure 57: Force4525Lconnectorized Force 4525L part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed includes the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Table 110 Force 4525L part numbers Cambiumdescription Cambium partnumber ePMP 6 GHz Force 4525L Radio (ROW) (no cord) C060940C021A ePMP 6 GHz Force 4525L Radio (ROW) (US cord) C060940C121A ePMP 6 GHz Force 4525L Radio (IC) (Canada/US cord) C068940C124A ePMP 6 GHz Force 4525L Radio (ROW) (EU cord) C060940C221A ePMP 6 GHz Force 4525L Radio (EU) (EU cord) C060940C223A ePMP 6 GHz Force 4525L Radio (ROW) (UK cord) C060940C321A ePMP 6 GHz Force 4525L Radio (EU) (UK cord) C060940C323A ePMP 6 GHz Force 4525L Radio (ROW) (India cord) C060940C421A Chapter 2: System Hardware 128 Cambiumdescription Cambium partnumber ePMP 6 GHz Force 4525L Radio (India) (India Cord) C060940C425A ePMP 6 GHz Force 4525L Radio (ROW) (China cord) C060940C521A ePMP 6 GHz Force 4525L Radio (ROW) (Brazil cord) C060940C621A ePMP 6 GHz Force 4525L Radio (ROW) (Argentina cord) C060940C721A ePMP 6 GHz Force 4525L Radio (ROW) (ANZ cord) C060940C821A ePMP 6 GHz Force 4525L Radio (ROW) (South Africa cord) C060940C921A ePMP 6 GHz Force 4525L Radio (ROW) (No PSU) C060940CZ21A ePMP 6 GHz Force 4525L Radio (FCC) (US Cord) C068940C122B ePMP 6 GHz Force 4525L Radio (Indonesia) (EU Cord) C060940C226A Force 4525L interfaces The Ethernet port is located on the rear of the integrated unit. Table 112 Force 4525L series rear interfaces Portname Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE) 100/1000BASE-T Ethernet Data SFP 10 Gigabit cage Optional 10 Gigabit SFP cage for SFP module Force 4525L specifications The Force 4525L integrated module conforms to the specifications listed in Table 113 and Table 114. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 113 Force 4525L physical specifications Category Specification Dimensions (Diameter x Depth) 256 mm x 125 mm x 46 mm (10.1 in x 4.9 in. x 1.8 in.) Weight 1.3 kg (2.9 lbs.) Table 114 Force 4525L environmental specifications Category Specification Temperature
-30C to 65C (-22F to 149F) Wind loading 200 km/hour (124 mph) Environmental IPx0 Chapter 2: System Hardware 129 Force 4525L heater At startup, if the Force 4525L module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated and the unit continues its start-up sequence. The effect on device startup time at various temperatures is defined in Table 115. Table 115 Force 4525L startup times based on ambient temperature InitialTemperature Startuptime(frompowerontooperational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 4525L wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180 kph (124 mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 116 and Table 117. Chapter 2: System Hardware 130 Table 116 Force 4525L wind loading (Kg) TypeofePMPdevice Largest surfacearea(squaremeters) Wind speed (meters per second) Force 4525L Integrated 0.03 2.82 Kg 5.02 Kg 7.84 Kg 30 40 50 Table 117 Force 4525L wind loading (lb) TypeofePMPdevice Largest surfacearea(squarefeet) Wind speed (miles per hour) Force 4525L Integrated 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Force 4525L software packages Force 4525L devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named. l ePMP-AX-v5.x.x.img (or higher version number) Force 4625 For details of the Force 4625 hardware, see:
l Force 4625 integrated description l Force 4625 part numbers l Force 4625 interfaces l Force 4625 specifications l Force 4625 heater l Force 4625 wind loading l Force 4625 software packages Force 4625 integrated description The Force 4625 device is a self-contained transceiver unit that houses both radio and networking electronics. The Force 4625 uses 802.11ac technology and supports MU-MIMO and other features offered by the ePMP XXXXX and ePMP XXXXX APs. It is also backward compatible with the ePMP XXXX using backward compatibility features. An overview of Force 4625 is shown in Figure 58. Chapter 2: System Hardware 131 Figure 58: Force4625connectorized Force 4625 part numbers Choose the correct regional variant to adhere to local licensing restrictions. Each of the parts listed includes the following items:
l One integrated unit l One power supply 1000/100 BASE-TX LAN injector l One line cord Force 4625 interfaces The Ethernet port is located on the rear of the integrated unit. Table 112 Force 4625 series rear interfaces Portname Connector Interface Description Eth RJ45 PoE input Power over Ethernet (PoE) 100/1000BASE-T Ethernet Data SFP 10 Gigabit cage Optional 10 Gigabit SFP cage for SFP module Force 4625 specifications The Force 4625 integrated module conforms to the specifications listed in Table 113 and Table 114. The integrated module meets the low-level static discharge specifications identified in Electromagnetic compatibility (EMC) compliance and provides internal surge suppression but does not provide lightning suppression. Table 113 Force 4625 physical specifications Category Specification Dimensions (Diameter x Depth) 256 mm x 125 mm x 46 mm (10.1 in x 4.9 in. x 1.8 in.) Weight 1.3 kg (2.9 lbs.) Chapter 2: System Hardware 132 Table 114 Force 4625 environmental specifications Category Specification Temperature
-30C to 65C (-22F to 149F) Wind loading 200 km/hour (124 mph) Environmental IPx0 Force 4625 heater At startup, if the Force 4625 module temperature is at or below 32F (0C), an internal heater is activated to ensure that the device can successfully begin operation. The units heater is only activated when the unit is powered on and will not apply heat to the device once the startup is complete. When the unit temperature is greater than 32F (0C), the heater is deactivated and the unit continues its start-up sequence. The effect on device startup time at various temperatures is defined in Table 115. Table 115 Force 4625 startup times based on ambient temperature InitialTemperature Startuptime(frompowerontooperational)
-22F (-30C) H 20 minutes
-4F (-20C) 6 minutes 14F (-10C) 2 minutes, 30 seconds Force 4625 wind loading Ensure that the device and the structure on which it is mounted are capable of withstanding the prevalent wind speeds at a proposed ePMP site. Wind speed statistics are available from national meteorological offices. The device and its mounting bracket are capable of withstanding wind speeds of up to 180 kph (124 mph). Wind blowing on the device will subject the mounting structure to significant lateral force. The magnitude of the force depends on both wind strength and the surface area of the device. Wind loading is estimated using the following formulae:
Force (in kilograms) = 0.1045aV2 Where:
Is:
a V the surface area in square meters wind speed in meters per second Force (in pounds) = 0.0042Av2 Where:
Is:
A v the surface area in square feet wind speed in miles per hour Chapter 2: System Hardware 133 Applying these formulae to the ePMP device at different wind speeds, the resulting wind loadings are shown in Table 116 and Table 117. Table 116 Force 4625 wind loading (Kg) TypeofePMPdevice Largest surfacearea(squaremeters) Wind speed (meters per second) Force 4625 Integrated 0.03 2.82 Kg 5.02 Kg 7.84 Kg 30 40 50 Table 117 Force 4625 wind loading (lb) TypeofePMPdevice Largest surfacearea(squarefeet) Wind speed (miles per hour) Force 4625 Integrated 0.28 7.53 lb 11.76 lb 16.93 lb 80 100 120 Force 4625 software packages Force 4625 devices may be upgraded by downloading new software packages from the Cambium Networks site or by using cnMaestro. The software packages applicable to ePMP integrated radios are named. l ePMP-AX-v5.x.x.img (or higher version number) Power supply For details of the ePMP power supply units, see:
l Power supply description l Power supply part numbers l Power supply interfaces l Power supply specifications l Power supply location considerations Power supply description The power supply unit that is connected to the ePMP modules is rated for indoor use. The ePMP modules are installed outdoors and terminated to network equipment using Cat5e cables with RJ45 connectors. The Cat5e cables are plugged into an AC or DC power supply to inject Power over Ethernet (PoE) into the module. The Cat5e cables connected to the power supply transitioning from indoors to outdoors must be rated for outdoor use. Attention All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. Chapter 2: System Hardware 134 Power supply part numbers Each module requires one power supply and one power supply line cord (line cord included with radio device, see Table 118. Table 118 Power supply part numbers Cambium description ePMP Power Supply for GPS Radio - no cord
(spare) Cambium part number N000900L001 Device Compatibility ePMP MP 3000 Access Point POWER SUPPLY, 30W, 56V Gbps support N000000L034 ePMP 3000 Access Point Attention Each ePMP device must be powered by the corresponding power supply listed in Table 118. This product is intended to be supplied by a UL Listed Power Supply Unit marked "LPS" or "PS2" and providing power over the Ethernet (PoE)"
supply. Power supply interfaces The power supply interfaces are illustrated in Power supply interfaces and described in Table 119 and Table 120 Power input Gigabit Data Gigabit Data + Power Figure 59: Powersupplyinterfaces Table 119 Power supply interface functions - N000900L001 Interface Function Power input Mains power input. Power output 30V Gigabit Data + Power RJ45 socket for connecting Cat5e cable to the radio. Note Chapter 2: System Hardware 135 Interface Function All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. Gigabit Data RJ45 socket for connecting Cat5e cable to the network. Table 120 Power supply interface functions - N000000L034 Interface Function Power input Mains power input. Power output 56V Gigabit Data + Power RJ45 socket for connecting Cat5e cable to the radio. Note All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. Gigabit Data RJ45 socket for connecting Cat5e cable to the network. Table 121 Power Supply LED functions LED Function Power (green) Power supply detection Power supply specifications The ePMP power supply conforms to the specifications listed in Table 122, Table 123, and Table 124. Table 122 Power supply physical specifications Category Specification Dimensions (H x W x D) 14 x 6.5 x 3.6 cm (5.5 x 2.55 x 1.42 in) Weight 0.26 lbs Table 123 Power supply environmental specifications Category Specification Ambient Operating Temperature 0C to +40C Humidity 20% - 90%
Chapter 2: System Hardware 136 Table 124 Power supply electrical specifications Category AC Input Efficiency Specification 100 to 240 VAC Meets Energy Level 6 Over Current Protection Short circuit, with auto-recovery Hold uptime 10 ms minimum at maximum load, 120 VAC Power supply location considerations Find a location for the power supply that meets the following requirements:
l The power supply is rated for indoor use and can be mounted on a wall or other flat surface. l The power supply must be kept dry, with no possibility of condensation, flooding, or rising dampness. l The power supply can be accessed to view status indicators. l The power supply can be connected to the ePMP module drop cable and network terminating equipment. l The power supply can be connected to a mains or DC power supply that meets the requirements defined in Table 124. Ethernet cabling For more information on the Ethernet cabling components of an ePMP installation, see:
l Ethernet standards and cable lengths l Outdoor Cat5e cable Ethernet standards and cable lengths All configurations require a copper Ethernet connection from the power supply port to the power supply and network terminating equipment. Attention All cables used for outdoor installations must be suitable to be used for that environment and rated accordingly. For each power supply, the maximum permitted drop cable length is specified in Table 125. Table 125 Power supply drop cable length restrictions Part number Description Maximum cable length (*1) N000900L001 Power Supply for Radio with Gigabit Ethernet (no cord) 330 feet (100m) N000000L034 Chapter 2: System Hardware 137
(*1) The maximum length of Ethernet cable from the device to the network device needs to follow 802.3 standards. If the power supply is not the network device the cable from the power supply to the network device must be included in the total maximum cable length. Outdoor Cat5e cable Cambium Industrial Cable Cambium Industrial Cable uses 24-gauge solid bare copper conductors, covered by bonded-pair polymer insulation. The conductors are protected by double-layer shielding consisting of a solid foil layer under the braided tinned copper mesh, providing excellent shielding while maximizing flexibility. And, the cable is jacketed by industrial-grade UV-resistant, abrasion-resistant, and oil-resistant PVC. Cambiums Industrial RJ45 connectors are specifically designed to work optimally with Cambium Industrial Cable. The connectors are fully shielded with integrated strain relief for greater pull strength, utilize a staggered contact design that minimizes crosstalk, and maximizes electrical performance, and the contacts are plated with 50 micro-inch thick 24-carat gold, exceeding TIA-1096 specifications and ensuring the best possible connection and oxidation resistance. Cambium Networks industrial-grade cable is well suited for high-quality durable installations of subscriber modules, APs, and enterprise point-to-point links as well as in tactical non-permanent deployments of infrastructure. Table 126 Cambium Industrial Cable part numbers Cambium description Cambium part number Industrial Grade CAT 5 Cable 50 meter unterminated N000000L106A Industrial Grade CAT 5 Cable 100 meter unterminated N000000L106A Industrial Grade CAT 5 Cable 300 meter unterminated N000000L108A Industrial Grade RJ45 Connector 100 Pack C000000L109A Termination Tool for C000000L109A RJ45 connectors C000000L110A Attention All RJ45 Ethernet LAN cables used for providing power or are connected to power ports (PoE) must be UL certified with VW-1 markings. Surge suppression unit Structures, equipment, and people must be protected against power surges (typically caused by lightning) by conducting the surge current to the ground via a separate preferential solid path. The actual degree of protection required depends on local conditions and applicable local regulations. To adequately protect an ePMP installation, both ground bonding and transient voltage surge suppression are required. Chapter 2: System Hardware 138 Network operators should always follow best practices for grounding and lightning protection. Doing so will minimize network outages and reduce the associated costs of tower climbs and equipment repair/replacement. Note Lightning-prone installations can be improved by:
n Installing a surge suppressor near the device (transient surge suppression) n Grounding the device to the pole (ground bonding) n Lowering the device/dish such that it is not the highest metallic object on the pole. Gigabit Ethernet surge suppressor The Gigabit Ethernet surge suppressor is critical for lightning protection to minimize the potential for damage. Figure 60: GigabitEthernetsurgesuppressor Table 127 Surge suppressor part numbers Cambium description Cambium part number Device Compatibility Gigabit Surge Suppressor (30V) C000000L065A Force 300-25 Force 300-19(R) Force 300-16 Force 300-13 Gigabit Surge Suppressor (56V) C000000L033A ePMP 3000 Access Point Attention Choose the 30V or 56V surge suppressor option based on your installed device power rating. Installing a 30V surge suppressor for a 56V device or a 56V surge suppressor for a 30V device may result in inadequate surge protection. Refer to Table 127 for more details. Chapter 2: System Hardware 139 cnPulse sync generator cnPulse is the latest GPS synchronization generation device designed specifically for Cambium Networks PMP and PTP radios. The cnPulse module is *IP67 (weatherproof and supports a wide temperature range for rugged environments. The GPS receiver is highly reliable and supports both GPS and GNSS signals. Figure 61: cnPulsesyncgenerator cnPulse receives its power from the CAT-5 drop cable in mode 2 so no external power supply is required. There are no configuration or software settings required. For ePMP 3000, cnPulse is deployed in-line with the radios CAT-5 drop cable. For more information, see: http://community.cambiumnetworks.com/t5/cnPulse/bd-p/cnPulse Note This product meets the UL/cUL 62368 / IEC 62368 edition 2 specification, and the radio housings are designed to be rain-tight. Chapter 2: System Hardware 140 Chapter 3: System Planning This chapter provides information to help the user to plan an ePMP link. The following topics are described in this chapter:
l How to plan ePMP links to conform to the regulatory restrictions that apply in the country of operation is explained under Radio spectrum planning l Factors to be considered when planning links such as range, path loss, and throughput are described under Link planning l The grounding and lightning protection requirements of an ePMP installation are described under Grounding and lightning protection l Factors to be considered when planning ePMP data networks are described under Data network planning Radio spectrum planning This section describes how to plan ePMP links to conform to the regulatory restrictions that apply in the country of operation. Attention The user must ensure the ePMP product operates in accordance with local regulatory limits. Note Contact the applicable radio regulator to check if the registration of the ePMP link is required. General wireless specifications The wireless specifications that apply to ePMP 802.11ac variants are listed under Table 128. The wireless specifications that are specific to each frequency variant are listed in Table 129. Table 128 Wireless specifications (all variants) Item Specification Channel selection Manual selection (fixed frequency) Automatic Channel Selection Manual power control To avoid interference with other users of the band, maximum power can be set lower than the default power limit. Maximum transmit power ePMP 3000 Access Point: 33 dBm Force 300-25: 29 dBm Force 300-19(R): 28dBm Chapter 3: System Planning 141 Item Specification Force 300-16: 29 dBm Force 300-13: 28dBm Integrated device antenna type Force 300-25: Dish antenna Force 300-19(R): Integrated patch Force 300-16: Integrated patch Force 300-13: Integrated patch Duplex scheme Adaptive TDD Over-the-air encryption AES Error Correction FEC Table 129 Wireless specifications, 5 GHz band Item 5 GHz RF band (GHz) 4.910 5.970 MHz Channel bandwidth 20 MHz, 40 MHz, or 80 MHz Typical antenna gain Integrated dish antenna 25 dBi Integrated patch antenna 16 dBi Sector antenna 17 dBi Dual-Horn antenna 13 dBi Omni antenna 13 dBi Antenna 3dB Beamwidth Integrated Dish: 6-10 azimuth, 6-10 elevation Integrated Patch: 15 azimuth, 30 elevation Sector antenna: 70 azimuth, 6 elevation Dual-Horn antenna: 45 azimuth/elevation Omni antenna: 360 azimuth, 7 elevation Regulatory limits The local regulator may restrict frequency usage and channel width and may limit the amount of conducted or radiated transmitter power. Many countries impose EIRP limits (Allowed EIRP) on products operating in the bands used by the ePMPSeries. For example, in the 5GHz band, these limits are calculated as follows:
l In the 5.8GHz band (5725 MHz to 5875 MHz), the EIRP must not exceed the lesser of 36 dBm or
(23 + 10 x Log Channel width in MHz) dBm. Some countries (for example the USA) impose conducted power limits on products operating in the 5 GHz band. Chapter 3: System Planning 142 Conforming to the limits Ensure the link is configured to conform to local regulatory requirements by configuring the correct country code (located in the web management interface, under Configure > Radio). In the following situations, the country code does not automatically prevent operation outside the regulations:
l When operating in ETSI regions, it is required to enter a license key in the ePMP web management interface to unlock valid country-specific frequencies. This key may be obtained from https://support.cambiumnetworks.com/licensekeys/epmp. Available spectrum The available spectrum for the operation depends on the region. When configured with the appropriate country code, the unit will only allow operation on those channels which are permitted by the regulations. Certain regulations have allocated certain channels as unavailable for use:
l Some European countries have allocated part of the 5.8 GHz band to Road Transport and Traffic Telematics (RTTT) systems. Where regulatory restrictions apply to certain channels, these channels are barred automatically by the use of the correct country code. For example, at 5.8GHz in some European countries, the RTTT band 5795 MHz to 5815 MHz is barred. With the appropriate country code configured for this region, the ePMP will not operate on channels within this band. The number and identity of channels barred by the license key and country code are dependent on the channel bandwidth. Channel bandwidth Select the required channel bandwidth for the link. The selection depends upon the ePMP frequency variant and country code. The wider a channel bandwidth the greater is its capacity. As narrower channel bandwidths take up less spectrum, selecting a narrow channel bandwidth may be a better choice when operating in locations where the spectrum is very busy. Both ends of the link must be configured to operate on the same channel bandwidth. Link planning This section describes factors to be taken into account when planning links, such as range, obstacles path loss, and throughput. Range and obstacles Calculate the range of the link and identify any obstacles that may affect radio performance. Perform a survey to identify all the obstructions (such as trees or buildings) in the path and to assess the risk of interference. This information is necessary to achieve an accurate link feasibility assessment. Path loss Path loss is the amount of attenuation the radio signal undergoes between the two ends of the link. The path loss is the sum of the attenuation of the path if there were no obstacles in the way (Free Space Path Chapter 3: System Planning 143 Loss), the attenuation caused by obstacles (Excess Path Loss), and a margin to allow for possible fading of the radio signal (Fade Margin). The following calculation needs to be performed to judge whether a particular link can be installed:
Where:
Is:
Free Space Path Loss (dB) Excess Path Loss (dB) Fade Margin Required (dB) Seasonal Fading (dB) Equipment Capability (dB) Free space path loss is a major determinant in received (Rx) signal level. Rx signal level, in turn, is a major factor in the system operating margin (fade margin), which is calculated as follows:
SystemOperatingMargin(fademargin)dB=Rxsignallevel(dB)Rxsensitivity(dB) Thus, the fade margin is the difference between the strength of the received signal and the strength that the receiver requires for maintaining a reliable link. Adaptive modulation Adaptive modulation ensures that the highest throughput that can be achieved instantaneously will be obtained, taking account of propagation and interference. When the link has been installed, web pages provide information about the link loss currently measured by the equipment, both instantaneously and averaged. Data network planning This section describes factors to be considered when planning ePMP data networks. Ethernet interfaces The ePMP Ethernet ports conform to the specifications listed in Table 130. Table 130 Ethernet bridging specifications Ethernet Bridging Specification Protocol 10BASE-Te/100BASE-Tx/1000BASE-T IEEE 802.3 IEEE 802.3at (PoE) IEEE802.3u compliant Auto-negotiation Chapter 3: System Planning 144 Ethernet Bridging Specification Interface 10/100/1000BASE-T (RJ-45) Maximum Ethernet Frame Size 1700 bytes Service classes for bridged traffic 3 classes Note Practical Ethernet rates will depend on network configuration, higher layer protocols, and platforms used. Over the air, throughput will be capped to the rate of the Ethernet interface at the receiving end of the link. Management VLAN Decide if the IP interface of the device management agent will be connected in a VLAN. If so, decide if this is a standard (IEEE 802.1Q) VLAN or provider bridged (IEEE 802.1ad) VLAN, and select the VLAN ID for this VLAN. The use of a separate management VLAN is strongly recommended. The use of the management VLAN helps to ensure that the device management agent cannot be accessed by customers. Quality of service for bridged Ethernet traffic Decide how the quality of service will be configured in ePMP to minimize frame loss and latency for high-
priority traffic. Wireless links often have lower data capacity than wired links or network equipment like switches and routers, and quality of service configuration is most critical at network bottlenecks. ePMP provides three priority types for traffic waiting for transmission over the wireless link Voice, High and Low. Low is the lowest priority and Voice is the highest priority. Traffic is scheduled using strict priority; in other words, traffic in a given priority is transmitted when all higher-priority transmissions are complete. Chapter 3: System Planning 145 Chapter 4: Using the Device Management Interface This chapter describes all configuration and alignment tasks that are performed when an ePMP system is deployed. Configure the units by performing the following tasks:
