| all | frequencies |
|
|
exhibits | applications |
|---|---|---|---|---|---|
| manuals | |||||
| app s | submitted / available | |||||||
|---|---|---|---|---|---|---|---|---|
| 1 2 3 4 |
|
USERS MANUAL | Users Manual | 2.85 MiB | September 04 2014 | |||
| 1 2 3 4 |
|
User Manual | Users Manual | 4.10 MiB | ||||
| 1 2 3 4 | Cover Letter(s) | |||||||
| 1 2 3 4 | Cover Letter(s) | |||||||
| 1 2 3 4 | Cover Letter(s) | |||||||
| 1 2 3 4 | External Photos | |||||||
| 1 2 3 4 | Internal Photos | |||||||
| 1 2 3 4 | ID Label/Location Info | |||||||
| 1 2 3 4 | ID Label/Location Info | |||||||
| 1 2 3 4 | RF Exposure Info | |||||||
| 1 2 3 4 | Test Report | |||||||
| 1 2 3 4 | Test Setup Photos | |||||||
| 1 2 3 4 | Parts List/Tune Up Info | |||||||
| 1 2 3 4 | Cover Letter(s) | |||||||
| 1 2 3 4 | Cover Letter(s) | September 04 2014 | ||||||
| 1 2 3 4 | ID Label/Location Info | September 04 2014 | ||||||
| 1 2 3 4 | Cover Letter(s) | September 04 2014 | ||||||
| 1 2 3 4 | ID Label/Location Info | September 04 2014 | ||||||
| 1 2 3 4 | RF Exposure Info | September 04 2014 |
| 1 2 3 4 | USERS MANUAL | Users Manual | 2.85 MiB | September 04 2014 |
January 2014 Version 1.1.6
| 1 Copyright Copyright 2014 4RF Limited. All rights reserved. This document is protected by copyright belonging to 4RF Limited and may not be reproduced or republished in whole or part in any form without the prior written permission of 4RF Limited. Trademarks Aprisa and the 4RF logo are trademarks of 4RF Limited. Windows is a registered trademark of Microsoft Corporation in the United States and other countries. Java and all Java-related trademarks are trademarks or registered trademarks of Sun Microsystems, Inc. in the United States and other countries. All other marks are the property of their respective owners. Disclaimer Although every precaution has been taken preparing this information, 4RF Limited assumes no liability for errors and omissions, or any damages resulting from use of this information. This document or the equipment may change, without notice, in the interests of improving the product. RoHS and WEEE compliance The Aprisa SR+ is fully compliant with the European Commissions RoHS (Restriction of Certain Hazardous Substances in Electrical and Electronic Equipment) and WEEE (Waste Electrical and Electronic Equipment) environmental directives. Restriction of hazardous substances (RoHS) The RoHS Directive prohibits the sale in the European Union of electronic equipment containing these hazardous substances: lead, cadmium, mercury, hexavalent chromium, polybrominated biphenyls (PBBs), and polybrominated diphenyl ethers (PBDEs). 4RF has worked with its component suppliers to ensure compliance with the RoHS Directive which came into effect on the 1st July 2006. End-of-life recycling programme (WEEE) The WEEE Directive concerns the recovery, reuse, and recycling of electronic and electrical equipment. Under the Directive, used equipment must be marked, collected separately, and disposed of properly. 4RF has instigated a programme to manage the reuse, recycling, and recovery of waste in an environmentally safe manner using processes that comply with the WEEE Directive (EU Waste Electrical and Electronic Equipment 2002/96/EC). 4RF invites questions from customers and partners on its environmental programmes and compliance with the European Commissions Directives (sales@4RF.com). Aprisa SR+ Product Description 2 |
Compliance General The Aprisa SR+ radio predominantly operates within frequency bands that require a site license be issued by the radio regulatory authority with jurisdiction over the territory in which the equipment is being operated. It is the responsibility of the user, before operating the equipment, to ensure that where required the appropriate license has been granted and all conditions attendant to that license have been met. Changes or modifications not approved by the party responsible for compliance could void the users authority to operate the equipment. Equipment authorizations sought by 4RF are based on the Aprisa SR+ radio equipment being installed at a fixed restricted access location and operated in point-to-multipoint or point-to-point mode within the environmental profile defined by EN 300 019, Class 3.4. Operation outside these criteria may invalidate the authorizations and / or license conditions. The term Radio with reference to the Aprisa SR+ User Manual, is a generic term for one end station of a point-to-multipoint Aprisa SR+ network and does not confer any rights to connect to any public network or to operate the equipment within any territory. Compliance European Telecommunications Standards Institute The Aprisa SR+ radio is designed to comply with the European Telecommunications Standards Institute
(ETSI) specifications as follows:
12.5 kHz and 25 kHz Channel Radio performance EN 300 113-2 EMC Environmental EN 301 489 Parts 1 & 5 EN 300 019, Class 3.4 Ingress Protection code IP51 Safety EN 60950-1:2006 Class 1 div 2 for hazardous locations Frequency band Channel size Power input 135-175 MHz 320-400 MHz 400-470 MHz 450-520 MHz 12.5 kHz, 25 kHz 12.5 kHz, 25 kHz 12.5 kHz, 25 kHz 12.5 kHz, 25 kHz 12 VDC 12 VDC 12 VDC 12 VDC Notified body Aprisa SR+ Product Description
| 3 Compliance Federal Communications Commission The Aprisa SR+ radio is designed to comply with the Federal Communications Commission (FCC) specifications as follows:
Radio EMC Environmental 47CFR part 24, part 90 and part 101 Private Land Mobile Radio Services 47CFR part 15 Radio Frequency Devices, EN 301 489 Parts 1 & 4 EN 300 019, Class 3.4 Ingress Protection code IP51 Safety EN 60950-1:2006 Class 1 div 2 for hazardous locations Frequency Band Channel size Power input Authorization FCC ID 135-175 MHz 216-220 MHz 12.5 kHz, 25 kHz 12 VDC Part 90 12.5 kHz, 25 kHz, 50 kHz 12 VDC Part 90 Pending Pending 400-470 MHz 12.5 kHz, 25 kHz 12 VDC Part 90 UIPSQ400M131 450-520 MHz 12.5 kHz, 25 kHz 12 VDC Part 90 896-902 MHz 12.5 kHz, 25 kHz 12 VDC Part 90 896-902 MHz 928-960 MHz 12.5 kHz, 25 kHz, 50 kHz 12.5 kHz, 25 kHz, 50 kHz 12 VDC Part 24 12 VDC Part 24 and Part 101 Pending Pending Pending Pending NOTE: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense. Aprisa SR+ Product Description 4 |
Compliance Industry Canada The Aprisa SR+ radio is designed to comply with Industry Canada (IC) specifications as follows:
Radio EMC RSS-119 / RSS-134 This Class A digital apparatus complies with Canadian standard ICES-003. Cet appareil numrique de la classe A est conforme la norme NMB-003 du Canada. Environmental EN 300 019, Class 3.4 Ingress Protection code IP51 Safety EN 60950-1:2006 Class 1 div 2 for hazardous locations Frequency Band Channel size Power input Authorization IC ID 135-175 MHz 12.5 kHz, 25 kHz 12 VDC RSS-119 215-240 MHz 12.5 kHz, 25 kHz 12 VDC RSS-119 Pending Pending 400-470 MHz 12.5 kHz, 25 kHz 12 VDC RSS-119 6772A-SQ400M131 896-902 MHz 12.5 kHz, 25 kHz 12 VDC RSS-119 896-902 MHz 928-960 MHz 12.5 kHz, 25 kHz, 50 kHz 12.5 kHz, 25 kHz, 50 kHz 12 VDC RSS-134 12 VDC RSS-119 and RSS-134 Pending Pending Pending Compliance Hazardous Locations Notice This product is suitable for use in Class 1, Division 2, Groups A - D hazardous locations or non-hazardous locations. The following text is printed on the Aprisa SR+ fascia:
WARNING: EXPLOSION HAZARD - Do not connect or disconnect while circuits are live unless area is known to be non-hazardous. The following text is printed on the Aprisa SR+ for product where the end user is in Canada:
AVERTISSEMENT: RISQUE D'EXPLOSION - Ne pas brancher ou dbrancher tant que le circuit est sous tension, moins qu'il ne s'agisse d'un emplacement non dangereux. Aprisa SR+ Product Description RF Exposure Warning
| 5 WARNING:
The installer and / or user of Aprisa SR+ radios shall ensure that a separation distance as given in the following table is maintained between the main axis of the terminals antenna and the body of the user or nearby persons. Minimum separation distances given are based on the maximum values of the following methodologies:
1. Maximum Permissible Exposure non-occupational limit (B or general public) of 47 CFR 1.1310 and the methodology of FCCs OST/OET Bulletin number 65. 2. Reference levels as given in Annex III, European Directive on the limitation of exposure of the general public to electromagnetic fields (0 Hz to 300 GHz)
(1999/519/EC). These distances will ensure indirect compliance with the requirements of EN 50385:2002. Frequency (MHz) Maximum Power Maximum Antenna Minimum Separation
(dBm) Note 1 Gain (dBi) Distance
(m) 135 175 215 216.5 217.5 240 320 400 450 470 520 896 902 928 960
+ 37
+ 37
+ 37
+ 37
+ 33
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37 15 15 15 15 15 15 15 15 15 15 15 28 28 28 28 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 7.5 7.5 7.5 7.5 Note 1: The Peak Envelope Power (PEP) at maximum set power level is +41 dBm. Aprisa SR+ Product Description Contents Contents | 7 1. Introduction ............................................................................ 11 The 4RF Aprisa SR+ Radio ...................................................................... 11 Product Overview ............................................................................... 12 Network Coverage and Capacity ....................................................... 12 Automatic Registration .................................................................. 12 Remote Messaging ........................................................................ 12 Product Features ................................................................................ 13 Functions .................................................................................. 13 Performance .............................................................................. 14 Usability ................................................................................... 14 System Gain vs FEC Coding ............................................................. 15 Architecture ...................................................................................... 16 Security ........................................................................................... 17 Interfaces ......................................................................................... 18 Antenna Interface ........................................................................ 18 Ethernet Interface ....................................................................... 18 RS-232 Interface .......................................................................... 18 USB Interfaces ............................................................................ 18 Protect Interface ......................................................................... 18 Alarms Interface .......................................................................... 18 Mounting .......................................................................................... 19 DIN Rail Mounting ........................................................................ 19 Rack Shelf Mounting ..................................................................... 21 Wall Mounting ............................................................................. 22 2. Product Options ....................................................................... 23 Interface Ports ................................................................................... 