l Preparing for configuration l Connecting to the unit l Using the web interface l Using the installation wizard Access Point l Using the installation wizard Subscriber Module l Using the menu options Preparing for configuration This section describes the checks to be performed before proceeding with the unit configuration. Safety precautions All national and local safety standards must be followed while configuring the units. Warning Ensure that personnel is not exposed to unsafe levels of RF energy. The units start to radiate as soon as they are powered up. Respect the safety standards defined in Compliance with safety standards, in particular, the minimum separation distances. Observe the following guidelines:
l Never work in front of the antenna when the device is powered. l Always power down the power supply before connecting or disconnecting the Ethernet cable from the module. Regulatory compliance All applicable radio regulations must be followed while configuring the units and aligning the antennas. For more information, refer to Compliance with safety standards section. Connecting to the unit To connect the unit to a management PC, perform the following procedures:
l Configuring the management PC l Connecting to the PC and powering up Chapter 4: Using the Device Management Interface 146 Configuring the management PC Perform the following procedure to configure the local management PC to communicate with the ePMP module. Procedure 1 Select Properties for the Ethernet port. In Windows 7 this is found in Control Panel > Network and Internet
Network Connections > Local Area Connection. 2 Select the Internet Protocol (TCP/IP) menu. 3 Click Properties. Figure 62: LocalArea ConnectionProperties dialogbox 4 Enter an IP address that is valid for the 169.254.1.x network, avoiding 169.254.1.1. A good example is 169.254.1.100. 5 Enter a subnet mask of 255.255.255.0. Leave the default gateway blank. 6 Click OK and then click Close. Connecting to the PC and powering up Perform the following procedure to connect a management PC directly to the ePMP for configuration and alignment purposes and to power up the ePMP device. Procedure 1. Verify that the device and power supply are connected correctly (the device Ethernet port is connected to the power supply Ethernet power port (GigabitData+Poweror 10/100Mbit Data+Power). 2. Connect the PC Ethernet port to the LAN ( GigabitDataor 10/100MbitData) port of the power supply using a standard (not crossed) Ethernet cable. 3. Apply main or battery power to the power supply. The Green power LED must blink continuously. Note If the power and Ethernet LEDs do not blink continuously, check Testing hardware section to troubleshoot. Chapter 4: Using the Device Management Interface 147 Using the web interface This section describes how to use the ePMP web interface. l Logging into the web interface Logging into the web interface Perform the following procedure to log into the web interface as a system administrator. Equipment and tools l ePMP device connected to the power supply by Ethernet cable. l PC is connected to the power supply by Ethernet cable. l Power supply powered up. l Minimum supported browser version Chrome v29, Firefox v24, Internet Explorer 10, Safari v5. Procedure 1. Verify that the device and power supply are connected correctly (the device Ethernet port is connected to the power supply Ethernet power port (GigabitData+Poweror 10/100Mbit Data+Power). 2. Configure the host machine with an IP address in the 169.254.1.x subnet (excluding 169.254.1.1). 3. Configure the host machine with an IP address in the 169.254.1.x subnet (excluding 169.254.1.1). 4. Connect the power supply to power mains. 5. From the browser, navigate to the device's default IP address 169.254.1.1. 6. Log in with admin username and admin password. Note If Device IP address Mode is set to DHCP and the device is unable to retrieve IP address information via DHCP, the device management IP is set to 192.168.0.1 (AP Mode), 192.168.0.2
(SM mode), or the previously-configured static Device IP Address. Units may always be accessed via the Ethernet port at 169.254.1.1. Chapter 4: Using the Device Management Interface 148 Note All the new ePMP devices contain default username and password configurations. It is recommended to change the password configurations immediately. These passwords may be configured in the management UI in section Configuration > System > Account Management. Using the installation wizard Access Point The ePMP device provides a guided configuration mechanism for configuring key parameters for the link operation. This setup can be accessed from the Installation page by clicking the button. Click Finish Setup to commit the changes to the device. Step 1: Main system parameters Figure 63: QuickStartpage Attribute Description Main Device Name The configured identifier used in an NMS such as cnMaestro Backward Compatibility Enabled: 802.11n ePMP subscribers can register to the AP (requires subscriber software upgrade). Disabled: 802.11n ePMP subscribers are not able to register to the AP. SSID SSID is a unique identifier for a wireless LAN which is specified in the APs beacon.
(Access Point Mode). SSID must be the same at both ends and different from the site name. Chapter 4: Using the Device Management Interface 149 Step 2: Radio parameters Figure 64: Radioparameterspage Attribute Description Radio Country Defines the country code being used by the device. The country code of the Subscriber Module follows the country code of the associated AP unless it is an FCC SKU in which case the country code is the United States or Canada. Country code defines the regulatory rules in use for the device. Driver Mode TDD: The device is operating in point-to-multipoint (PMP) mode using TDD scheduling. The AP can GPS synchronize in this mode. ePTP Master: The AP is operating as a Master in point-to-point mode. The AP does not support GPS Synchronization in this mode but can provide significantly lower latency than other modes. QoS (MIR and traffic priority) capability and Link Quality/Capacity indicators are not available in this mode. TDD PTP: The APis operating in point-to-point (PTP) mode using TDD scheduling. The AP can GPS synchronize in this mode. The schedule of downlink traffic to uplink traffic on the radio link. The three options, 75/25, 50/50, and 30/70, allow the radio to operate in a fixed ratio on every frame. In other words, this ratio represents the amount of the total radio links aggregate throughput that will be used for downlink resources, and the amount of the total radio links aggregate throughput that will be used for uplink resources. Downlink/Uplink Ratio Chapter 4: Using the Device Management Interface 150 Attribute Description Max Range Channel Bandwidth This parameter represents the cell coverage radius. Subscriber Modules outside the configured radius will not be able to connect. It is recommended to configure Max Range to match the actual physical distance of the farthest subscriber. Configure the channel size used by the radio for RF transmission. Frequency Carrier Configure the frequency carrier for RF transmission. This list is dynamically adjusted to the regional restrictions based on the setting of the Country parameter. Ensure that a thorough spectrum analysis has been completed before configuring this parameter. Step 3: Network parameters Figure 65: Networkparameterspage Attribute Description Network IP Assignment Static: Device management IP addressing is configured manually in fields IP Address, Subnet Mask, Gateway, Preferred DNS Server, and Alternate DNS Server. DHCP: Device management IP addressing (IP address, Subnet Mask, Gateway, and DNS Server) is assigned via a network DHCP server, and parameters IP Address, Subnet Mask, Gateway, Preferred DNS Server, and Alternate DNS Server are not configurable. IP Address Internet protocol (IP) address. This address is used by the family of Internet protocols to uniquely identify this unit on a network. If IP Address Assignment is set to DHCP and the device is unable to retrieve IP address information via DHCP, the device management IP is set to fallback IP 192.168.0.1 (AP) or 192.168.0.2 (SM). Chapter 4: Using the Device Management Interface 151 Attribute Description Subnet Mask Defines the address range of the connected IP network. For example, if the IP Address is configured to 192.168.2.1 and Subnet Mask is configured to 255.255.255.0, the device will belong to subnet 192.168.2.X. Gateway Configure the IP address of the deviceon the current network that acts as a gateway. A gateway acts as an entrance and exit to packets from and to other networks. Preferred DNS Server Alternate DNS Server Configure the primary IP address of the server used for DNS resolution. Configure the secondary IP address of the server used for DNS resolution. Step 4: Security parameters Figure 66: Securityparameterspage Attribute Description Network Wireless Security Open: All Subscriber Module devices requesting network entry are allowed registration. WPA2: The WPA2 mechanism provides AES radio link encryption and Subscriber Module network entry authentication. When enabled, the Subscriber Module must register using the Authentication Pre-shared Key configured on the AP and Subscriber Module. RADIUS: Enables Subscriber Module authentication via a pre-configured Radius server. Chapter 4: Using the Device Management Interface 152 Attribute Description WPA2 Pre-
shared Key Servers GUI User Authentication Configure this key on the AP, then configure the Subscriber Module with this key to complete the authentication configuration. This key must be between 8 to 128 symbols. Up to 3 RADIUS servers can be configured on the device with the following attributes:
IP Address: IP Address of the RADIUS server on the network. Port: The RADIUS server port. The default is 1812. Secret: Secret key that is used to communicate with the RADIUS server. This parameter applies to both the AP and its registered SMs. Device Local Only: The device GUI authentication is local to the device using one of the accounts configured under Configuration > System > Account Management. Remote RADIUS Server Only: The device GUI authentication is performed using a RADIUS server. Remote RADIUS Server and Fallback to Local: The device GUI authentication is performed using a RADIUS server. Upon failure of authentication through a RADIUS server, the authentication falls back to one of the local accounts configured under Configuration > System > Account Management. Using the installation wizard Subscriber Module The ePMP device features a guided configuration mechanism for configuring key parameters for link operation. This setup is accessed on the Installation page by clicking the Start Setup button. Click Finish Setup to commit the changes to the device. Step 1: Main system parameters Chapter 4: Using the Device Management Interface 153 Figure 67: Mainsystemparameterspage Attribute Description Main Device Name Radio Mode The configured identifier used in an NMS such as cnMaestro This parameter controls the function of the device All ePMP devices are configured to operate as an Access Point (AP) or a Subscriber Module (SM). Step 2: Radio parameters Figure 68: Radioparameterspage Attribute Description Radio Preferred APs SSID The Preferred Access Points SSID defines the AP SSID to which the Subscriber Module
(SM) device attempts the registration. Wireless Security Open: The SM device attempts the registration to preferred APs SSID with no security mechanism. WPA2: The WPA2 mechanism provides AES radio link encryption and SM network entry authentication. When enabled, the SMmust register using the Authentication Pre-shared Key configured on the AP and SM. WPA2 Pre-
shared Key The Preferred Access Points WPA2 Pre-shared Key must be configured on the SM device to match the pre-shared key configured on the Access Point for registration with WPA2 security. Chapter 4: Using the Device Management Interface 154 Attribute Description Scan Channel Bandwidth Configure the channel size used by the radio for RF transmission. Radio Frequency Scan List Configure the frequency carrier for RF transmission. This list is dynamically adjusted to the regional restrictions based on the setting of the Country parameter. Ensure that a thorough spectrum analysis is completed before configuring this parameter. Step 3: Network parameters Figure 69: Networkparameterspage Attribute Description Network Network Mode NAT: The SM acts as a router and packets are forwarded or filtered based on their IP header (source or destination). Bridge: The SM acts as a switch and packets are forwarded or filtered based on their MAC destination address. Router: The SM acts as a router and packets are forwarded or filtered based on their IP header (source or destination) using specific static routes and IP aliases configured by the operator. IP Assignment Static: Device management IP addressing is configured manually in fields IP Address, Subnet Mask, Gateway, Preferred DNS Server, and Alternate DNS Server. DHCP: Device management IP addressing (IP address, Subnet Mask, Gateway, and DNS Server) is assigned via a network DHCP server, and parameters IP Address, Subnet Mask, Gateway, Preferred DNS Server, and Alternate DNS Server are not configurable. IP Address Internet protocol (IP) address. This address is used by the family of Internet protocols to uniquely identify this unit on a network. If IP Address Assignment is set to DHCP and the device is unable to retrieve IP address information via DHCP, the device management IP is set to fallback IP 192.168.0.1 (AP) or 192.168.0.2 (SM). Chapter 4: Using the Device Management Interface 155 Attribute Description Subnet Mask Defines the address range of the connected IP network. For example, if the IP Address is configured to 192.168.2.1 and Subnet Mask is configured to 255.255.255.0, the device belongs to subnet 192.168.2.X. Gateway Configure the IP address of the deviceon the current network that acts as a gateway. A gateway acts as an entrance and exit to packets from and to other networks. Preferred DNS Server Alternate DNS Server Configure the primary IP address of the server used for DNS resolution. Configure the secondary IP address of the server used for DNS resolution. Installation wizard step 4 Security parameters Attribute Network Description EAP-TTLS Username Configure the EAP-TTLS Username to match the credentials on the RADIUS server being used for the network. Use Ethernet MAC Address at EAP-TTLS Username EAP-TTLS Password The device MAC Address can be used as the EAP-TTLS Username in either :
or - delimited format. Configure the EAP-TTLS Password to match the credentials on the RADIUS server being used for the network. Authentication Identity String Configure this identity string to match the credentials on the RADIUS server being used for the network. The default value for this parameter is anonymous. Authentication Identity Realm Configure this identity string to match the credentials on the RADIUS server being used for the network. The default value for this parameter is cambiumnetworks.com. Chapter 4: Using the Device Management Interface 156 Using the menu options Use the menu navigation bar in the left panel to navigate to each web page. Some of the menu options are only displayed for specific system configurations. Refer the Table 131 to locate information about using each web page. Table 131 Menu options and web pages Main menu Menu option Web page information Status Installation Configuration Radio System Network Security Status page Installation page Configuration menu Configuration > Radio page Configuration > System page Configuration > Network page Configuration > Security page Monitor Monitor menu Performance Monitor > Performance page System Wireless Monitor > System page Monitor > Wireless page Throughput Chart Monitor > Throughput Chart page GPS Monitor > GPS page (Access Point mode) Network Monitor > Network page System Log Monitor > System Log page Tools Tools menu Software Upgrade Tools > Software Upgrade page Backup / Restore Tools > Backup/Restore page License Management Tools > License Management page (Access Point Mode) Spectrum Analyzer Tools > Spectrum Analyzer page eAlign Tools > eAlign page Wireless Link Test Tools > Wireless Link Test page Watchdog Tools > Watchdog page Ping Tools > Ping page Traceroute Tools > Traceroute page Chapter 4: Using the Device Management Interface 157 Status page The status page describes the status information of the QoE device. Figure 70: Statuspage Table 132 Status page attributes Attribute Description Device Name The configured device name of the AP, used for identifying the device in an NMS such as the Cambium Network Services Server (CNSS). SSID The current configured name/SSID of the AP. Operating Frequency The current frequency carrier used for radio transmission, based on the configuration of the Frequency Carrier parameter (in DFS regions, if radar has been detected, this field may display either DFS Alternate Frequency Carrier 1 or DFS Alternate Frequency Carrier 2). Operating Channel Bandwidth The current channel bandwidth used for radio transmission, based on the configuration of the Channel Bandwidth parameter. Transmitter Output Power The current operating transmit power of the AP. Antenna Gain The configured gain of the external antenna. Country The current configured country code, which has an effect on DFS operation and transmits power restrictions. Registered Subscriber Modules will inherit this country code when registration is complete (unless SM is locked to the US region). Chapter 4: Using the Device Management Interface 158 Attribute Description Access Point Mode TDD: The Access Point is operating in point-to-multipoint (PMP) mode using TDD scheduling. The AP can GPS synchronize in this mode (except when in Flexible mode). ePTP Master: The Access Point is operating as a Master in point-to-point mode. The AP does not support GPS Synchronization in this mode but can provide significantly lower latency than other modes. QoS (MIR and traffic priority) capability and Link Quality/Capacity indicators are not available in this mode. PTP: The Access Point is operating in point-to-point (PTP) mode using TDD scheduling. The AP can GPS synchronize in this mode (except when in Flexible mode). The current configured schedule of downlink traffic to uplink traffic on the radio link. In other words, this ratio represents the amount of the total radio links aggregate throughput that will be used for downlink resources and the amount of the total radio links aggregate throughput that will be used for uplink resources. Downlink/Uplink Frame Ratio Wireless Security Currently configured authentication type used for radio link encryption as well as SM authentication. cnMaestro Remote Management Indicates whether the device is currently configured to be managed by the Cambium cloud management system cnMaestro. cnMaestro Connection Status The current management status of the device concerning the Cambium Cloud Server. When Enabled under Configuration > System, the device will be managed by the Cambium Remote Management System, which allows all Cambium devices to be managed from the Cambium Cloud Server. cnMaestro Account ID The ID that the device is currently using to be managed by the Cambium Cloud Server. Wireless MAC Address Ethernet MAC Address SFP Port MAC Address IP Address The MAC address of the device wireless interface. The MAC address of the device Ethernet (LAN) interface. The MAC address of the device SFP interface. The currently configured device IP address (LAN) is used for management access. IPv6 Link Local Address A link-local address is required for the IPv6-enabled interface (applications may rely on the link-local address even when there is no IPv6 routing). The IPv6 link-
local address is comparable to the auto-configured IPv4 address 169.254.0.0/16. IPv6 Address The IPv6 address for device management. Date and Time The current date and time on the device, subject to the configuration of the parameter Time Zone. System Uptime The total uptime of the radio since the last reset. Chapter 4: Using the Device Management Interface 159 Attribute Description System Description The current configured system description. Sync Source Status Displays the current status of sync timing for the AP. Device Coordinates The current configured Latitude and Longitude coordinates in decimal format. DFS Status N/A: DFS operation is not required for the region configured in parameter Country Code. Channel Availability Check: Before transmitting, the device must check the configured Frequency Carrier for radar pulses for 60 seconds). If no radar pulses are detected, the device transitions to state In-Service Monitoring. In-Service Monitoring: Radio is transmitting and receiving normally while monitoring for radar pulses that require a channel move. Radar Signal Detected: The receiver has detected a valid radar pulse and is carrying out detect-and-avoid mechanisms (moving to an alternate channel). In-Service Monitoring at Alternative Channel: The radio has detected a radar pulse and has moved the operation to a frequency configured in DFS Alternative Frequency Carrier 1 or DFS Alternative Frequency Carrier 2. System Not In Service due to DFS: The radio has detected a radar pulse and has failed channel availability checks on all alternative frequencies. The non-
occupancy time for the radio frequencies in which radar was detected is 30 minutes. Ethernet Status Up: The Ethernet (LAN) interface is functioning properly. This also displays the current port speed and duplex mode to which the Ethernet port has auto negotiated to or configured. Down: The Ethernet (LAN) interface is either disconnected or has encountered an error and is not servicing traffic. Wireless Status Up: The radio (WAN) interface is functioning properly Down: The radio (WAN) interface has encountered an error and is not servicing traffic. SFP Port Displays the current port speed and duplex mode to which the SFP port has auto-negotiated or displays the current port speed and duplex mode that have been configured manually. SFP Port Type Displays the type of SFP module connected to the device. Registered Subscriber Modules The total number of SMs currently registered to the AP. Registered Elevate Subscriber Modules The total number of ePMP Elevate (third-party software solution) subscribers registered to the AP. Installation page For more information on the installation page, refer to Using the installation wizard Access Point and Using the installation wizard Subscriber Module sections. Chapter 4: Using the Device Management Interface 160 Configuration menu Use the Configuration menu to access all applicable device configuration parameters. Configuration > Radio page Figure 71: Configuration>Radiopage(APmode) Note The Trial Configuration allows you to try a configuration change without applying the configuration. Chapter 4: Using the Device Management Interface 161 Figure 72: Configuration>Radiopage(SMmode) Table 133 Configuration > Radio page attributes Attribute Description General Driver Mode TDD: The device is operating in Point-to-Multipoint (PMP) mode using TDD scheduling. The AP can GPS synchronize in this mode. ePTP Slave: The SM is operating as a Slave in point-to-point mode. The AP and the system do not support GPS Synchronization in this mode but can provide significantly lower latency than other modes. QoS (MIR and traffic priority) capability and Link Quality/Capacity indicators are not available in this mode. TDD PTP: The Access Point is operating in point-to-point (PTP) mode using TDD scheduling. The AP can GPS synchronize in this mode. Radio Mode Access Point: The unit controls the point-to-point link and its maintenance. On startup, the Access Point transmits until a link with the Subscriber Module is made. Subscriber Module: The unit listens for its peer and only transmits when the peer has been identified. Chapter 4: Using the Device Management Interface 162 Attribute Description Backward Compatibility
(Access Point Mode) Country
(Access Point Mode) Range Unit
(Access Point Mode) Enabled: 802.11n ePMP subscribers can register to the AP (requires subscriber software upgrade). Disabled: 802.11n ePMP subscribers are not able to register to the AP. Defines the country code being used by the device. The country code of the Subscriber Module follows the country code of the associated Access Point unless it is an FCC SKU in which case the country code is the United States or Canada. Country code defines the regulatory rules in use for the device. Units of measurement on the device are displayed in either miles (m) or kilometers
(km). Access Point Configuration (AP mode) Antenna Sector: Panel, 90 or Dual-Horn, 60
(Access Point Mode) SSID
(Access Point Mode) Max Registrations Allowed
(Access Point Mode) Omni: KP-5QSOMNI-13 SSID is a unique identifier for a wireless LAN which is specified in the APs beacon.