23 Protected Station ............................................................................... 24 Protected Ports ........................................................................... 24 Operation .................................................................................. 25 Switch Over ........................................................................ 25 Configuration Management ...................................................... 25 Data Driven Protected Station................................................................. 26 Operation .................................................................................. 26 Duplexer Kits ..................................................................................... 27 UHF Duplexer Kits ........................................................................ 27 VHF Duplexer Kits ........................................................................ 28 USB RS-232 Serial Port .......................................................................... 29 USB RS-232 operation .................................................................... 29 Aprisa SR+ Product Description 8 | Contents 3. Specifications .......................................................................... 30 RF Specifications ................................................................................ 30 Frequency Bands ......................................................................... 30 Channel Sizes ............................................................................. 31 Receiver ................................................................................... 34 Transmitter ............................................................................... 37 Modem ..................................................................................... 37 Data Payload Security ................................................................... 37 Interface Specifications ........................................................................ 38 Ethernet Interface ....................................................................... 38 RS-232 Asynchronous Interface ......................................................... 39 Hardware Alarms Interface ............................................................. 40 Protection Switch Specifications ....................................................... 40 Power Specifications ............................................................................ 41 Power Supply .............................................................................. 41 Power Consumption ...................................................................... 42 Power Dissipation ........................................................................ 42 General Specifications .......................................................................... 43 Environmental ............................................................................ 43 Mechanical ................................................................................ 43 Compliance ................................................................................ 44 4. Management ........................................................................... 45 SuperVisor ........................................................................................ 45 Viewing the Aprisa SR+ Terminal Settings ............................................ 46 Configuring the Aprisa SR+ Terminal Details ......................................... 47 Configuring the Aprisa SR+ RF Network Details ...................................... 47 Configuring the Aprisa SR+ Radio Settings ............................................ 48 Command Line Interface ....................................................................... 49 SNMP .............................................................................................. 49 LED Display Panel ............................................................................... 50 Normal Operation ........................................................................ 50 Single Radio Software Upgrade ......................................................... 51 Network Software Upgrade ............................................................. 51 Test Mode ................................................................................. 51 5. Applications ............................................................................ 52 Basic point-to-multipoint application ........................................................ 52 Advanced point-to-multipoint application with repeater ................................. 53 Multi-interface point-to-multipoint application ............................................ 54 Multi-hop Daisy Chain Repeaters in LBS Mode Application ................................ 55 Pseudo Peer to Peer using Base-Repeater Application .................................... 56 Aprisa SR+ Product Description Contents | ix 6. Product Architecture ................................................................. 57 Product Operation .............................................................................. 57 Physical Layer ............................................................................. 57 Data Link Layer / MAC layer ............................................................ 57 Channel Access .................................................................... 57 Hop by Hop Transmission ......................................................... 58 Adaptive Coding Modulation ..................................................... 59 Network Layer ............................................................................ 60 Packet Routing ..................................................................... 