(AP mode). SSID must be the same at both ends and different from the site name. Based on sector/network planning and subscriber service level implementations, this parameter allows setting the maximum number of subscribers that are allowed to register/gain network entry. The maximum number of subscribers allowed for each channel bandwidth is as follows:
l 20/40 MHz: 120 subscribers l 10 MHz: 60 subscribers l 5 MHz: 30 subscribers The maximum registrations allowed depending on the channel bandwidth of the current operating frequency which can be the primary Frequency Carrier or one of the alternate Frequency Carriers. For DFS regions, the maximum number of subscribers is based on the channel bandwidth of the current operating channel. That is Frequency Carrier, Alternate Frequency Carrier 1, or Alternate Frequency Carrier 2. The number of elevate devices that are allowed to register is specified by the applied license. Max Range
(Access Point Mode) This parameter represents the cell coverage radius. Subscriber Modules outside the configured radius will not be able to connect. It is recommended to configure Max Range to match the actual physical distance of the farthest subscriber. Chapter 4: Using the Device Management Interface 163 Attribute Description Configure the channel size used by the radio for RF transmission. Channel Bandwidth
(Access Point Mode) Frequency Carrier
(Access Point Mode) Configure the frequency carrier for RF transmission. This list is dynamically adjusted to the regional restrictions based on the setting of the Country parameter. Ensure that a thorough spectrum analysis has been completed before configuring this parameter. Frequency Reuse
(Access Point Mode) The Frequency Reuse parameter allows operators to define which APs are co-
located (or within radio range) with other APs. This definition results in an automatic radio network modification such that self-interference is reduced amongst the co-located sectors. A network in which two frequencies F1 and F2 are reused throughout the installation is shown in Figure 72. Note that CMM3 and CMM4 devices cannot be used as synchronization sources for ePMP 3000, the parameter setting suggestions below serve as a guideline for mixed 802.11n and 802.11ac networks. Figure 73: Frequencyreuseinstallation The set of APs to configure the Frequency Reuse option is dependent on the GPS synchronization sources in the whole network, CMM3, CMM4, CMM5, or GPS. 0B0BThe GPS sync source is the same on all APs or is a combination of GPS, CMM4, CMM5 In this configuration the GPS synchronization source in the whole network is one of the following:
l GPS l CMM4 Chapter 4: Using the Device Management Interface 164 Attribute Description l CMM5 The rules in selecting the APs to enable the Frequency Reuse in this installation are:
Only ONE of the APs on the same tower configured with the same frequency must be configured with the Frequency Reuse Mode parameter set to Back Sector; the other AP must be configured with Frequency Reuse set to Front Sector. Also, APs on different towers facing each other with overlapped coverage must be configured with Frequency Reuse set to Back Sector. 1B1BThe GPS sync source is a mixture of all types (CMM3, CMM4, CMM5 or GPS) In this configuration the GPS sync source in the whole network is one of the following:
l (CMM3 and GPS) or l (CMM3 and CMM4 / CMM5) or l (CMM3 and CMM4 / CMM5 and GPS) The rules in selecting the APs to configure Frequency Reuse to Frequency Reuse to Front Sector or Back Sector in a mixture of sync sources installations are:
Only ONE of the APs on the same tower configured with the same frequency must have Frequency Reuse set to Back Sector if the sync source of both APs is the same or the sync is a combination of GPS and CMM4 / CMM5; the other AP has the Front Sector ON. For the APs on different towers facing each other with overlapped coverage:
l l l l l If both APs have the same sync source, then only ONE of them must have the Back Sector ON; the other AP shall have the Front Sector ON. If one AP has GPS as sync source and the other one has CMM4 / CMM5 then only ONE of them must have Back Sector ON; the other AP shall have Front Sector ON. If one AP has GPS or CMM4 / CMM5 as sync source and the other one has CMM3. If the AP with CMM3 sync source has Back Sector ON, then the other AP
(with GPS or CMM4 / CMM5 sync source) must have the Back Sector ON. If the AP with CMM3 sync source has Frequency Reuse set to Off, then the other AP (with GPS or CMM4 CMM5 sync source) must have Frequency Reuse set to OFF. Power Control Chapter 4: Using the Device Management Interface 165 Attribute Description Transmitter Output Power
(Access Point Mode) Transmitter Output Power is the total transmit power of the device. The device has four transmit chains and total transmit power sums the power from all chains. This does not include antenna gain. Transmitter Output Power may be limited by regulatory rules for the country in use. Antenna Gain The total gain of the antenna in use by the device. Defines the desired received power level at the AP from the registered Subscriber Module. APs use this parameter to control the transmission power of the Subscriber Module to reduce system self-interference. Subscriber Module Target Receive Level
(Access Point Mode) Network Entry RSSI Threshold This defines the Downlink RSSI threshold below which a Subscriber Module will not register to an Access Point.
(Subscriber Module Mode) Network Entry SNR Threshold This defines the Downlink Signal-to-Noise-Ratio (SNR) threshold below which the Subscriber Module will not register to an Access Point.
(Subscriber Module Mode) Synchronization (AP mode) Co-location Mode Disabled: The ePMP device can synchronize only with other ePMP APs.
(Access Point Mode) Synchronization Source
(Access Point Mode) Enabled: The ePMP device can be configured to synchronize with PMP 100 or PMP 450 series of radios in addition to other ePMP APs. Please refer to the ePMP and PMP 100 Co-location and Migration Recommendations Guide for guidance on synchronizing ePMP and PMP 100. Verify that frame size (ms) is configured equally across the co-located installations. GPS: Synchronization timing is received via the APs connected GPS antenna. Co-
located or in-range APs receiving synchronization via GPS or CMM transmits and receive at the same time, thereby reducing self-interference. CMM5: Synchronization timing is received via the APs Ethernet port via a connected Cambium Cluster Management Module 5 (CMM5). Co-located or in-
range APs receiving synchronization via GPS or CMM will transmit and receive at the same time, thereby reducing self-interference. For more information on CMM configuration, refer to the PMP Synchronization Solutions User Guide. If a CMM is being used, verify that the cables from the CMM to the network switch are at most 30 ft (shielded) or 10 ft (unshielded) and that the network switch is not PoE (802.3af). Internal: Synchronization timing is generated by the AP and the timing is not based on GPS pulses. Chapter 4: Using the Device Management Interface 166 Attribute Description Synchronization Holdoff Time
(Access Point Mode) APs using synchronization source of Internal does not transmit and receive in sync with other co-located or in-range APs, which introduces self-interference into the system. The Synchronization Holdoff Time is designed to gracefully handle fluctuations/losses in the GPS synchronization signaling. After the AP has received a reliable synchronization pulse for at least 60 seconds, if there is a loss of synchronization signal, the Synchronization Holdoff timer is started. During the holdoff interval, all SM registrations are maintained. If a valid GPS synchronization pulse is regained during the holdoff interval, then the AP continues to operate normally. If a valid synchronization pulse is not regained from the GPS source during the holdoff interval, then the AP ceases radio transmission. The default is 30 seconds. Preferred Access Points (SM mode) Preferred Access Points list
(Subscriber Module Mode) The Preferred Access Points List is comprised of a list of up to 16 Access Point devices to which the SM device sequentially attempts registration. For each AP configured, if authentication is required, enter the Wireless Security type and WPA2 Pre-shared Key associated with the configured SSID. Scheduler (AP mode) Downlink/Uplink Ratio
(Access Point Mode) The schedule of downlink traffic to uplink traffic on the radio link. The three options, 75/25, 50/50, and 30/70, allow the radio to operate in a fixed ratio on every frame. In other words, this ratio represents the amount of the total radio links aggregate throughput that is used for downlink resources, and the amount of the total radio links aggregate throughput that is used for uplink resources. Guard interval
(Access Point Mode) Downlink Max Rate
(AP mode) The purpose of the guard interval is to introduce immunity to propagation delays, echoes, and reflections, to which digital data is normally very sensitive. Longer guard periods allow more distant echoes to be tolerated. However, longer guard intervals reduce channel efficiency. Specifies the maximum downlink MCS value that the Rate Adapt algorithm will choose for Radio 1. If an installation is exhibiting packet loss due to downlink interference, modifying Downlink Max Rate to limit the device's maximum MCS rate may result in more reliable packet delivery. This is especially true in installations among changing and unpredictable interference. Note This setting is not available when the AP is set to ePTP Master mode. Radio Configuration Maximum Tx Power
(SM mode) Auto: The APcan control, using ATPC (Automatic Transmit Power Control), the TX power of the SM up to the maximum capability of the SMs transmitter (based on regulatory limits). Manual: The AP can control the TX power of the SM up to the value configured in the Transmitter Power field. Chapter 4: Using the Device Management Interface 167 Attribute Description Transmitter Output Power
(SMmode) The total transmit power of the radio interface. The device has four transmit chains for each channel and total transmit power sums the power from all chains. This does not include antenna gain. Transmitter output power may be limited by regulatory rules for the country in use. Uplink Maximum Rate
(SM mode) Specifies the maximum uplink MCS value that the Rate Adapt algorithm chooses for Radio 1. If an installation is exhibiting packet loss due to uplink interference, modifying Uplink Max Rate to limit the device's maximum MCS rate may result in more reliable packet delivery. This is especially true in installations among changing and unpredictable interference. Note This setting is not available when the SM is set to ePTP Slave mode. Scan Channel Bandwidth
(Subscriber Module Mode) The selected scan channel bandwidths are scanned by the SM. Any combination may be selected. When bandwidth is selected, a tab for the bandwidth appears and a listing of all available channels is presented once the tab for the bandwidth is selected. Each bandwidth tab may contain a number on the left side. This number defines how many channels have been selected for that bandwidth. If no channels are selected for bandwidth, then all channels are scanned. Configuration > Quality of Service (QoS) The AP Quality of Service (QoS) page The ePMP platform supports three QoS priority levels (not available in ePTP Master mode) using air fairness, priority-based starvation avoidance scheduling algorithm. Ordering of traffic amongst the priority levels is based on a percentage of total link throughput. In other words, all priorities receive some throughput so that low priority traffic is not starved from the transmission. In effect, the greatest amount of throughput is guaranteed to the VOIP priority level, then High, then Low. Priority Level ePMP Traffic Priority Label Highest Priority VOIP (only utilized when VOIP Enable is set to Enabled) Medium Priority High Lowest Priority Low By default, all traffic passed over the air interface is a low priority. The APs Quality of Service page may be utilized to map traffic to certain priority levels using QoS classification rules. The rules included in the table are enforced starting with the first row of the table. Warning Each additional traffic classification rule increases device CPU utilization. Careful network traffic planning is required to efficiently use the device processor. Chapter 4: Using the Device Management Interface 168 The ePMP platform also supports radio data rate-limiting (Maximum Information Rate, or MIR) based on the configuration of the MIR table. Operators may add up to 16 MIR profiles on the AP, each with unique limits for uplink and downlink data rates. The SM field MIR Profile Setting is used to configure the appropriate MIR profile for limiting the SMs data rate. Figure 74: Configuration>APQualityofServicepage Table 134 AP Radio Configuration attributes Attribute Description Maximum Information Rate (MIR) MIR Disabled: When disabled, RF transmission is only limited by the capacity of the link
(and any active QoS classification rules). MIR Profiles Number Description Enabled: When enabled, all downlink and uplink traffic is limited based on the profiles configured in the MIR table. The MIR (Maximum Information Rate) table is comprised of up to sixteen profiles which, after configured, may be set on the SM to employ a certain service level or data rate. Assign a profile number to each row in the AP MIR table. This profile number is then set on each SM to limit data transfer rates based on the operators configuration of the MIR table and its profiles. Assign a logical description for each service level. For example, a tiered service-level provider may deploy service levels Gold, Silver and Bronze or 20 Mbps, 10 Mbps and 5 Mbps to offer a clear description. Downlink MIR
(kbps) Specify the downlink rate at which the AP is allowed to transmit for this configured profile. Chapter 4: Using the Device Management Interface 169 Attribute Description Uplink MIR
(kbps) Specify the uplink rate at which the AP is allowed to transmit for this configured profile. Traffic Priority Traffic Priority Disabled: No traffic prioritization is performed. All traffic is treated with equal priority
(low priority). Enabled: Traffic prioritization is enabled, and specific types of traffic can be prioritized using the fields below. VoIP Priority Enabled: When enabled, two entries are automatically added to the first and second rows of the QoS Classification Rules table, one with Rule Type CoS (5) and one with Rule Type DSCP (46). The addition of these rules ensures that VoIP traffic passed over the radio downlink is given the highest priority. The CoS and DSCP values may be modified to accommodate non-standard VoIP equipment. Disabled: When disabled, VoIP traffic is scheduled normally along with all other user data. Broadcast Priority Low Priority: All broadcast traffic sent over the downlink is prioritized as low priority and is delivered to the SM after scheduled high priority and VoIP traffic. High Priority: All broadcast traffic sent over the downlink is prioritized as a high priority and is scheduled for delivery to SMs before low priority traffic but after VoIP traffic. Multicast Priority Low Priority: All multicast traffic sent over the downlink is prioritized as low priority and will be delivered to the SM after scheduled high priority and VoIP traffic. High Priority: All multicast traffic sent over the downlink is prioritized as a high priority and is scheduled for delivery to SMs before low priority traffic but after VoIP traffic. QoS Classification Rules The QoS Classification Rules table contains all of the rules enforced by the device when passing traffic over the radio downlink. Traffic passed through the device is matched against each rule in the table; when a match is made the traffic is sent over the radio link using the priority defined in Traffic Priority column. Type CoS: Class of Service; traffic prioritization is based on the 3-bit header present in the 802.1Q VLAN-tagged Ethernet frame header in the packet entering the APs Ethernet port. VLAN ID: traffic prioritization is based on the VLAN ID of the packet entering the APs Ethernet port. EtherType: traffic prioritization is based on the two-octet Ethertype field in the Ethernet frame entering the APs Ethernet port. The Ethertype is used to identify the protocol of the data in the payload of the Ethernet frame. IP: traffic prioritization is based on the source and (or) destination IP address of the packet entering the APs Ethernet port. A subnet mask may be included to define a range of IP addresses to match. Chapter 4: Using the Device Management Interface 170 Attribute Description MAC: traffic prioritization is based on the source and (or) destination MAC address of the packet entering the APs Ethernet port. A mask may be included to define a range of MAC addresses to match. The mask is made up of a hex representation of a series of 1s to start the mask and 0s that end the mask. A 1 may not follow a 0. Thus FF:FF:FF:FF:00:00 is allowed, but FF:00:FF:FF:FF:FF is not. The MAC address is combined with the mask to define the range of allowed MAC addresses. Details Represents the details of the Class of Service (CoS) present in the packet entering the APs Ethernet port. Priority Represents the QoS classification rule priority. The SM Quality of Service page The ePMP platform supports three QoS priority levels (not available in ePTP Master mode) using air fairness, priority-based starvation avoidance scheduling algorithm. Ordering of traffic amongst the priority levels is based on a percentage of total link throughput. In other words, all priorities receive some throughput so that low priority traffic is not starved from the transmission. In effect, the greatest amount of throughput is guaranteed to the VOIP priority level, then High, then Low. Priority Level ePMP Traffic Priority Label Highest Priority VOIP (only utilized when VOIP Enable is set to Enabled) Medium Priority High Lowest Priority Low By default, all traffic passed over the air interface is a low priority. The SMs QoS page may be utilized to map traffic to certain priority levels using QoS classification rules. The rules included in the table are enforced starting with the first row of the table. Warning Each additional traffic classification rule increases device CPU utilization. Careful network traffic planning is required to efficiently use the device processor. The ePMP platform also supports radio data rate-limiting (Maximum Information Rate (MIR)) based on the configuration of the MIR table. Operators may add up to 16 MIR profiles on the AP, each with unique limits for uplink and downlink data rates. The SM field MIR Profile Setting is used to configure the appropriate MIR profile for limiting the SMs data rate. Chapter 4: Using the Device Management Interface 171 Figure 75: Configuration>SMQualityofServicepage Table 135 SM QoS attributes Attribute Description Maximum Information Rate (MIR) MIR Profile Number Configure the desired MIR (Maximum Information Rate) profile for SM operation. This profile must be configured on the AP else the default profile (0) is used. Traffic Priority Enabled: The QoS Classification Rules table is editable and is utilized by the device to classify traffic. Disabled: The QoS Classification Rules table is greyed out and all traffic is sent at one priority level. VoIP Priority Enabled: When enabled, two entries are automatically added to the first and second rows of the QoS Classification Rules table, one with Rule Type CoS (5) and one with Rule Type DSCP (46). The addition of these rules ensures that VoIP traffic passed over the radio downlink is given the highest priority. The CoS and DSCP values may be modified to accommodate non-standard VoIP equipment. Broadcast Priority Low Priority: All Broadcast traffic sent over the uplink is prioritized as low priority and is delivered to the AP after scheduled high priority and VoIP traffic. High Priority: All Broadcast traffic sent over the uplink is prioritized as a high priority and is scheduled for delivery to the AP before low priority traffic but after VoIP traffic. Multicast Priority Low Priority: All Multicast traffic sent over the uplink is prioritized as low priority and is delivered to the AP after scheduled high priority and VoIP traffic. High Priority: All Multicast traffic sent over the uplink is prioritized as a high priority and is scheduled for delivery to the AP before low priority traffic but after VoIP traffic. Chapter 4: Using the Device Management Interface 172 Attribute Description Subscriber Module Priority Normal: SM gives priority to the packets as defined in the rules which can be Low, High, or VoIP. Normal priority allows data to be added to the appropriate High, Low, and VoIP queues based on the QoS rules. This is the default setting. If no rule is defined for a packet, then the packet priority is Low. High: SM places all data other than VoIP in the High queue. It is given higher priority than SMs configured with Low and Normal when there is contention for bandwidth under the AP. Low: Low priority places all data that is not VoIP in the Low priority queue. It will be given lower priority than SMs configured with High when there is contention for bandwidth under the same AP. VoIP queue is the highest priority queue followed by the High queue and then by the Low queue. Higher priority queues have preference over lower priority queues, but does not suffer them. QoS Classification Rules The QoS Classification Rules table contains all of the rules enforced by the device when passing traffic over the radio downlink. Traffic passed through the device is matched against each rule in the table; when a match is made the traffic is sent over the radio link using the priority defined in column Traffic Priority. Type DSCP: Differentiated Services Code Point; traffic prioritization is based on the 6-bit differentiated services field in the IP header present in the packet entering the Ethernet port. CoS: Class of Service; traffic prioritization is based on the 3-bit header present in the 802.1Q VLAN-tagged Ethernet frame header in the packet entering the SMs Ethernet port. VLAN ID: Traffic prioritization is based on the VLAN ID of the packet entering the SMs Ethernet port. EtherType: Traffic prioritization is based on a 2 octet Ethertype field in the Ethernet frame entering the SMs Ethernet port. The Ethertype is used to identify the protocol of the data in the payload of the Ethernet frame. IP: Traffic prioritization is based on the source and/or destination IP addresses of the packet entering the SMs Ethernet port. A subnet mask may be included to define a range of IP addresses to match. MAC: Traffic prioritization is based on the source and/or destination MAC addresses of the packet entering the SMs Ethernet port. A mask may be included to define a range of MAC addresses to match. The mask is made up of a hex representation of a series of 1s to start the mask and 0s that end the mask. A 1 may not follow a 0. Thus, FF:FF:FF:FF:00:00 is allowed, but FF:00:FF:FF:FF:FF is not. The MAC address is combined with the mask to define the range of allowed MAC addresses. Details Priority The Rule Details column is used to further configure each classification rule specified in column Rule Type. High: Traffic entering the SMs Ethernet port is prioritized as high priority for sending over the radio link (traffic will be sent after VOIP-classified traffic but before Low-
classified traffic). Chapter 4: Using the Device Management Interface 173 Attribute Description Low: Traffic entering the SMs Ethernet port is prioritized as low priority for sending over the radio link (traffic will be sent after VOIP-classified and High-classified traffic is sent). Configuration > System page Figure 76: Configuration>Systempageparameters Table 136 Configuration > System page attributes Attribute Description General Device Name The configured identifier is used in an NMS such as cnMaestro. Display Device Name Before Login Disabled: For security, the configured Device Name is hidden on the device login screen. Enabled: The configured Device Name is displayed upper-left on the device login screen. Chapter 4: Using the Device Management Interface 174 Attribute Description Inactive Logout Disabled: The device does not automatically log out users after a period of inactivity. Enabled: After the period configured in the Inactive Logout Period has elapsed, the device automatically log out the user. Inactive Logout Period Represents the amount of time for which a user remains logged in. After this period has elapsed, the user automatically logged out. Web-page Auto Update Configure the interval for which the device retrieves system statistics for display on the management interface. For example, if this setting is configured to 5 seconds, the statistics and status parameters displayed on the management interface is refreshed every 5 seconds (default). Webpage Auto Update is a session-only configuration change. It is updated with the Enterkey and is not savable when using the Save button. Range Unit Units of measurement on the device are displayed in either miles (m) or kilometers
(km). Web Access HTTP: The device's web management interface is accessed via HTTP. HTTPS: The device's web management interface may only be accessed via secure HTTPS. HTTP Port This specifies theTCP/UDPport to be used with HTTPorHTTPS. The default value forHTTPis 80 and HTTPS is 443. SSH Access Disabled: Access to the device through SSH is not possible. Enabled: Cambium Networks engineers can access the device through SSH which enables them to log in to the radio and troubleshoot. SSH Access is Enabled by default. Telnet Access Disabled: Command Line Interface access via Telnet is not allowed Enabled: Command Line Interface access via Telnet is allowed Network Time Protocol (NTP) NTP Server IP Assignment Static: The device retrieves NTP time data from the servers configured in fields NTP Server IP Address. DHCP: The device retrieves NTP time data from the server IP issued via a network DHCP server. Preferred NTP Server Configure the primary NTP server IP addresses from which the device retrieves time and date information. Alternate NTP Server Configure alternate or secondary NTP server IP addresses from which the device retrieves time and date information. Time Zone The Time Zone option may be used to offset the received NTP time to match the operators local time zone. Location Services Chapter 4: Using the Device Management Interface 175 Attribute Description On-board GPS Latitude On-board GPS Longitude On-board GPS Height GPS-retrieved Latitude information for the device in decimal format. GPS-retrieved Longitude information for the device in decimal format. GPS-retrieved height information for the device in meters. Use GPS Coordinates Click Update to retrieve device location and height information via the connected GPS source. Device Latitude Device Longitude Configure Latitude information for the device in decimal format. Configure Longitude information for the device in decimal format. Device Height Configure height above sea level for the device in meters. Device Location Hyperlink to display the device location in Google Maps Simple Network Management Protocol (SNMP) Read-Only Community String Specify a control string that can allow a Network Management Station (NMS) to read SNMP information. No spaces are allowed in this string. This password will never authenticate an SNMP user or an NMS to read/write access. Read-Write Community String System Name The Read-only Community String value is clear text and is readable by a packet monitor. Specify a control string that can allow a Network Management Station (NMS) to access SNMP information. No spaces are allowed in this string. Specify a string to associate with the physical module. This parameter can be polled by the NMS. Special characters are supported. System Description Specify a description string to associate with the physical module. This parameter can be polled by the NMS. Special characters are supported. System Location Specify a description string to associate with the physical location. This parameter can be polled by the NMS. Special characters are supported. Traps Disabled: SNMP traps for system events are not sent from the device. Enabled: SNMP traps for system events are sent to the servers configured in table Trap Servers. Chapter 4: Using the Device Management Interface 176 Attribute Description Trap Community String Configure an SNMP Trap Community String which is processed by the servers configured in Trap Servers. This string is used by the trap server to decide whether or not to process the traps incoming from the device (i.e. for traps to successfully be received by the trap server, the community string must match). System Logging (Syslog) Server 1-4 Specify up to four Syslog servers to which the device sends Syslog messages. Syslog Mask Configure the levels of Syslog messages which the devices send to the servers configured in parameters Server 1-4. Caution Choose only the Syslog levels for the appropriate installation. Excessive logging can cause the device log file to fill and starts overwriting the previous entries. cnMaestro Remote Management When Enabled, the device is managed by cnMaestro - the Cambium Networks Remote Management System, allows all Cambium Networks devices to be managed in the cloud. cnMaestro URL Configure the URL of cnMaestro. The default value is https://cloud.cambiumnetworks.com. Cambium ID Configure the Cambium ID that the device uses for onboarding on to cnMaestro. Onboarding Key Configure the password/key associated with the Cambium-ID that the device uses for onboarding on to cnMaestro. Account Management Administrator Account The Administrator account has full read and write permissions for the device. Disabled: The disabled user is not granted access to the device management interface. The administrator user level cannot be disabled. Enabled: The user is granted access to the device management interface. Username The username associated with the administrator account is used upon device login. Password Configure a custom password to secure the device. Only the Administrator account can override this password. The password character display may be toggled using the visibility icon
. Installer Account The Installer account has permissions to read and write parameters applicable to unit installation and monitoring. Disabled: The disabled user is not granted access to the device management interface. Enabled: The user is granted access to the device management interface. Chapter 4: Using the Device Management Interface 177 Attribute Description Username The username associated with the installer account used upon device login. Password Configure a custom password to secure the device. Only the Administrator account can override this password. The password character display may be toggled using the visibility icon
. Home User Account The Home User account has permission to access pertinent information for support purposes. Disabled: The disabled user is not granted access to the device management interface. Enabled: The user is granted access to the device management interface. Username The username associated with the home user account is used upon device login. Password Configure a custom password to secure the device. Only the Administrator account can override this password. The password character display may be toggled using the visibility icon
. Read-Only Account The Read-Only account has permission to view only the Monitor page. Disabled: The disabled user is not granted access to the device management interface. Enabled: The user is granted access to the device management interface. Username The username associated with the read-only account used upon device login. Password Configure a custom password to secure the device. Only the Administrator account can override this password. The password character display may be toggled using the visibility icon
. Chapter 4: Using the Device Management Interface 178 Configuration > Network page Figure 77: Configuration>Networkpage(APmode) Chapter 4: Using the Device Management Interface 179 Figure 78: Configuration>Networkpage(SMmode,BridgeNetworkmode) Chapter 4: Using the Device Management Interface 180 Figure 79: Configuration>Networkpage(SMmode,NATNetworkmode) Figure 80: Configuration>Networkpage(SMmode,Routermode) Table 137 Configuration > Network page attributes Attribute Description General Network Mode NAT: The SM acts as a router and packets are forwarded or filtered based on their IP header (source or destination). Bridge: The SM acts as a switch and packets are forwarded or filtered based on their MAC destination address. Router: The SM acts as a router and packets are forwarded or filtered based on their IP header (source or destination) using specific static routes and IP aliases configured by the operator. Chapter 4: Using the Device Management Interface 181 Attribute Description IP Assignment Static: Device management IP addressing is configured manually in fields IP Address, Subnet Mask, Gateway, Preferred DNS Server, and Alternate DNS Server. DHCP: Device management IP addressing (IP address, Subnet Mask, Gateway, and DNS Server) is assigned via a network DHCP server, and parameters IP Address, Subnet Mask, Gateway, Preferred DNS Server, and Alternate DNS Server are not configurable. Static: Wireless IP address is configured manually in fields Wireless IP Address, Wireless IP Subnet Mask, Wireless Gateway IP Address, Preferred DNS IP Address, and Alternate DNS IP Address. DHCP: Device management IP addressing (Wireless IP address, Wireless Subnet mask, Wireless Gateway, and DNS server) is assigned via a network DHCP server. Internet protocol (IP) address. This address is used by the family of Internet protocols to uniquely identify this unit on a network. If IP Address Assignment is set to DHCP and the device is unable to retrieve IP address information via DHCP, the device management IP is set to fallback IP 192.168.0.1 (Access Point) or 192.168.0.2 (Subscriber Module). Defines the address range of the connected IP network. For example, if Device IP Address (LAN) is configured to 192.168.2.1 and IP Subnet Mask (LAN) is configured to 255.255.255.0, the device will belong to subnet 192.168.2.X. Configure the IP address of the deviceon the current network that acts as a gateway. A gateway acts as an entrance and exit to packets from and to other networks. Configure the primary IP address of the server used for DNS resolution. Configure the secondary IP address of the server used for DNS resolution. Wireless IP Assignment
(NAT mode, Router mode) IP Address Wireless IP Address (NAT mode, Router mode) Subnet Mask Wireless IP Address (NAT mode, Router mode) Gateway Wireless Gateway
(NAT mode, Router mode) Preferred DNS Server Alternate DNS Server IPv6 Assignment IPv6 Assignment specifies how the IPv6 address is obtained. Static: Device management IP addressing is configured manually in fields IPv6 Address and IPv6 Gateway. DHCPv6: Device management IP addressing (IP address and gateway) is assigned via a network DHCP server, and parameters IPv6 Address and IPv6 Gateway are unused. If the DHCPv6 server is not available previous static IPv6 address will be used as a fallback IPv6 address. If no previous static IPv6 address is available, no IPv6 address will be assigned. DHCPv6 will occur over the wireless interface by default. IPv6 Address Internet protocol version 6 (IPv6) address. This address is used by the family of Internet protocols to uniquely identify this unit on a network. Chapter 4: Using the Device Management Interface 182 Attribute Description IPv6 addresses are represented by eight groups of four hexadecimal digits separated by colons. IPv6 Gateway Configure the IPv6 address of the deviceon the current network that acts as a gateway. A gateway acts as an entrance and exit to packets from and to other networks. Ethernet Port Security
(Subscriber Module Mode) Secure MAC Limit
(SM mode) Disabled: No MAC address limit/gaining timers are imposed for bridging at the SM device Ethernet port. Enabled: By configuring Secure MAC Limit and MAC Aging Time, a limit is imposed on the number and duration of bridged devices connected to the SM Ethernet port. Configure the number of simultaneous secure MAC addresses that is allowed at the Ethernet interface of the SM MAC Aging Time
(SM mode) Configure the time for which the secure MAC addresses should be allowed to age. Once the Aging timer expires for a MAC address, it is removed from the internal table and no longer count as an active MAC. Set the time to 0 to disable aging. Ethernet Interface (Subscriber Module NAT Mode, Router Mode) IP Address
(SM NAT mode, Router mode) Subnet Mask
(SMNAT mode, Router Mode) DHCP Server
(SM NAT mode, Router mode) DHCP Start IP
(SM NAT mode, Router mode) DHCP End IP
(SM NAT mode, Router mode) Ethernet interface Internet protocol (IP) address. This address is used by the family of Internet protocols to uniquely identify this unit on a network. Defines the address range of the connected IP network. For example, if Device IP Address (LAN) is configured to 192.168.2.1 and IP Subnet Mask (LAN) is configured to 255.255.255.0, the device belongs to subnet 192.168.2.X. Disabled: Use this setting when SM is in NAT or Router mode if there is an existing DHCP Server below the SM handing out IP Addresses or if all devices below the SM is configured with static IP Addresses. Enabled: Use this setting when SM is in NAT or Router mode, to use the SMs local/onboard DHCP server to hand out IP addresses to its clients. Configure the first address which is issued to a DHCP client. Upon additional DHCP requests, the DHCP Start IP is incremented until the local DHCP End IP is reached. Configure the highest IP address in the DHCP pool that can be issued to a DHCP client. Preferred DHCP DNS Server Configure the primary DNS Server IP address which is used to configure DHCP clients (if local DHCP Server is set to Enabled).
(SM NAT mode, Router mode) Alternate DHCP DNS Server Configure the secondary DNS Server IP address which is used to configure DHCP clients (if local DHCP Server is set to Enabled). Chapter 4: Using the Device Management Interface 183 Attribute Description
(SM NAT Mode, Router mode) DHCP Lease Time
(SM NAT Mode, Router mode) PPPoE Service Name Configure the time for which a DHCP IP address is leased. When the lease time expires, the DHCP client must renew IP addresses via DHCP request. Point-to-Point Protocol over Ethernet: Used for encapsulating PPP frames inside Ethernet frames. Optional entry to set a specific service name to connect to for the PPPoE session. If this is left blank the SM accepts the first service option that comes back from the Access Concentrator specified below, if any. This is limited to 32 characters. Access Concentrator An optional entry to set a specific Access Concentrator to connect to for the PPPoE session. If this is blank, the SM accepts the first Access Concentrator which matches the service name (if specified). This is limited to 32 characters. Static Routes (Subscriber Module Router Mode) Static Routes
(SM Router mode) When Enabled, it allows the operator to create static routes that will apply to both the Wireless and Ethernet interface of the SM. This allows operators to configure a custom table of explicit paths between networks. Static routing is often used as a method to reduce the overhead of processing dynamic routes through a network when the specific path is known (or, it is simpler to define a specific path). Static routing is also used as a backup when dynamic routing protocols fail to complete a route from one network to another. In router mode, the Static Routes table is referenced by the SM to forward/filter packets to a particular destination configured by the user based on the IP addressing information contained in the table. Since static routes do not change with network changes, it is recommended to only use static routes for simple network paths that are not prone to frequent changes (requiring updates to the routes configured on the ePMP SM). It is important to consider each hop in a static routes path to ensure that the routing equipment has been configured to statically or dynamically route packets to the proper destination. Otherwise, network communication fails. Network Address Translation (NAT) is not performed when the SM is in Router mode. Target Network IP
(SM Router mode) Configure the target subnet/networks IP address to which the SM should route the packets. Subnet Mask Configure the subnet mask for the Target Network IP address.
(SMRouter mode) Gateway
(SM Router mode) Configure the gateway to which packets that match the Target Network IP Address and Subnet Mask are sent. Chapter 4: Using the Device Management Interface 184 Attribute Description Description Provide a description to easily identify the static route and its purpose.
(SM Router mode) IP Aliases (Subscriber Module Router Mode) IP Aliases
(SM Router mode) When Enabled, IP aliases allow the operator to associate more than one IP address to the Ethernet interface of the SM. This configuration of multiple IP addresses for the SMs Ethernet interface allows connections to multiple networks, often used as a mechanism for management access to the device from a convenient networking path. IP Address Configure the IP address for the alias.
(SM Router mode) Subnet Mask Configure the subnet mask for the alias.
(SM Router mode) Description
(SM Router mode) Provide a description to easily identify the IP alias and its purpose/connected network. Separate Wireless Management Interface (SM NAT mode, Router mode) Separate Management IP
(SM NAT mode, Router mode) IP Assignment
(SM NAT mode, Router mode) IP Address
(SMNAT mode, Router mode) Subnet Mask
(SM NAT mode, Router mode) Gateway
(SM NAT mode, Router mode) Disabled: When disabled, the Wireless IP is the management interface for the SM. Enabled: When enabled, the IP Address below is the management interface for the SM. Static: Separate Wireless Management Interface is configured manually in fields IP Address, Subnet Mask and Gateway. DHCP: Management IP addressing (IP Address, Subnet Mask, Gateway, and DNS Server) is assigned via a network DHCP server. Configure the IP address that is used to access the SMs management interface when in NAT mode. The Wireless IP (public IP) does not allow management access. Defines the address range of the connected IP network. For example, if the IP Address is configured to 192.168.2.1 and Subnet Mask is configured to 255.255.255.0, the device wireless interface belongs to the subnet 192.168.2.X. Configure the IP address of a computeron the current network that acts as a gateway. A gateway acts as an entrance and exit to packets from and to other networks. Chapter 4: Using the Device Management Interface 185 Attribute Description Separate Management VLAN
(SM NAT mode, Router mode) Enabled: A VLAN configuration establishes a logical group within the network. Each computer in the VLAN, regardless of initial or eventual physical location, has access to the same data based on the VLAN architecture. For the network operator, this provides flexibility in network segmentation, simpler management, and enhanced security. When the SM is in NAT mode, the Separate Wireless Management VLAN configuration applies to management data. VLAN ID
(SM NAT mode, Router mode) VLAN Priority
(SM NAT mode, Router mode) Disabled: When disabled, the SM does not have a unique management VLAN. Configure this parameter to include the devices management traffic on a separate VLAN network. ePMP radios can prioritize VLAN traffic based on the eight priorities described in the IEEE 802.1p specification. Data VLAN Priority represents the VLAN Priority or Class of Service (CoS). Operators may use this prioritization field to give precedence to the devices management data. This parameter only takes effect if the Separate Wireless Management VLAN parameter is enabled. Configure this parameter to set the value of the Priority code point field in the 802.1q tag for management traffic on the configured VLAN ID originating from the SM. The default value is 0. Virtual Local Area Network (VLAN) Management VLAN
(AP mode) Enabled: The AP management interface can be assigned to a management VLAN to separate management traffic (remote module management via SNMP or HTTP) from user traffic (such as internet browsing, voice, or video. Once the management interface is enabled for a VLAN, an APs management interface can be accessed only by packets tagged with a VLAN ID matching the management VLAN ID. A VLAN configuration establishes a logical group within the network. Each computer in the VLAN, regardless of initial or eventual physical location, has access to the same data based on the VLAN architecture. For the network operator, this provides flexibility in network segmentation, simpler management, and enhanced security. Disabled: When disabled, all IP management traffic is allowed to the device. VLAN
(Management +
Data)
(SM mode) Enabled: The device management interface can be assigned to a Management VLAN to separate management traffic (remote module management via SNMP or HTTP) from user traffic (such as internet browsing, voice, or video. Once the management interface is enabled for a VLAN, the management interface can be accessed only by packets tagged with a VLAN ID matching the management VLAN ID. A VLAN configuration establishes a logical group within the network. Each computer in the VLAN, regardless of initial or eventual physical location, has access to the same data based on the VLAN architecture. For the network operator, this provides flexibility in network segmentation, simpler management, and enhanced security. Disabled: When disabled, all IP management traffic is allowed to the device. Chapter 4: Using the Device Management Interface 186 Attribute Description VLAN ID
(NAT mode, Router mode) VLAN Priority
(NAT mode, Router mode) Management VLAN ID
(APmode)
(SM Bridge mode) Management VLAN Priority
(AP mode)
(SM Bridge mode) Configure this parameter to include the devices management traffic on a separate VLAN network. ePMP radios can prioritize VLAN traffic based on the eight priorities described in the IEEE 802.1p specification. Data VLAN Priority represents the VLAN Priority or Class of Service (CoS). Operators may use this prioritization field to give precedence to the device management data. This parameter only takes effect if the Separate Wireless Management VLAN parameter is enabled. Configure this parameter to set the value of the Priority code point field in the 802.1q tag for management traffic on the configured VLAN ID originating from the SM. The default value is 0. Configure this parameter to include the devices management traffic on a separate VLAN network. For example, if Management VLAN ID is set to 2, UI access is allowed only from frames tagged with VLAN ID 2. This parameter only takes effect if the MGMT VLAN parameter is enabled. ePMP devices can prioritize VLAN traffic based on the eight priorities described in the IEEE 802.1p specification. Management VLAN Priority represents the VLAN Priority or Class of Service (CoS). Operators may use this prioritization field to give precedence to the device management traffic. This parameter only takes effect if the Management VLAN parameter is enabled. Configure this parameter to set the value of the Priority code point field in the 802.1q tag for traffic on the management VLAN originating from the Subscriber Module. The default value is 0. Data VLAN
(SM mode)
(Bridge mode) Enabled: A VLAN tag is added to all untagged traffic entering the Salve device LAN port before sending it to the Access Point and remove tags in the opposite direction from traffic (tagged with Data VLAN ID) entering on the SM device WAN port before sending to the SM device LAN port. Data VLAN ID
(SM mode)
(Bridge mode) Data VLAN Priority
(SM mode)
(Bridge mode) Disabled: When disabled, no changes are made to untagged traffic passing through the SM device. Configure this parameter to include this VLAN tag to all untagged traffic entering on the Subscriber Module device LAN port before sending it to the Access Point device and remove tags in the opposite direction from traffic (tagged with Data VLAN ID) entering on the Subscriber Module device WAN port before sending to the SM device LAN port. ePMP devices can prioritize VLAN traffic based on the eight priorities described in the IEEE 802.1p specification. Data VLAN Priority represents the VLAN Priority or Class of Service (CoS). Operators may use this prioritization field to give precedence to device user data. This parameter only takes effect if the Data VLAN parameter is enabled. Configure this parameter to set the value of the Priority code point field in the 802.1q tag for traffic on the Data VLAN originating from the SMdevice. The default value is 0. Chapter 4: Using the Device Management Interface 187 Attribute Description Membership VLAN
(SM Bridge mode) Configure the Membership VLAN Table to include the SM in one or more VLANs. When the SM receives a packet tagged from either the Ethernet (LAN) or Wireless
(WAN) side with a VLAN ID which is contained in the Membership VLAN Table, the packet is forwarded and sent out to the other interface. When the SM receives a packet tagged with a VLAN ID that is not present in the Membership VLAN Table, the frame is dropped (assuming there is at least one VLAN ID present in the Membership VLAN table or configured as a Data VLAN). VLAN Mapping
(SM Bridge mode) Configure the VLAN Mapping Table to map the C-VLAN of traffic ingressing the Ethernet (LAN) port of the SM to an S-VLAN before being forwarded to the air interface on the UL. In the DL direction, the SM will automatically un-map the S-
VLAN to the C-VLAN before forwarding the tagged packets to the Ethernet (LAN) interface of the SM. C-VLAN
(SM Bridge mode) Configure the C-VLAN ID of the tagged traffic for which the mapping needs to occur. The C-VLAN ID must be entered in the SM VLAN Membership VLAN table. S-VLAN Configure the S-VLAN ID to which the tagged traffic needs to be mapped.
(SM Bridge mode) The S-VLAN ID must be entered in the SM VLAN Membership VLAN table. Ethernet Port Ethernet MTU Ethernet Port
(SM mode) Port Setting Specify the device MTU or Maximum Transmission Unit; the size in bytes of the largest data unit that the device is configured to process. Larger MTU configurations can enable the network to operate with greater efficiency, but in the case of retransmissions due to packet errors, efficiency is reduced since large packets must be resent in the event of an error. Disabled: The primary Ethernet port is disabled (a mechanism for restricting access for non-payment). Enabled: The primary Ethernet port is enabled. Allows the Gigabit Ethernet port duplex settings and port speed to be either manually configured or auto-negotiate with the connected Ethernet device on the other end of the link. Guidelines for using Port Setting:
l l l If auto-negotiation is turned on, this applies to both Port Speed and Port Duplex Mode. If the other end of the Ethernet connection supports auto-negotiation, then select Auto-Negotiate. If the other end of the Ethernet connection does not support auto-
negotiation, then select Manual and both ends of the link should manually set the port speed and port duplex mode. Port Speed With Port Setting configured to Manual, the Gigabit Ethernet port speed can be forced to 1000 Mbps, 100 Mbps, or 10 Mbps. Chapter 4: Using the Device Management Interface 188 Attribute Description Port Duplex mode With Port Setting configured to Manual, the Gigabit Ethernet port duplex mode can be forced to Full or Half. Port Forwarding (Subscriber Module Mode) (NAT Mode) UPnP IGD
(SM mode)
(NAT mode) Universal Plug and Play (UPnP) is a set of networking protocols that permits networked devices, such as personal computers, printers, Internet gateways, Wi-Fi APs, and mobile devices to seamlessly discover each other's presence on the network and establish functional network services for data sharing, communications, and entertainment. UPnP is intended primarily for residential networks without enterprise-class devices. With UPnP IGD and PCP protocols, ePMP will support explicit dynamic port mappings. Enable UPnP IGD (Internet Gateway Device) to allow the ePMP device to use the IGD profile for UPnP support. NAT PMP (PCP)
(SM mode)
(NAT mode) The PCP (Port Control Protocol) allows an IPv6 or IPv4 host to control how incoming IPv6 or IPv4 packets are translated and forwarded by a Network Address Translator (NAT) or simple firewall, and also allows a host to optimize its outgoing NAT keepalive messages. PCP was standardized as a successor to the NAT Port Mapping Protocol (NAT-PMP), with which it shares similar protocol concepts and packet formats. Enable this parameter to allow the ePMP device to use the PCP protocol for UPnP support. The Data Port Forwarding Table is used to define which range of wireless ports are forwarded to a LAN (SM local network) IP address below the SM. Data Port Forwarding
(SM mode)
(NAT mode) Protocol UDP: Packet forwarding decisions are based on UDP packets.
(SM mode) TCP: Packet forwarding decisions are based on TCP packets.
(NAT mode) Port Begin
(SM mode)
(NAT mode) Configure the beginning of the range of wireless ports to match for forwarding to LAN IP. Port End Configure the end of the range of wireless ports to match for forwarding to LAN IP.
(SM mode)
(NAT mode) Forwarding IP
(SM mode)
(NAT mode) Configure the LAN IP of the device situated below the SM which receives the packets forwarded based on the separate management IP port forwarding table configuration. Chapter 4: Using the Device Management Interface 189 Attribute Description Mapped Port
(SM mode)
(NAT mode) Configure the port of the device situated below the SM which receives the packets forwarded based on the Data Port Forwarding Table configuration. Point-to-Point Protocol over Ethernet (PPPoE) (SM mode) (NAT mode, Router mode) PPPoE
(SM mode)
(NAT mode, Router mode) Service Name
(SM mode)
(NAT mode, Router mode) Access Concentrator
(SM mode)
(NAT mode, Router mode) Authentication
(SM mode)
(NAT mode, Router mode) Point-to-Point Protocol over Ethernet: Used for encapsulating PPP frames inside Ethernet frames. Optional entry to set a specific service name to connect to for the PPPoE session. If this is left blank the SM accepts the first service option that comes back from the Access Concentrator specified below, if any. This is limited to 32 characters. Optional entry to set a specific Access Concentrator to connect to for the PPPoE session. If this is blank, the SM accepts the first Access Concentrator which matches the service name (if specified). This is limited to 32 characters. ALL: This means that CHAP authentication is attempted first, then PAP authentication. The same password is used for both types. CHAP: This means that CHAP authentication is attempted. PAP: This means that PAP authentication is attempted. Username This is the CHAP/PAP username that is used. This is limited to 32 characters.
(SM mode)
(NAT mode, Router mode) Password This is the CHAP/PAP password that is used. This is limited to 32 characters.
(SM mode)
(NAT mode, Router mode) MTU Size
(SM mode)
(NAT mode, Router mode) Maximum Transmission Unit; the size in bytes of the largest data unit that the device is configured to process inside the PPPoE tunnel. This field allows the operator to specify the largest MTU value to use in the PPPoE session if PPPoE MSS Clamping is Enabled. The user is able to enter an MTU value up to 1492. However, if the MTU determined in LCP negotiations is less than this user-specified value, the SM uses the smaller value as its MTU for the PPPoE link. Chapter 4: Using the Device Management Interface 190 Attribute Description Keep Alive Time
(SM mode)
(NAT Mode, Router Mode) MSS Clamping
(SM mode)
(NAT mode, Router mode) Configure the Keep Alive Time to allow the radio to keep the PPPoE session up after establishment. As an example, if this field is set to 5, the PPPoE client sends a keep-alive message to the PPPoE server every 5 seconds. If there is no acknowledgment, it sends the Keep alive message to the server 4 more times (for a total of 5 times) before tearing down the PPPoE session. Setting this to 12 will mean the keep-alive message is sent every 12 seconds and when there is no acknowledgment, the client will try for a total of 12 times every 12 seconds before tearing down the PPPoE session. Disabled: The SM PPPoE session allows any MTU size determined by other devices in the PPPoE session during the LCP negotiations. Enabled: The SM PPPoE session enforces a max MTU size determined by the PPPoE MTU Size setting for all devices in the PPPoE session during the LCP negotiations unless one of the devices enforces an MTU setting that is smaller in value. SFP Port (Access Point Mode) SFP Port Disabled: The SFP port is inactive.
(AP mode) Enabled: The SFP port is active. Advanced IPv6 Support System-wide IPv6 Protocol Support. When enabled, appropriate IPv6 modules and services are loaded. Spanning Tree Protocol Disabled: When disabled, Spanning Tree Protocol (802.1d) functionality is disabled at the Access Point. Enabled: When enabled, Spanning Tree Protocol (802.1d) functionality is enabled at the Access Point, allowing for the prevention of Ethernet bridge loops. DHCP Server Below Subscriber Module
(SM mode) Disabled: This blocks DHCP servers connected to the SM device LAN side from handing out IP addresses to DHCP clients above the SM device (wireless side). Enabled: This allows DHCP servers connected to the SM device LAN side to assign IP addresses to DHCP clients above the SM device (wireless side). This configuration is typical in PTP links. Management Access (AP mode) Ethernet: Only allow access to the APs web management interface via a local Ethernet (LAN) connection. In this configuration, the APs web management interface may not be accessed from over the air (from a device situated below the SM). Ethernet and Wireless: Allow access to the APs web management interface via a local Ethernet (LAN) connection and from over the air (from a device situated below the SM). APs configured with Management Access Interface set to Ethernet and Ethernet and Wireless are susceptible to unauthorized access. SM Traffic Isolation Disabled: This is the default mode. When SM isolation is disabled, an SM can communicate with another SM, when both the SMs are associated with the same Access Point (AP). Chapter 4: Using the Device Management Interface 191 Attribute Description
(AP mode) Enabled: When the SM Isolation feature is Enabled, an SM is unable to communicate with another SM (peer-to-peer traffic) when both the SMs are associated with the same AP. This feature essentially enables the AP to drop the packets to avoid peer-to-peer traffic scenarios. DHCP Option 82
(AP mode) Disabled: The device does not insert the remote-id (option ID 0x2) and the circuit-
id (ID 0x01). DHCP Option 82 is Disabled by default. Enabled: The device inserts remote-id (option ID 02) to be the SM MAC address and the circuit-id (ID 001) to be the APs MAC address. Those two fields are used to identify the remote device and connection from which the DHCP request was received. LLDP The Link Layer Discovery Protocol (LLDP) is a vendor-neutral link layer protocol
(as specified in IEEE 802.1AB) used by ePMP for advertising its identity, capabilities, and neighbors on the Ethernet/wired interface. Disabled: ePMP does not receive or transmit LLDP packets from/to its neighbors. Enabled: ePMP can receive LLDP packets from its neighbors and send LLDP packets to its neighbors, depending on the LLDP Mode configuration below. LLDP Mode Receive and Transmit: ePMP sends and receives LLDP packets to/from its neighbors on the Ethernet/LAN interface. Receive Only: ePMP receives LLDP packets from its neighbors on the Ethernet/LAN interface and discovers them. PPPoE Intermediate Agent When enabled, during the PPPoE Discovery phase the AP inserts access loop identification into the PPPoE PADR packets. This mechanism helps the service provider to distinguish between end hosts connected via Ethernet as an access device (typically, home routers situated below an ePMP subscriber device). On the AP, PPPoE Intermediate Agent enables subscriber line identification by tagging Ethernet frames of corresponding users with Vendor-Specific PPPoE Tags Circuit ID (defining AP name, frame, slot, port, and VLAN ID information) and Remote ID (defining user phone number). Broadcast / Multicast Traffic Shaping (SM mode) (Bridge mode) Broadcast Packet Limit
(SM mode)
(Bridge mode) Broadcast Packet Rate
(SM mode)
(Bridge mode) Enabled: This allows the user to set the Broadcast Packet Rate below. Configure this parameter to limit the number of broadcast packets that will be allowed on the ingress of the radios Ethernet port. Set the packets per second value to limit the impact of events such as broadcast storms. Disabled: There is no limit on the amount of broadcast traffic allowed into the ingress of the radios Ethernet port. Set the packets per second value to limit the amount of broadcast traffic allowed on the ingress on the radios Ethernet port. The packets per second limit can be set individually on each ePMP radio. The range is 100 to 16000 packets per second. The default is 1000. Chapter 4: Using the Device Management Interface 192 Attribute Description Reliable Multicast Enabled: This feature allows ePMP to support IGMP capable devices. Once a multicast group is identified, the AP allows multicast traffic to be sent only to the SMs within the multicast group. The SMs support up to 5 unique multicast groups. Also, when this option is enabled, the multicast traffic is sent to the SMs using the current Downlink MCS rate. Disabled: ePMP still supports IGMP capable devices but the multicast traffic is sent using MCS 1 on the downlink to all SMs, regardless of the multicast group. Multicast Group Limit Configure the maximum number of simultaneous multicast groups that the SM will allow from devices below it. The default is 3.
(SM mode)
(Bridge mode) Multicast VLAN
(SM mode)
(Bridge mode) Multicast VLAN ID
(SM mode)
(Bridge mode) Multicast VLAN Priority
(SM mode)
(Bridge mode) Enabled: A VLAN tag is added to all untagged multicast traffic entering the SMs LAN port before sending it to the AP and remove tags in the opposite direction from traffic (tagged with Multicast VLAN ID) entering on the SMs WAN port before sending to the SMs LAN port. Disabled: When disabled, no changes are made to untagged multicast traffic passing through the SM. Configure this parameter to include this VLAN tag to all untagged multicast traffic entering on the SMs LAN port before sending it to the AP and remove tags in the opposite direction from multicast traffic (tagged with Multicast VLAN ID) entering on the SMs WAN port before sending to the SMs LAN port. ePMP radios can prioritize VLAN traffic based on the eight priorities described in the IEEE 802.1p specification. Multicast VLAN Priority represents the VLAN Priority or Class of Service (CoS). Operators may use this prioritization field to give precedence to the device's multicast data. This parameter only takes effect if the Multicast VLAN parameter is enabled. Configure this parameter to set the value of the Priority code point field in the 802.1q tag for traffic on the Multicast VLAN originating from the SM. The default value is 0. De-Militarized Zone (Subscriber Module NAT Mode) DMZ
(SM NAT mode) Disabled: Packets arriving on the wireless interface destined for the Ethernet side of the network are dropped if a session does not exist between the Source IP
(Wireless) and Destination IP (Ethernet). By default, NAT requires the sessions to be initiated from the Ethernet side before a packet is accepted from the Wireless to the Wired side. Enabled: Any packets with an unknown destination port (not associated with an existing session or not defined in the port forwarding rules) are automatically sent to the device configured with DMZ IP Address. IP Address
(SM NAT mode) Configure the IP address of an SM-connected device that is allowed to provide network services to the wide-area network. Chapter 4: Using the Device Management Interface 193 Attribute Description Allow ICMP to DMZ
(SM NAT mode) Enabled: ICMP packets are forwarded to the DMZ IP Disabled: SM answers ICMP requests, and SM Wireless IP Address becomes reachable by ping when DMZ enabled Configuration > Security page The Security page is used to configure system security features including authentication and Layer2/Layer3 Firewall rules. Attention If a device firewall rule is added with Action set to Deny and Interface set to LAN or WAN and no other rule attribute is configured, the device drops all Ethernet or wireless traffic, respectively. Ensure that all firewall rules are specific to the type of traffic which must be denied and that no rules exist in the devices with the only Action set to Deny and Interface set to LAN or WAN. To regain access to the device, perform a factory default. Chapter 4: Using the Device Management Interface 194 Figure 81: Configuration>Securitypage(APmode) Figure 82: Configuration>Securitypage(SMmode) Table 138 Configuration > Security page attributes Attribute Description Security Options Wireless Security
(AP mode) WPA2 For AP mode devices, select the security mode enforced upon network entry. For SM mode devices, select the security mode utilized upon network entry attempts. Open: All SM devices requesting network entry are allowed registration. WPA2: The WPA2 mechanism provides AES radio link encryption and SM network entry authentication. When enabled, the SM must register using the authentication pre-shared key configured on the AP and SM. RADIUS: Enables SM authentication via a pre-configured Radius server. WPA2 Pre-
shared Key Configure this key on the AP, then configure the SM with this key to complete the authentication configuration. This key must be between 8 to 128 symbols. RADIUS (AP mode) Servers
(AP mode) For more Radio servers, click Add. Up to 3 Radius servers can be configured on the device with the following attributes:
l IP Address: IP Address of the Radius server on the network. l Port: The Radius server port. The default is 1812. l Secret: Secret key that is used to communicate with the RADIUS server. Server Retries The number of times the radio retries authentication with the configured Radius server before it fails authentication of the SM. Chapter 4: Using the Device Management Interface 195 Attribute Description
(AP mode) Server Timeout
(AP mode) GUI User Authentication
(AP mode) EAP-TTLS Username
(SM mode) Use Ethernet MAC Address at EAP-TTLS Username
(SM mode) EAP-TTLS Password
(SM mode) Timeout between each retry with the configured RADIUS server before it fails authentication of the SM. This applies to both the AP and its registered SMs. Device Local Only: The devices GUI authentication is local to the device using one of the accounts configured under Configuration > System > Account Management. Remote RADIUS Server Only: The UI authentication of the device is performed using a RADIUS server. Remote RADIUS Server and Fallback to Local: The UI authentication of the device is performed using a RADIUS server. Upon failure of authentication through a RADIUS server, the authentication falls back to one of the local accounts configured under Configuration > System > Account Management. Configure the EAP-TTLS Username to match the credentials on the RADIUS server being used for the network. The device MAC Address can be used as the EAP-TTLS Username in either : or -
delimited format. Configure the EAP-TTLS Password to match the credentials on the RADIUS server being used for the network. Authentication Identity String Configure this Identity string to match the credentials on the RADIUS server being used for the network. The default value for this parameter is anonymous.
(SM mode) Authentication Identity Realm Configure this Identity string to match the credentials on the RADIUS server being used for the network. The default value for this parameter is cambiumnetworks.com.
(SM mode) Default Root Certificate Default EAP-TTLS root certificate that must match the certificate on the RADIUS server.
(SM mode) Canopy Root Certificate PMP 450 default EAP-TTLS root certificate to match the certificate on the RADIUS server used with current PMP 450 installations.
(SM mode) Chapter 4: Using the Device Management Interface 196 Attribute Description Import a user certificate if a certificate different from the default certificates is needed. Import a second user certificate if a certificate different from the default or 1st user provisioned certificate is needed. User Provisioned Root Cert 1
(SM mode) User Provisioned Root Cert 2
(SM mode) Firewalls Layer 2 Firewall Enabled: Modifications to the Layer 2 Firewall Table are allowed and rules are enforced. Disabled: Modifications to the Layer 2 Firewall Table are not allowed and rules are not enforced. Layer 2 Firewall Rules The Layer 2 firewall table may be used to configure rules matching layer 2 (MAC layer) traffic which results in forwarding or dropping the traffic over the radio link or Ethernet interface. Layer 3 Firewall Disabled: Modifications to the Layer 3 Firewall Table are not allowed and rules are not enforced. Enabled: Modifications to the Layer 3 Firewall Table are allowed and rules are enforced. Layer 3 Firewall Rules The Layer 3 firewall table may be used to configure rules matching layer 3 (IP layer) traffic which results in forwarding or dropping the traffic over the radio link or Ethernet interface. Wireless MAC Address Filtering (Access Point Mode) Wireless MAC Filter
(AP mode) Disabled: SMs with any MAC Address are allowed to register to the AP. Enabled: SMs with specific MAC addresses can be allowed (permit) or denied
(prevent) registration with the AP as configured under the MAC Filter List. Wireless MAC Filter Policy Prevent: All MAC Addresses configured under the MAC Filter List are denied registration to the AP.
(AP mode) Permit: Only the MAC Addresses configured under the MAC Filter List are allowed to register to the AP. Wireless MAC Filter List Configure the SMs MAC addresses that are permitted or prevented from registering to the AP.
(AP mode) MAC Address MAC Address of the SM.
(AP mode) Description Friendly description to identify the SM.
(AP mode) Chapter 4: Using the Device Management Interface 197 Monitor menu This section is used to analyze and troubleshoot network performance and operation. Use the Monitor menu to access device and network statistics and status information. Chapter 4: Using the Device Management Interface 198 Monitor > Performance page Chapter 4: Using the Device Management Interface 199 Figure 83: Monitor>Performancepage Table 139 Monitor > Performance page attributes Attribute Description Reset Statistics Time Since Last Reset Time since the stats were last reset. Ethernet Statistics Transmitted Total Traffic The total amount of traffic in KB transferred from the device Ethernet interface. Total Packets The total number of packets transferred from the device Ethernet interface. Packet Errors The total number of packets transmitted out of the device Ethernet interface with errors due to collisions, CRC errors, or irregular packet size. Packet Drops The total number of packets dropped before sending out from the devices Ethernet interface due to Ethernet setup or filtering issues. Broadcast Packets Multicast Packets The total number of broadcast packets sent via the device Ethernet interface. The total number of multicast packets sent via the device Ethernet interface. Ethernet Statistics Received Total Traffic The total amount of traffic in KB received by the device Ethernet interface. Total Packets The total number of packets received by the device Ethernet interface. Packet Errors The total number of packets received by the device Ethernet interface with errors due to collisions, CRC errors, or irregular packet size. Packet Drops The total number of packets dropped before sending out from the devices wireless interface due to Ethernet setup or filtering issues. Broadcast Packets Multicast Packets The total number of broadcast packets received via the device Ethernet interface. The total number of multicast packets received via the device Ethernet interface. SFP Statistics Transmitted Total Traffic The total amount of traffic in KB transferred from the device SFP interface. Total Packets The total number of packets transferred from the device SFP interface. Packet Errors The total number of packets transmitted out of the device SFP interface with errors due to collisions, CRC errors, or irregular packet size. Packet Drops The total number of packets dropped before sending out from the devices SFP interface due to setup or filtering issues. Broadcast Packets The total number of broadcast packets sent via the device SFP interface. Chapter 4: Using the Device Management Interface 200 Attribute Description Multicast Packets The total number of multicast packets sent via the device SFP interface. SFP Statistics - Received Total Traffic The total amount of traffic in KB received by the device SFP interface. Total Packets The total number of packets received by the device SFP interface. Packet Errors The total number of packets received by the device SFP interface with errors due to collisions, CRC errors, or irregular packet size. Packet Drops The total number of packets dropped before sending out of the device wireless interface due to SFP setup or filtering issues. Broadcast Packets Multicast Packets The total number of broadcast packets received via the device SFP interface. The total number of multicast packets received via the device SFP interface. Wireless Statistics Downlink Total Traffic The total amount of traffic transmitted out of the device wireless interface in Kbits. Total Packets The total number of packets transmitted out of the device wireless interface. Error Drop Packets The total number of packets dropped after transmitting out of the device Wireless interface due to RF errors (No acknowledgment and other RF related packet error). Capacity Drop Packets (AP mode) The total number of packets dropped after transmitting out of the device wireless interface due to capacity issues (data buffer/queue overflow or other performance or internal packet errors). Retransmission Packets (AP mode) Multicast /
Broadcast Traffic Broadcast Packets Multicast Packets The total number of packets re-transmitted after transmitting out of the device's wireless interface due to the packets not being received by the receiving device. The total amount of multicast and broadcast traffic transmitted out of the device wireless interface in KB. The total number of broadcast packets transmitted out of the device wireless interface. The total number of multicast packets transmitted out of the device wireless interface. Wireless Statistics Uplink Total Traffic The total amount of traffic received via the device wireless interface in KB. Total Packets The total number of packets received via the device wireless interface. Error Drop Packets The total number of packets dropped before sending out of the device Ethernet interface due to RF errors (packet integrity error and other RF-related packet error). Chapter 4: Using the Device Management Interface 201 Attribute Description Capacity Drop Packets (SM mode) The total number of packets dropped after transmitting out of the device wireless interface due to capacity issues (data buffer/queue overflow or other performance or internal packet errors). Multicast /
Broadcast Traffic Broadcast Packets Multicast Packets Link Quality
(Uplink)
(SM mode) The total amount of multicast and broadcast traffic received on the device wireless interface in KB. The total number of broadcast packets received on the device wireless interface. The total number of multicast packets received on the device wireless interface. Defines the Packet Error Rate (PER) in the uplink direction by percentage. A background color corresponds to a percentage range. l Blue is between 80 and 100%. l Green is between 50 and 80%. l Yellow is between 30 and 50%. l Red is between 0 and 30%. Link Capacity
(Uplink)
(SM mode) Defines the capacity of the uplink as defined byMCS.DS MCS9 provides the greatest capacity.SS MCS1 provides the least. The capacity of the link is defined as the percentage throughput of the actual link as compared to a link that was always running atDS MCS 9. A background color corresponds to a percentage range. l Blue is between 80 and 100%. l Green is between 50 and 80%. l Yellow is between 30 and 50%. l Red is between 0 and 30%. System Statistics Session Drops Indicates the total number of Subscriber Module sessions dropped on the AP. Link Drop Counter Indicates the total number of times the wireless link was lost. Total Device Reboots Indicates the total number of times the device has been rebooted since the statistics were last reset from theGUI,CLI, orSNMP. Soft Device Reboots Indicates the number of times the device has been rebooted by the user throughGUI,CLI, orSNMP since the statistics were last reset from theGUI,CLI, orSNMP. Hard Device Reboots Indicates the number of times the device has been rebooted via power feeding and due to power outage since the statistics were last reset from theGUI,CLI, orSNMP. Chapter 4: Using the Device Management Interface 202 Attribute Description The total number of Network Entry Attempts by Subscriber Module devices. The total number of successful network entry attempts. The total number of failed Network Entry Attempts by SM devices. Network Entry Attempts (AP mode) Successful Network Entries
(AP mode) Network Entry Authentication Failures (AP mode) Radar (DFS) Detections Subscriber Module Statistics (AP mode) MAC Address MAC Address of the Subscriber Module connected to the AP. Total Uplink
(KB) Total Uplink Packets Uplink Packet Drops Total Downlink
(KB) Total Downlink Packets Downlink Packet Drops The total amount of traffic received via the AP wireless interface from the Subscriber Module in KB. The total number of packets received via the AP wireless interface from this SM. The total number of packets dropped before sending out of the AP Ethernet interface due to RF errors (packet integrity error and other RF-related packet error) from the SM. The total amount of traffic transmitted out of the AP wireless interface in KB. The total number of packets transmitted out of the AP wireless interface. The total number of packets dropped after transmitting out of the AP wireless interface due to RF errors (No acknowledgment and other RF-related packet errors). Downlink Capacity Packet Drops The total number of packets dropped after transmitting out of the AP Wireless interface due to capacity issues (data buffer/queue overflow or other performance or internal packet errors). Downlink Retransmitted Packets Downlink Power
(dBm) The total number of packets re-transmitted after transmitting out of the AP Wireless interface due to the packets not being received by the SM. The transmit power of the AP for the downlink packets to the SM. Downlink Packets per MCS MCS 1 MCS 9 DS / SS The number of packets (and percentage of total packets) transmitted out of the device wireless interface for every modulation mode used by the device transmitter, based on radio conditions. Chapter 4: Using the Device Management Interface 203 Attribute Description DS represents dual-stream transmissions and SS represents single-stream transmissions. Uplink Packets per MCS MCS 1 MCS 9 DS / SS The number of packets (and percentage of total packets) received on the device wireless interface for every modulation mode, based on radio conditions. DS represents dual-stream transmissions and SS represents single-stream transmissions. Downlink Frame Time Percentage of frame time used in the uplink. Total Frame Time Used
(AP mode) Monitor > System page Figure 84: Monitor>Systempage Table 140 Monitor > System page attributes Attribute Description Hardware Version Serial Number
(MSN) Firmware Version Board hardware version information. Serial Number information. U-Boot version information. Chapter 4: Using the Device Management Interface 204 Attribute Description Software Version Software Version (Active Bank) The currently operating version of software on the device. The currently operating version of software on the device. Software Version
(Inactive Bank) The backup software version on the device is used upon failure of the active bank. Two software upgrades in sequence updates both the Active Software Bank Version and the Inactive Software Bank Version. Device-Agent Version The operating version of the device agent, which is used for communication with cnMaestro. NTP Status Indicates whether time and date have been obtained from the NTP server. Date and Time Current date and time, subject to time zone offset introduced by the configuration of the device Time Zone parameter. Until a valid NTP server is configured, this field displays the time configured from the factory. System Uptime The total system uptime since the last device reset. Wireless MAC Address Ethernet MAC Address SFP Port MAC Address Sync Source Status Read-Only Users Read-Write Users The hardware address of the device's wireless interface. The hardware address of the device LAN (Ethernet) interface. The hardware address of the device SFP interface. The status of the configured GPS synchronization source. Displays the number of active Read-Only users logged into the radio. Displays the number of active Read-Write users logged into the radio. GUI User Authentication The method by which users are authenticated when logging into the device management interface. Factory Reset Via Power Sequence Enabled: When Enabled under Tools > Backup/Restore > Reset Via Power Sequence, it is possible to reset the radios configuration to factory defaults using the power cycle sequence explained under Resetting ePMP to factory defaults by power cycling. Disabled: When disabled, it is not possible to factory default the radios configuration using the power cycle sequence. cnMaestro Connection Status The current management status of the device for the Cambium Cloud Server. When Enabled under Configuration> System, the device will be managed by the Cambium Networks Remote Management System, which allows all Cambium devices to be managed from the Cambium Networks Cloud Server. Chapter 4: Using the Device Management Interface 205 Attribute Description cnMaestro Account ID The ID that the device is currently using to be managed by the Cambium Networks Cloud Server. Monitor > Wireless page Figure 85: Monitor>Wirelesspage(AccessPointMode) Chapter 4: Using the Device Management Interface 206 Figure 86: Monitor>Wirelesspage(SubscriberModuleMode) Table 141 Monitor > Wireless page attributes Attribute Description Registered Access Point SSID
(SM mode only Wireless Status
(AP mode) SSID of the AP to which the SM is registered. Up: The device's wireless interface is functioning and sending beacons. Down: The device's wireless interface has encountered an error disallowing full operation. Reset the device to re-initiate the wireless interface. Wireless Status
(SM mode) Up: The device wireless interface is functioning and the device has completed network entry. Registered AP MAC Address
(SM mode) Range
(SM mode) Operating Frequency Operating Channel Bandwidth DFS Status Down: The device's wireless interface has encountered an error disallowing full operation. Evaluate radio and security configuration on the AP and SM device to determine the network entry failure. Wireless MAC address of the AP to which the SM is registered. The calculated distance from the AP, determined by radio signal propagation delay. The current frequency at which the device is operating. The current channel size at which the device is transmitting and receiving. N/A: DFS operation is not required for the region configured in parameter Country Code. Channel Availability Check: Before transmitting, the device must check the configured Frequency Carrier for radar pulses for 60 seconds). If no radar pulses are detected, the device transitions to state In-Service Monitoring. In-Service Monitoring: Radio is transmitting and receiving normally while monitoring for radar pulses that require a channel move. Radar Signal Detected: The receiver has detected a valid radar pulse and is carrying out detect-and-avoid mechanisms (moving to an alternate channel). In-Service Monitoring at Alternative Channel: The radio has detected a radar pulse and has moved the operation to a frequency configured in DFS Alternative Frequency Carrier 1 or DFS Alternative Frequency Carrier 2. System Not In Service due to DFS: The radio has detected a radar pulse and has failed channel availability checks on all alternative frequencies. The non-
occupancy time for the radio frequencies in which radar was detected is 30 minutes. Chapter 4: Using the Device Management Interface 207 Attribute Description Downlink SNR The Signal-to-Noise Ratio of the signal being received from the AP.
(SM mode) Transmitter Power The current power level at which the device is transmitting. Uplink MCS Specifies the current MCS utilized for uplink transmission.
(AP mode) Registered Subscriber Modules
(AP mode) The count of registered AP. Ethernet Status The speed and duplex at which the configured LAN port is operating. Country Registered Subscriber Modules
(AP mode) Defines the country code being used by the device. The country code of the Subscriber Module follows the country code of the associated Access Point unless it is an FCC SKU in which case the country code is the United States or Canada. Country code defines the regulatory rules in use for the device. Use the Registered Subscriber Modules table to monitor the registered Subscriber Module device, their key RF status, and statistics information. The Subscriber management interface may also be accessed by clicking the hyperlinks in the IPv4
/ IPv6 Addresses and Device Name columns. Click Deregister to disassociate the SM device from the AP. MAC Address The MAC address of the SM wireless interface.
(AP Mode) IPv4 / IPv6 Addresses (AP mode) Device Name (AP mode) SM Distance
(miles) Session Time
(hh:mm:ss)
(AP mode) The IP address of the SM wireless interface. The configured device name of the SM wireless interface. Indicates the calculated distance of the SM from the AP. The time duration for which the SM has been registered and in session with the AP. RSSI (dBm) Downlink / Uplink Indicates the estimated RSSI of the AP at the SM (first value) and the RSSI of the SM measured at the AP (second value). SNR (dB) Downlink / Uplink Indicates the estimated SNR of the AP at the SM (first value) and the SRN of the SM measured at the AP (second value). Chapter 4: Using the Device Management Interface 208 Attribute Description MCS Downlink /
Uplink Current MCS at which the downlink (first value) and uplink (second value) are operating.
(AP mode) Downlink Quality
(AP mode) Downlink Capacity
(AP mode) The downlink quality is based on the current MCS and PER (Packet Error Rate) for this SM. The downlink capacity is based on the current DL MCS for the highest supported MCS (MCS15). The downlink capacity is based on the current DL MCS for the highest supported MCS (MCS15). MU-MIMO Gain Indicates if MU-MIMO is supported by the subscriber and the MU-MIMO gain achieved by MU-MIMO capable subscribers. Model Name Model of SM. Add As Preferred
(SM mode) Click Add to add the APto the Preferred Access Points List under Configuration >
Radio. SSID The SSID of the visible AP.
(SM mode) MAC Address The MAC address of the visible AP.
(SMmode) Frequency Carrier
(MHz)
(SM mode) Channel Bandwidth (MHz)
(SMmode) The current operating frequency of the visible AP. The current operating channel bandwidth of the visible AP. RSSI (dBm) The current measured Received Signal Strength Indicator at the AP.
(SMmode) SNR (dB) The current measured Signal-to-Noise Ratio (SNR) of the SM to AP link.
(SM mode) Registration State
(SMmode) The indication of the result of the Subscriber Module device network entry attempt:
l Successful: The SM registration is successful. l Failed - Out of Range: The SM is out of the Access Points configured maximum range (Max Range parameter). l Failed- Capacity limit reached at Access Point: The AP is no longer allowing SM network entry due to capacity reached. Chapter 4: Using the Device Management Interface 209 Attribute Description l Failed- No Allocation on Access Point: The SM to APhandshaking failed due to a misconfigured pre-shared key between the SM and AP. l Failed- SW Version Incompatibility: The version of software resident on the AP is older than the software version on the SM. l Failed- PTP Mode: ACL Policy: The AP is configured with PTP Access set to MAC Limited and the SMs MAC address is not configured in the APs PTP MAC Address field. l Failed - Other: The AP does not have the required available memory to allow network entry. This timer indicates the time elapsed since the SMregistered to the AP. Session Time
(hh:mm:ss)
(SM Mode) Wireless Security This field indicates the security state of the AP to SMlink.
(SMmode) Meets Reg Criteria
(SMMode) Yes: The scanned AP meets the Network Entry criteria defined by the internal Network Algorithm. No: The scanned AP does not meet the Network Entry criteria defined by the internal Network Algorithm. Monitor > Throughput Chart page Use the Throughput Chart page to reference a line chart visual representation of system throughput over time. The blue line indicates downlink throughput and the orange line indicates uplink throughput. The X-axis may be configured to display data over seconds, minutes, or hours, and the Y-axis is adjusted automatically based on average throughput. Hover over data points to display details. Chapter 4: Using the Device Management Interface 210 Figure 87: Monitor>ThroughputChartpage Table 142 Monitor > Throughput Chart page attributes Attribute Description Throughput Measurement Period Adjust the X-axis to display throughput intervals in seconds, minutes, or hours. Monitor > GPS page (AP mode) Use the GPS Status page to reference key information about the device's GPS readings, tracked satellites, and firmware version. Figure 88: Monitor>GPSpageattributes(APmode) Table 143 Monitor > GPS page attributes (AP mode) Attribute Description On-board GPS Latitude
(AP mode) On-board GPS Longitude
(AP mode) On-board GPS Height
(AP mode) On a GPS Synchronized ePMP radio, the field is automatically populated with the Device Latitude information from the on-board GPS chip. On a GPS Synchronized ePMP radio, the field is automatically populated with the Device Longitude information from the on-board GPS chip. On a GPS Synchronized ePMP radio, the field is automatically populated with the Device height above sea level from the onboard GPS chip. GPS Time (Greenwich Mean Time) On a GPS Synchronized ePMP radio, the field is automatically populated with the time from the onboard GPS chip.
(AP mode) Chapter 4: Using the Device Management Interface 211 Attribute Description GPS Firmware version
(AP mode) Satellites Tracked
(AP mode) Satellites Visible
(AP mode) Satellites
(AP mode) ID
(AP mode) On a GPS Synchronized ePMP radio, the field indicates the current firmware version of the onboard GPS chip. On a GPS Synchronized ePMP radio, the field indicates the number of satellites currently tracked by the onboard GPS chip. On a GPS Synchronized ePMP radio, the field indicates the number of satellites visible to the onboard GPS chip. The Satellites table provides information about each satellite that is visible or tracked along with the Satellite ID and Signal to Noise Ratio (SNR) of the satellite. Represents the Satellite ID. Signal-to-Noise Ratio This is an expression of the carrier signal quality concerning signal noise.
(AP mode) Status
(AP mode) Status of each Satellite available. Monitor > Network page Use the Network Status page to reference key information about the device network status. Chapter 4: Using the Device Management Interface 212 Figure 89: Monitor>Networkpage Table 144 Monitor > Network page attributes Attribute Description Ethernet Interface IP Assignment Static: Device management IP addressing is configured manually in fields IP Address, Subnet Mask, Gateway, Preferred DNS Server, and Alternate DNS Server. DHCP: Device management IP addressing (IP Address, Subnet Mask, Gateway, and DNS Server) is assigned via a network DHCP server, and parameters IP Address, Subnet Mask, Gateway, Preferred DNS Server, and Alternate DNS Server are not configurable. IP Address Internet protocol (IP) address. This address is used by the family of Internet protocols to uniquely identify this unit on a network. If IP Address Assignment is set to DHCP and the device is unable to retrieve IP address information via DHCP, the device management IP is set to fallback IP 192.168.0.1
(Access Point) or 192.168.0.2 (Subscriber Module). Chapter 4: Using the Device Management Interface 213 Attribute Description Subnet Mask Defines the address range of the connected IP network. For example, if Device IP Address (LAN) is configured to 192.168.2.1 and IP Subnet Mask (LAN) is configured to 255.255.255.0, the device will belong to subnet 192.168.2.X. Default Gateway MTU Size Configure the IP address of the deviceon the current network that acts as a gateway. A gateway acts as an entrance and exit to packets from and to other networks. The currently configured Maximum Transmission Unit for the device Ethernet (LAN) interface. Larger MTU configurations can enable the network to operate with greater efficiency, but in the case of retransmissions due to packet errors, efficiency is reduced since large packets must be resent in the event of an error. Main PSU Port The speed and duplex at which the configured LAN port is operating. Port Speed The speed at which the configured LAN port is operating. The duplex at which the configured LAN port is operating. Port Duplex Mode Network Status DNS Server IP The configured IP address(es) of the network DNS servers. DHCP Option 82 Status of DHCP Option 82 operation in the network. NTP Status Represents the status of NTP retrieval in the network. ARP Table MAC Address MAC Address of the devices on the bridge. IP Address IP Address of the devices on the bridge. Interface The interface on which the ePMP identified the devices on. Bridge Table MAC Address The hardware address of the ePMP device. Port The port to which the device is connected. SM MAC MAC Address for the connected SM device. Aging Timer
(secs) Time set for the MAC addresses in the Bridge table before renewal. Monitor > System Log page The System Log page is used to view the device system log and to download the log file to the accessing PC/device. Chapter 4: Using the Device Management Interface 214 Figure 90: Monitor>SystemLogpage Table 145 Monitor > System Log page attributes Attribute Description Syslog Display Enabled: The system log file is displayed on the management UI. Disabled: The system log file is hidden on the management UI. Download Use this button to download the full system log file to a connected PC or device. Tools menu The Tools menu provides several options for upgrading device software, configuration backup/restore, managing licenses, analyzing RF spectrum, testing the wireless link, testing network connectivity, and analyzing interferers. Tools > Software Upgrade page The Software Upgrade page is used to update the device radio software to take advantage of new software features and improvements. Attention Read the Release Notes associated with each software release for special notices, feature updates, resolved software issues, and known software issues. The Release Notes may be accessed at the Cambium Support Center. Chapter 4: Using the Device Management Interface 215 Figure 91: Tools>SoftwareUpgradepage Table 146 Tools > Software Upgrade page attributes Attribute Description Main Software Hardware Version Software Version Software Version
(Active Bank) Software Version
(Inactive Bank) Firmware Version Upgrade Options Defines the board type and frequency band of operation. Defines the current operating software version. ePMP devices two banks of flash memory which each contain a version of the software. The version of the software last upgraded onto the flash memory is made the active bank. This software is used by the device when rebooted. The version of the software that was the Active Bank is made the Inactive Bank when another version of the software is upgraded onto the Flash memory. The Inactive Bank of the software is used by the device in case the Active Bank cannot be used due to a failure condition. The current U-boot version. URL: A web server may be used to retrieve software upgrade packages (downloaded to the device via the webserver). For example, if a web server is running at IP address 192.168.2.1 and the software upgrade packages are located in the home directory, an operator may select an option From URL and configure the Software Upgrade Source field to http://192.168.2.1/<software_upgrade_package>. Local File: Click Browse to select the local file containing the software upgrade package. Chapter 4: Using the Device Management Interface 216 Attribute Description Select File Click Browse to select a local file (located on the device accessing the web management interface) for upgrading the device software. Upgrade Click the Upgrade button to begin the software upgrade process. Ensure that the power to the device is not interrupted during a software upgrade. Power interruption may cause flash corruption and render the device inoperable. GPS Firmware Firmware Version Upgrade Options The current firmware of the on-board GPS chip. URL: A web server may be used to retrieve GPS firmware upgrade packages
(downloaded to the device via the webserver). For example, if a web server is running at IP address 192.168.2.1 and the firmware upgrade packages are located in the home directory, an operator may select an option From URL and configure the GPS Firmware Upgrade Source field to http://192.168.2.1/<firmware_upgrade_package>. Local File: Click Browse and select the local file containing the GPS firmware upgrade package. Select File Click Browse and select a local file (located on the device accessing the web management interface) for upgrading the on-board GPS chip firmware. Tools > Backup/Restore page The Backup/Restore page is used to update the device radio software to take advantage of new software features and improvements. Chapter 4: Using the Device Management Interface 217 Figure 92: Tools>Backup/Restorepage Table 147 Tools > Backup/Restore page attributes Attribute Description Backup Configuration Configuration File Format Text (Editable): This option downloads the configuration file in the .json format and can be viewed and/or edited using a standard text editor. Binary (Secured): This option downloads the configuration file in the .bin format, and cannot be viewed and/or edited using an editor. Use this format for a secure backup. Restore Configuration Select File Skip unsupported configuration elements Click Browse and select a local file (located on the device accessing the web management interface) for restoring the device configuration. In the case of configuration incompatibility, the unsupported configuration elements can be ignored and skipped. Factory Default Configuration Reset Via Power Sequence Enabled: When enabled, it is possible to reset the radios configuration to factory defaults using the power cycle sequence explained under Resetting ePMP to factory defaults by power cycling. Disabled: When disabled, it is not possible to factory default the radios configuration using the power cycle sequence. Retain Passwords When set to Enabled, then after a factory default of the radio for any reason, the passwords used for UI and CLI access does not be defaulted and remains unchanged. The default value of this field is Disabled. Keep Passwords Reset to Factory Defaults If the passwords cannot be retrieved after the factory default, access to the radio will be lost/unrecoverable. This feature prevents unauthorized users from gaining access to the radio for any reason, including theft. When the Keep Passwords checkbox is selected, the passwords used for GUI and CLI access will not be defaulted and remains unchanged. This is a one-time option, and it does not apply to factory default procedures completed by power cycling (Reset Via Power Sequence). Use this button to reset the device to its factory default configuration. A reset to factory default configuration resets all device parameters. With the SM device in the default configuration, it may not be able to register to an APdevice configured for your network. Backup Technical Support File Download The Backup Technical Support File is a compressed archive of the applicable statistics and configuration parameters used by Cambium Networks Support for troubleshooting. This file is downloaded from the ePMP device to the accessing device. Chapter 4: Using the Device Management Interface 218 Tools > License Management page (Access Point Mode) The APs License Management page is used to:
l Install licensing for ePMP Elevate subscriber access allotments l Convert the AP from Lite (10 subscribers) to Full (120 subscribers) l Configure the Country Code ETSI-locked devices. There are two types of ePMP elevate license management mechanisms available on the ePMP device Flexible and Fixed, described below:
Figure 93: APePMPElevatelicensemanagementoptions Note Elevate Flexible Licensing is available only for ePMP AP devices with GPS sync. Country Code configuration for ETSI locked device and Full Capacity Keys for AP Lite devices are available only via Fixed License Management. Elevate is available via Fixed or Flexible License Management. Note To use flexible licensing, the AP must have DNS server access to be able to resolve URLs (and communicate with the license server). Also, the AP must have a valid, accurate time server (NTP) connection. Chapter 4: Using the Device Management Interface 219 Figure 94: Tools>LicenseManagementpage Table 148 Tools > License Management attributes Attribute Description Flexible License Management License Server Agent Cloud Licensing ID Connection Status Disabled: No communication with the License Server is established Enabled: Enables License Server functionality to obtain the number of allowed ePMP Elevate SMs to be connected to the AP This field represents a Cambium Networks customer identification used for AP identification on the License Server. This identifier is generated upon License Entitlement activation at the Cambium Networks web-based Support Center. The Connection Status displays the License Server process state when the License Server Agent is Enabled. This status may also be referenced on the device Home page. Enable Proxy Disabled: The AP must have a valid internet connection to reach the license server Enabled: A proxy server is specific for the license server access from a private network Proxy Server IP Address Specify the IP address of the proxy server used for internet access from a private network Proxy Server Port Refresh Requests Failed Specify the port used on the proxy server for internet access from a private network The number of failed refresh (polling) requests to the License Server. The ePMP Elevate Subscriber Module Limit resets to 1 after the 3rd failed refresh request. Chapter 4: Using the Device Management Interface 220 Attribute Description Update Requests Failed NTP Status ePMP Elevate Subscriber Module Limit The number of failed updates (licensing information transfer) requests to the License Server. The ePMP Elevate Subscriber Module Limit resets to 1 after the 5th failed updated request. Represents whether or not the current time and date have been retrieved from the configured NTP server The number of ePMP Elevate devices allowed to register to the AP Flexible License Management Local License Key The License Key is obtained from support.cambiumnetworks.com and must be entered into this field to enable additional functionality (registration capacity, ePMP Elevate support) of the ePMP device. Version Specifies the licensing version scheme for the license key. MAC address The MAC Address is extracted from the license key and must match the MAC Address of this device for the licenses to be enacted. Country Code A two-character value representing the licensed country Subscriber Module Limit ePMP Lite / Force 110 devices are limited to 10 SMs in AP TDD mode. SM Limit will display Unlocked if a license is present which allows no limit of SMs to register to the device in AP TDD mode. Signature A valid license key must have a valid signature included. The status is displayed after a license key is entered and saved. Licenses can only be used if the signature is valid. Tools > Spectrum Analyzer page The Spectrum Analyzer feature is no longer available from the web User Interface. This tool is now available as a stand-alone application and available at:
https://support.cambiumnetworks.com/files/epmp_tools_and_docs. Tools > eAlign page The eAlign page is used to aid with subscriber link alignment. Chapter 4: Using the Device Management Interface 221 Figure 95: Figure61Tools>eAlignpage Note A valid link to an SM is required to provide meaningful RSSI measurements. Attention ePMP supports Automatic Transmit Power Control (ATPC) where the Subscriber Module devices are instructed by the Access Point to adjust their Tx power for the Subscriber Module device signal (UL RSSI) to arrive at the Access Point at a predetermined RSSI level (configurable on the Access Point under Configuration
> Radio > Power Control > Subscriber Module Target Receive Level). This feature is beneficial to keep the overall noise floor in the sector to an acceptable level. However, the feature negates the purpose of eAlign measurements on the Access Point device since, during the alignment, the Subscriber Module may constantly change its Tx power. It is recommended to turn off ATPC and set the Subscriber Module Tx power to maximum allowable power during alignment. While aligning the link using eAlign, please follow these steps:
Procedure 1. On the Subscriber Module, set Configuration > Radio > Power Control >
Max Tx Power to Manual. 2. Set Configuration > Radio > Power Control > Transmitter Power to 26 dBm (or maximum value allowed by regulations). 3. Click Save. Chapter 4: Using the Device Management Interface 222 4. Perform link alignment using eAlign. 5. Once alignment is complete, set Configuration > Radio > Power Control >
Max Tx Power back to Auto. 6. Click Save. Tools > Wireless Link Test page The Wireless Link Test page is used to conduct a simple test of wireless throughput. This allows the user to determine the throughput that can be expected on a particular link without having to use external tools. Figure 96: Tools>WirelessLinkTestpage Table 149 Tools > Wireless Link Test page attributes Attribute Test Setup Mode Description Single Radio: The link test is conducted between the AP and one SM. Dual SM: The link test is conducted between the AP and two grouped SM
(must be operating in MU-MIMO mode). SM MAC Address Choose the MAC Address of the SM with which the wireless link test is conducted. Chapter 4: Using the Device Management Interface 223 Attribute Packet Size Duration Downlink Uplink Average Registered SM Description Choose the Packet Size to use for the throughput test. Choose the time duration in seconds to use for the throughput test. This field indicates the result of the throughput test on the downlink, in Mbps. This field indicates the result of the throughput test on the uplink, in Mbps. An auto-adjusting chart displaying the average throughput of the link. This table provides information about the wireless link of each registered SM. Tools > Watchdog page The Watchdog performs ping checks to determine the reachability of a target IP address. If the target IP address is unreachable, a chosen action is performed. Figure 97: Tools>Watchdogpage Table 150 Tools > Watchdog page attributes Attribute Description Test Setup Watchdog Disabled: The device does not ping a specified IP address periodically for verification of connectivity Enabled: The device periodically pings the IP address specified. If IP connectivity is lost, the action defined in Watchdog Action is performed. Watchdog Action Wireless Restart: In case of lost ping connectivity to the specified IP address, the device automatically restarts the wireless interface. Chapter 4: Using the Device Management Interface 224 Attribute Description Ethernet Restart: In case of lost ping connectivity to the specified IP address, the device automatically restarts the Ethernet interface. Device Reboot: In case of lost ping connectivity to the specified IP address, the device automatically reboots. IP Address Indicates the target IP address for which the device attempts ping connectivity diagnostics. Indicates the interval in minutes between each ping connectivity diagnostic. Watchdog Ping Interval Watchdog Ping Retries Indicates the number of ping retries executed by the device before considering the test failed (and conducting the action defined in Watchdog Action). Tools > Ping page The Ping page is used to conduct a simple test of IP connectivity to other devices that are reachable from the network. If no ping response is received or if Destination Host Unreachable is reported, the target may be down, there may be no route back to the device, or there may be a failure in the network hardware (DNS server failure). Figure 98: Tools>Pingpage Table 151 Tools > Ping page attributes Attribute Description Ping IP Address Version IPv4: The ping test is conducted via the IPv4 protocol. IPv6: The ping test is conducted via the IPv6 protocol. IP Address Enter the IP address of the ping target. Chapter 4: Using the Device Management Interface 225 Attribute Description Number of packets (-c) Buffer size
(-s) TTL (-t) Enter the total number of ping requests to send to the target. Enter the number of data bytes to be sent. Set the IP Time-To-Live (TTL) for multicast packets. This flag applies if the ping target is a multicast address. Ping results The results of the ping test are displayed in the box. Tools > Traceroute page The Traceroute page is used to display the route (path) and associated diagnostics for IP connectivity between the device and the destination specified. Figure 99: Tools>Traceroutepage Table 152 Tools > Traceroute page attributes Attribute Description Traceroute IP Address Enter the IP address of the target of the traceroute diagnostic. Fragmentation (-
F) ON: Allow the source and target to fragment probe packets. OFF: Do not fragment probe packets (on the source or target). Trace method (-l) ICMP ECHO: Use ICMP ECHO for traceroute probes. UDP: Use UDP for traceroute probes. Display TTL (-l) ON: Display TTL values for each hop on the route. OFF: Suppress display of TTL values for each hop on the route. Chapter 4: Using the Device Management Interface 226 Attribute Description Verbose (-v) ON: ICMP packets other than TIME_EXCEEDED and UNREACHABLE are displayed in the output. OFF: Suppress display of extraneous ICMP messaging. Traceroute Results Traceroute test results are displayed in the box. Chapter 4: Using the Device Management Interface 227 Chapter 5: Operation and Troubleshooting This chapter provides instructions for operators of ePMP networks. The following topics are described in this chapter:
l General Planning for troubleshooting l Upgrading device software l Testing hardware l Troubleshooting the radio link l Resetting ePMP to factory defaults by power cycling General Planning for troubleshooting Effective troubleshooting depends in part on measures taken before experiencing the trouble in the network. Cambium Networks recommends the following measures for each site:
Procedure 1. Identify troubleshooting tools that are available at your site (such as a protocol analyzer). 2. Identify commands and other sources that can capture baseline data for the site. These may include:
l Ping l tracert or traceroute l Throughput Test results l Throughput data l Configure GUI page captures l Monitor GUI page captures l Session logs 3. Start a log for the site, including:
4. Operating procedures l Site-specific configuration records l Network topology l Software releases l Types of hardware deployed l Site-specific troubleshooting process Chapter 5: Operation and Troubleshooting 228 l Escalation procedures l GPS latitude/longitude of each network element Upgrading device software To take an advantage of new features and software improvements for the ePMP system, visit Cambium Networks ePMP Software website: https://support.cambiumnetworks.com/files/epmp To upgrade the device software, perform the following steps:
1. Login to the device UI via the management IP. 2. Navigate to page Tools, Software Upgrade. 3. Under the Main Software section, set the Upgrade Option to URL to pull the software file from a network software server or select Local File to upload a file from the accessing device. If URL is selected, enter the server IP address, Server Port, and File path. 4. If Local File is selected, click Browse to launch the file selection dialogue. Click Upgrade 5. Do not power off the unit in the middle of an upgrade process. 6. Once the software upgrade is complete, click the Reset icon. Testing hardware This section describes the procedure to test the hardware when it fails while starting or during operation. Before start testing the hardware, verify that all the outdoor cables which connects the device to equipment inside the building, are of the supported type, as defined in Ethernet cabling. Checking the power supply LED When the power supply is connected to the main power supply, the expected LED behavior is:
l The power LED illuminates continuously in Green color. If the expected LED operation does not occur, or if a fault is suspected in the hardware, check the LED states and choose the correct test procedure. l Power LED is off l Ethernet LED is off Power LED is OFF Meaning: Either the power supply is not receiving power from the AC/DC outlet, or there is a wiring fault in the unit. Action: Remove the device cable from the PSU and observe the effect on the power LED. If the power LED does not illuminate, confirm that the main power supply is working, for example, check the plug. If the power supply is working, report a suspected power supply fault to Cambium Networks. Chapter 5: Operation and Troubleshooting 229 Ethernet LED is OFF Meaning: There is no Ethernet traffic between the device and the power supply. Action: The fault may be in the LAN or device cable:
l Remove the LAN cable from the power supply, examine it, and confirm it is not faulty. l If the PC connection is working, remove the AP/SM cable from the power supply, examine it, and check that the wiring to pins 1, 2 and 3, 6 are correct and not crossed. Test Ethernet packet errors reported by the device Login to the device and click Monitor, Performance. Click Reset System Counters at the bottom of the page andwait until LAN RX Total Packet Counterhas reached1 million. If the counter does not increment or increments too slowly, because for example the ePMP system is newly installed and there is no offered Ethernet traffic,then license this procedure and consider using theTest ping packet loss procedure. Check the LAN RX Error Packet Counter statistic. The test has passed if this is less than 10. Test Ethernet packet errors reported by managed switch or router If the device is connected to a managed Ethernet switch or router, it may be possible to monitor the error rate of Ethernet packets. Refer to the UserGuideof the managed network equipment. The test has passed ifthe rate of packet errors reported by the managed Ethernet switch or router is less than 10 in one million packets. Test ping packet loss Using a computer, it is possible to generate andmonitor packetslost between the power supply and the AP/SM. This can be achieved by executing the Command Prompt application whichissupplied as standard with Windows and Mac operating systems. Attention This procedure disrupts network traffic carried by the device under test. Procedure 1. Ensure that the IP address of the computer is configured appropriately for connection to the device under test, and does not conflict with other devices connected to the network. 2. 3. If the power supply is connected to an Ethernet switch or router then connect the computer to a spare port, if available. If it is not possible to connect the computer to a spare port of an Ethernet switch or router, then the power supply must be disconnected from the network in order to execute this test:
l Disconnect the power supply from the network. l Connect the computer directly to the LAN port of the power supply. 4. On the computer, open the Command Prompt application. Chapter 5: Operation and Troubleshooting 230 5. Send 1000 ping packets of length 1500 bytes. The process takes 1000 seconds, which is approximately 17 minutes. If the computer is running a Windows operating system, this is achieved by typing (for an IPv6 address, use the ping6 command):
ping n 1000 l 1500 <ipaddress>
where <ipaddress> is the IP address of the AP or SM under test. If the computer is running a MAC operating system, this is achieved by typing:
ping c 1000 s 1492 <ipaddress>
where <ipaddress> is the IP address of the AP/SM under test. 6. Record how many ping packets are lost. This is reported by Command Prompt on completion of the test. The test has passed if the number of lost packets is less than 2. Troubleshooting the radio link This section describes the process of testing the link when there is no radio communication, when it is unreliable, or when the data throughput rate is too low. It may be necessary to test both ends of the link. The module has lost or does not establish radio connectivity If there is no wireless activity, then perform the following steps:
1. Check that the devices are configured with the same Frequency Carrier. 2. Check that the Channel Bandwidth is configured the same at both ends of the link. 3. On the AP, verify that the Max Range setting is configured to a distance slightly greater than the distance between the Access Point and the other end of the link. 4. Check that the Access Point Synchronization Source is configured properly based on the network configuration. 5. Verify the authentication settings on the devices. if Authentication Type is set to WPA2, verify that the Pre-shared Key matches between the AP and the SM Preferred Access Points List. 6. Check that the software at each end of the link is the same version. 7. Check that the desired AP SSID is configured in the SM Preferred Access Points List. 8. On the SM, check the DL RSSI and DL CINR values. Verify that for the SM installed distance, that the values are consistent with the values reported by the LINKPlanner tool. 9. Check Tx Power on the devices. 10. Check that the link is not obstructed or misaligned. 11. Check the DFS status page (Monitor, System Status) at each end of the link and establish that there is a quiet wireless channel to use. Chapter 5: Operation and Troubleshooting 231 12. If there are no faults found in the configuration and there is absolutely no wireless signal, retry the installation procedure. 13. If this does not work then report a suspected device fault to Cambium Networks. Module exhibiting frequent boots or disconnects For any Force 300-16 units exhibiting frequent disconnects or reboots, the 4.4 official release must be applied twice to ensure both banks are updated. Once completed, ensure both banks are running 4.4 under Monitor > System. In general, this practice can be followed for all 802.11ac models as they support two banks for software storage. Link is unreliable or does not achieve the data rates required If there is some activity but the link is unreliable or does not achieve the data rates required, then perform the following steps:
1. Check that the interference has not increased by monitoring the uplink and downlink CINR values reported in the Access Point page Monitor > Wireless Status. 2. Check that the RSSI values reported at the device are proper based on the distance of the link the LINKPlanner tool is designed to estimate these values. 3. Check that the path loss is low enough for the communication rates required. 4. Check that the device has not become misaligned. 5. Review the Quality of Service configuration and ensure that traffic is properly classified and prioritized. Resetting ePMP to factory defaults by power cycling Operators may reset an ePMP radio to the default factory configuration by a sequence of power cycling
(removing and re-applying power to the device). This procedure allows operators to perform a factory default reset without a tower climb or additional tools. The procedure is depicted in . 1. Remove the Ethernet cable from the PoE jack of the power supply for at least 10 seconds. 2. Reconnect the Ethernet cable to re-supply power to the ePMP device for 3-5 secondsand disconnect the cable to power off the ePMP device for 3-5 seconds. (1st power cycle). 3. Reconnect the Ethernet cable to re-supply power to the ePMP device for 3-5 secondsand disconnect the cable to power off the ePMP device for 3-5 seconds. (2nd power cycle). 4. Reconnect the Ethernet cable to re-supply power to the ePMP device for 3-5 secondsand disconnect the cable to power off the ePMP device for 3-5 seconds. (3rd power cycle). 5. Reconnect the Ethernet cable to re-supply power to the ePMP device for 3-5 secondsand disconnect the cable to power off the ePMP device for 3-5 seconds. (4th power cycle). 6. Reconnect the Ethernet cable to re-supply power to the ePMP device for at least 30 seconds and allow it to go through the boot-up procedure (Note: Device will go through an additional reset automatically). This will reset the current configuration files to factory default configuration (such as IP addresses, Device mode, RF configuration). The device can be pinged from a PC to check if Chapter 5: Operation and Troubleshooting 232 boot-up is complete (Successful ping replies indicate boot-up is complete). 7. Access the ePMP device using the default IP address of 192.168.0.1 (AP) or 192.168.0.2 (SM). Figure 100: Powercycletimings Where:
Is:
V+(ON) Power through PoE has been applied to the device Off ton toff Power through PoE has been removed from the device The time duration for which the device has been powered on. This should be 3-5 seconds. The time duration for which the device has been powered off. This should be 3-5 seconds. Chapter 5: Operation and Troubleshooting 233 Glossary Term Definition AES ANSI CINR CMM DFS EIRP EMC EMD ETH ETSI FCC FEC GUI Advanced Encryption Standard American National Standards Institute Carrier to Interference plus Noise Ratio Cluster Management Module Dynamic Frequency Selection Equivalent Isotropically Radiated Power Electromagnetic Compatibility Electromagnetic Discharge Ethernet European Telecommunications Standards Institute Federal Communications Commission Forward Error Correction Graphical User Interface HTTP Hypertext Transfer Protocol IC Industry Canada IEEE Institute of Electrical and Electronics Engineers IP LAN LED LoS Internet Protocol Local Area Network Light Emitting Diode Line of Sight MIMO Multiple In Multiple Out MIR Maximum Information Rate MU-MIMO Multi-User Multiple In Multiple Out MTU Maximum Transmission Unit nLOS Near Line of Sight NTP Network Time Protocol OFDM Orthogonal Frequency Division Multiplexing PC Personal Computer Glossary 234 Term Definition PMP PTP Point to Multipoint Point to Point QAM Quadrature Amplitude Modulation QPSK Quadrature Phase Shift Keyed RF RMA RSSI Radio Frequency Return Merchandise Authorization Received Signal Strength Indication RTTT Road Transport and Traffic Telematics RX SAR Receive Standard Absorption Rate SNMP Simple Network Management Protocol SW TDD Software Time Division Duplex TDWR Terminal Doppler Weather Radar TX UNII URL Transmit Unlicensed National Information Infrastructure Uniform Resource Locator Glossary 235 Cambium Networks Cambium Networks delivers wireless communications that work for businesses, communities, and cities worldwide. Millions of our radios are deployed to connect people, places and things with a unified wireless fabric that spans multiple standards and frequencies of fixed wireless and Wi-Fi, all managed centrally via the cloud. Our multi-gigabit wireless fabric offers a compelling value proposition over traditional fiber and alternative wireless solutions. We work with our Cambium certified ConnectedPartners to deliver purpose-built networks for service provider, enterprise, industrial, and government connectivity solutions in urban, suburban, and rural environments, with wireless that just works. User Guides http://www.cambiumnetworks.com/guides Technical training https://learning.cambiumnetworks.com/learn Support website (enquiries) https://support.cambiumnetworks.com Main website http://www.cambiumnetworks.com Sales enquiries solutions@cambiumnetworks.com Warranty https://www.cambiumnetworks.com/support/standard-warranty/
Telephone number list http://www.cambiumnetworks.com/contact-us/
Address Cambium Networks Limited, Unit B2, Linhay Business Park, Eastern Road, Ashburton, Devon, TQ13 7UP United Kingdom Cambium Networks and the stylized circular logo are trademarks of Cambium Networks, Ltd. All other trademarks are the property of their respective owners. www.cambiumnetworks.com Copyright 2022 Cambium Networks, Ltd. All rights reserved. Cambium Networks 236
1 2 3 4 5 6 | Internal Photos | Internal Photos | 2.19 MiB | November 09 2022 / May 20 2023 | delayed release |
1 2 3 4 5 6 | External Photos | External Photos | 320.49 KiB | November 09 2022 / May 20 2023 | delayed release |
1 2 3 4 5 6 | Label Location | ID Label/Location Info | 233.31 KiB | November 09 2022 / November 21 2022 |
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1 2 3 4 5 6 | Confidentiality Request | Cover Letter(s) | 114.32 KiB | November 09 2022 / November 21 2022 |
WARNING:pdfminer.pdfpage:The PDF <_io.BufferedReader name='/Volumes/Scratch/Incoming/eg-scratch/6211897.pdf'> contains a metadata field indicating that it should not allow text extraction. Ignoring this field and proceeding. Use the check_extractable if you want to raise an error in this case Cambium Networks Inc. 3800 Golf Road, Suite 360 Rolling Meadows, IL 60008, USA Confidential Letter Date: 2022/10/13 Federal Communications Commission 7435 Oakland Mills Road Columbia MD 21046 Subject: Request for Confidentiality FCC IDZ8H89FT0075 To Whom It May Concern:
Long Term Confidentiality Pursuant to Sections 0.457 and 0.459 of the Commissions Rules, we hereby respectfully request confidential treatment of information accompanying this application as outlined below:
Block Diagrams Schematics Operational Description The above materials contain trade secrets and proprietary information not customarily released to the public. The public disclosure of these matters might be harmful to the Applicant and provide unjustified benefits to its competitors. We understand that pursuant to Rule 0.457, disclosure of this Application and all accompanying documentation will not be made before the date of the Grant for this application. Short Term Confidentiality Pursuant to Sections 0.457 and 0.459 of the Commissions Rules, we hereby respectfully request short-term confidential treatment of information accompanying this application as outlined below until 180 days after the Grant Date of Equipment Authorization in order to ensure sensitive business information remains confidential until the actual marketing of the device:
External Photos Internal Photos Test Setup photos Users Manuals Respectfully, Applicants company name
: Cambium Networks Inc. Applicants company address
: 3800 Golf Road, Suite 360 Rolling Meadows, IL 60008, USA Signature
Name and Job Title
: Steve M. Payne / R.F. Principle Staff Engineer E-Mail Tel Fax
steve.payne@cambiumnetworks.com
: 224-392-5930
: 847-576-0801
1 2 3 4 5 6 | P2P Declaration Letter | Cover Letter(s) | 44.94 KiB | November 09 2022 / November 21 2022 |
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We, Cambium Networks Inc., declare that the radio device is restricted to point-to-point operation and requires professional installation from a Cambium Authorized Professional installer. Regards, FCC Grantee contact person information. Applicants company name
: Cambium Networks Inc. Applicants company address
: 3800 Golf Road, Suite 360 Rolling Meadows, IL 60008, USA Signature
Name and Job Title
: Steve M. Payne / Sr. R.F. Principal Staff Engineer E-Mail Tel Fax
: steve.payne@cambiumnetworks.com
: 224-392-5930
: 847-576-0801
1 2 3 4 5 6 | Power of Attorney Letter | Cover Letter(s) | 87.95 KiB | November 09 2022 / November 21 2022 |
WARNING:pdfminer.pdfpage:The PDF <_io.BufferedReader name='/Volumes/Scratch/Incoming/eg-scratch/6211902.pdf'> contains a metadata field indicating that it should not allow text extraction. Ignoring this field and proceeding. Use the check_extractable if you want to raise an error in this case Cambium Networks Inc. 3800 Golf Road, Suite 360 Rolling Meadows, IL 60008, USA Power of Attorney Date: 2022/10/13 Dear Sir, I hereby have entrusted the following person to be a proxy regarding application for Type Certification. Sporton International Inc. Hsinchu Laboratory Address
: No.8, Lane 724, Bo-ai St., Jhubei City, HsinChu County 302, Taiwan, R.O.C. Name
Leo Huang Job Title
: Manager e-mail
Leohuang@sporton.com.tw I am therefore responsible for the contents of the application. FCC ID: Z8H89FT0075 Respectfully, Applicants company name
: Cambium Networks Inc. Applicants company address
: 3800 Golf Road, Suite 360 Rolling Meadows, IL 60008, USA Signature
Name and Job Title
: Steve M. Payne / R.F. Principle Staff Engineer E-Mail Tel Fax
steve.payne@cambiumnetworks.com
: 224-392-5930
: 847-576-0801
1 2 3 4 5 6 | Professional Installation Declaration | Cover Letter(s) | 111.75 KiB | November 21 2022 |
WARNING:pdfminer.pdfpage:The PDF <_io.BufferedReader name='/Volumes/Scratch/Incoming/eg-scratch/6234925.pdf'> contains a metadata field indicating that it should not allow text extraction. Ignoring this field and proceeding. Use the check_extractable if you want to raise an error in this case Cambium Networks Inc. 3800 Golf Road, Suite 360 Rolling Meadows, IL 60008, USA Professional Installation Declaration Date: 2022/10/13 FCC IDZ8H89FT0075 To Whom It May Concern:
Please be advised that due to the unique Market and function targeted by this product, this product will need special trained professional in configuring and installing the product. We hereby declare that the product will be distributed through controlled distribution channel which has special trained professional to install this product and will not be sold directly to the general public through retail store. Respectfully, Applicants company name
: Cambium Networks Inc. Applicants company address
: 3800 Golf Road, Suite 360 Rolling Meadows, IL 60008, USA Signature
Name and Job Title
: Steve M. Payne / R.F. Principle Staff Engineer E-Mail Tel Fax
steve.payne@cambiumnetworks.com
: 224-392-5930
: 847-576-0801
1 2 3 4 5 6 | Test Setup Photos | Test Setup Photos | 575.02 KiB | November 09 2022 / May 20 2023 | delayed release |
frequency | equipment class | purpose | ||
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1 | 2024-08-13 | 6535 ~ 6855 | 6FC - 15E 6 GHz Fixed Client | Class III permissive change to software defined radio |
2 | 2024-08-09 | 6535 ~ 6855 | 6SD - 15E 6 GHz Standard Power Access Point | Class III Permissive Change |
3 | 2024-05-15 | 6535 ~ 6855 | 6FX - 15E 6 GHz Standard Client Device | |
4 | 2024-05-14 | 6535 ~ 6855 | 6SD - 15E 6 GHz Standard Power Access Point | |
5 | 2024-05-13 | 6535 ~ 6855 | 6FC - 15E 6 GHz Fixed Client | |
6 | 2022-11-21 | 5745 ~ 5825 | NII - Unlicensed National Information Infrastructure TX | Original Equipment |
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2024-08-13
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1 2 3 4 5 6 | Applicant's complete, legal business name |
Cambium Networks Inc.
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1 2 3 4 5 6 | FCC Registration Number (FRN) |
0016216152
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1 2 3 4 5 6 | Physical Address |
3800 Golf Road Suite 360
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3800 Golf Road
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Rolling Meadows, Illinois 60008
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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******@timcoengr.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 |
Z8H
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1 2 3 4 5 6 | Equipment Product Code |
89FT0075
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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 |
S******** M******** P****
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1 2 3 4 5 6 | Title |
R.F. Principle Staff Engineer
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1 2 3 4 5 6 | Telephone Number |
224-3********
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1 2 3 4 5 6 | Fax Number |
847-5********
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1 2 3 4 5 6 |
s******@cambiumnetworks.com
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app s | Technical Contact | |||||
n/a | ||||||
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?: | 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 | ||||
1 2 3 4 5 6 | Yes | |||||
1 2 3 4 5 6 | If so, specify the short-term confidentiality release date (MM/DD/YYYY format) | 11/11/2024 | ||||
1 2 3 4 5 6 | 11/10/2024 | |||||
1 2 3 4 5 6 | 11/09/2024 | |||||
1 2 3 4 5 6 | 05/20/2023 | |||||
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? | Yes | ||||
1 2 3 4 5 6 | Equipment Class | 6FC - 15E 6 GHz Fixed Client | ||||
1 2 3 4 5 6 | 6SD - 15E 6 GHz Standard Power Access Point | |||||
1 2 3 4 5 6 | 6FX - 15E 6 GHz Standard Client Device | |||||
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) | ePMP 6GHz Force 4625 SM | ||||
1 2 3 4 5 6 | Related OET KnowledgeDataBase Inquiry: Is there a KDB inquiry associated with this application? | Yes | ||||
1 2 3 4 5 6 | Modular Equipment Type | Does not apply | ||||
1 2 3 4 5 6 | Purpose / Application is for | Class III permissive change to software defined radio | ||||
1 2 3 4 5 6 | Class III Permissive Change | |||||
1 2 3 4 5 6 | Original Equipment | |||||
1 2 3 4 5 6 | Composite Equipment: Is the equipment in this application a composite device subject to an additional equipment authorization? | No | ||||
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 | Power listed is EIRP. Software Defined Radio. Professional installation is required. Device operates with specific antennas in MIMO configurations as described in this filing. The antennas used for this device must be installed to provide a separation distance of at least 36 cm from all persons and must not transmit simultaneously with any other antenna or transmitter, except in accordance with FCC multi-transmitter product procedures. Users must be provided with installation instructions and transmitter operating conditions for satisfying RF exposure compliance. This device has 20, 40, 80 and 160 MHz bandwidth modes. Class III Permissive Change: Adds the frequencies 6835 MHz with 80 MHz bandwidth and 6795 MHz with 160 MHz bandwidth in U-NII Band 7 for 6SD and 6FC modes via software update. | ||||
1 2 3 4 5 6 | Power listed is EIRP. Software Defined Radio. Device operates with specific antennas in MIMO configurations as described in this filing. The antennas used for this device must be installed to provide a separation distance of at least 36 cm from all persons and must not transmit simultaneously with any other antenna or transmitter, except in accordance with FCC multi-transmitter product procedures. Users must be provided with installation instructions and transmitter operating conditions for satisfying RF exposure compliance. This device has 20, 40, 80 and 160 MHz bandwidth modes. Class III Permissive Change: Adds Standard Power Access Point, Standard Client and Fixed Client operation via software change. | |||||
1 2 3 4 5 6 | Output Power listed is the maximum conducted output power. This device must be installed and operated so as to provide a separation distance of at least 20 cm from all persons and must not be co-located or operating in conjunction with any other antenna or transmitter, except in accordance with FCC multi-transmitter product procedures, or as evaluated in this filing. This device supports 20, 40 and 80 MHz modes. System requires professional Installation. | |||||
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 |
Sporton International Inc. Hsinchu Laboratory
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1 2 3 4 5 6 | Name |
A**** C********
|
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1 2 3 4 5 6 | Telephone Number |
+886-********
|
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1 2 3 4 5 6 | Fax Number |
+886-********
|
||||
1 2 3 4 5 6 |
a******@sporton.com.tw
|
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Equipment Specifications | |||||||||||||||||||||||||||||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
1 | 1 | 15E | EP MO | 5955 | 6415 | 3.89 | |||||||||||||||||||||||||||||||||||
1 | 2 | 15E | EP MO | 6535 | 6855 | 3.963 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
2 | 1 | 15E | EP MO | 5955 | 6415 | 3.89 | |||||||||||||||||||||||||||||||||||
2 | 2 | 15E | EP MO | 6535 | 6855 | 3.963 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
3 | 1 | 15E | EP MO | 5955 | 6415 | 3.89 | |||||||||||||||||||||||||||||||||||
3 | 2 | 15E | EP MO | 6535 | 6855 | 3.963 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
4 | 1 | 15E | EP MO | 5955 | 6415 | 3.89 | |||||||||||||||||||||||||||||||||||
4 | 2 | 15E | EP MO | 6535 | 6855 | 3.963 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
5 | 1 | 15E | EP MO | 5955 | 6415 | 3.89 | |||||||||||||||||||||||||||||||||||
5 | 2 | 15E | EP MO | 6535 | 6855 | 3.963 | |||||||||||||||||||||||||||||||||||
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
6 | 1 | 15E | MO | 5745.00000000 | 5825.00000000 | 0.0003200 |
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