60 Static IP Router .................................................................... 61 Bridge Mode with VLAN Aware .................................................. 63 VLAN Bridge Mode Description .................................................. 64 Avoiding Narrow Band Radio Traffic Overloading .................................... 66 Product Architecture ........................................................................... 68 Aprisa SR+ Radio Block Diagram ........................................................ 69 Aprisa SR+ Protected Station Block Diagram ......................................... 69 7. Contact Us .............................................................................. 70 Introduction | 11 1. Introduction The 4RF Aprisa SR+ Radio The 4RF Aprisa SR+ is a point-to-multipoint digital radio providing secure narrowband wireless data connectivity for SCADA, infrastructure and telemetry applications. The radios carry a combination of serial packet data and Ethernet data between the base station, repeater stations and remote stations. The Aprisa SR+ is configurable as a point-to-multipoint base station, a remote station or a repeater station. Aprisa SR+ Product Description 12 | Introduction Product Overview Network Coverage and Capacity The Aprisa SR+ has a typical link range of up to 120 km, however, geographic features, such as hills, mountains, trees and foliage, or other path obstructions, such as buildings, will limit radio coverage. Additionally, geography may reduce network capacity at the edge of the network where errors may occur and require retransmission. However, the Aprisa SR+ uses 10W output power and Forward Error Correction
(FEC) which greatly improves the sensitivity and system gain performance of the radio resulting in less retries and minimal reduction in capacity. Ultimately, the overall performance of any specific network will be defined by a range of factors including the RF output power, the modulation used and its related receiver sensitivity, the geographic location, the number of remote stations in the base station coverage area and the traffic profile across the network. Effective network design will distribute the total number of remote stations across the available base stations to ensure optimal geographic coverage and network capacity. One base station can register and operate with up to 500 remote / repeater stations. The practical limit of remote / repeater stations that can operate with one base station is determined by a range of factors including the number of services, the packet sizes, the protocols used, the message types and network timeouts. Automatic Registration On start-up, the remote station transmits a registration message to the base stations which responds with a registration response. This allows the base station to record the details of all the remote stations active in the network. If a remote station cannot register with the base station after multiple attempts (RF LED flashing red) within 10 minutes, it will automatically reboot. If a remote station has registered with the base station but then loses communication, it will automatically reboot within 2 minutes. Remote Messaging There are two message types in the Aprisa SR+ network, broadcast messages and unicast messages. Broadcast messages are transmitted by the base station to the remote stations and unicast messages are transmitted by the remote station to the base station. These messages are commonly referred to as uplink
(unicast remote to base) and downlink (broadcast base to remote). All remotes within the coverage area will receive broadcast messages and pass them on to either the Ethernet or serial interface. The RTU determines if the message is intended for it and will accept it or discard it. Aprisa SR+ Product Description Introduction | 13 Product Features Functions Point-to-point (PTP) or Point-to-multipoint (PMP) operation Licensed frequency bands:
VHF 135 VHF 220 UHF 320 UHF 400 UHF 450 UHF 896 UHF 928 135-175 MHz 216-220 MHz 320-400 MHz 400-470 MHz 450-520 MHz 896-902 MHz 928-960 MHz Channel sizes software selectable:
12.5 kHz 25 kHz 50 kHz Adaptive Coding Modulation (ACM): QPSK to 64 QAM Half duplex or full duplex RF operation (full duplex channel access for point-to-multipoint available in a future software release) Ethernet data interface and RS-232 asynchronous multiple port options Software selectable dual / single antenna port options (dual antenna port for external duplexers or filters) Data encryption and authentication using 128,192 and 256 bit AES and CCM security standards Terminal server operation for transporting RS-232 traffic over IP or Ethernet IEEE 802.1Q VLAN support with single and double VLAN tagged and add/remove VLAN manipulation to adapt to the appropriate RTU / PLCs QoS supports using IEEE 802.1p VLAN priority bits to prioritize and handle the VLAN / traffic types L2/3/4 filtering for security and avoiding narrow band radio network overload L3 Router mode with standard static IP route for simple routing network integration L2 Bridge mode with VLAN aware for standard Industrial LAN integration Ethernet header and IP/TCP/UDP ROCH header compression to increase the narrow band radio capacity Ethernet and serial payload compression to increase the narrow band radio capacity Pseudo peer to peer communication between remote stations through base-repeater or repeater stations SuperVisor web management support for element and sub-network (base-repeater-remotes) management SNMPv1/2/3 & encryption MIB supports for 4RF SNMP manager or third party SNMP agent network management SNTP for accurate wide radio network time and date Build-configuration / flexibility of serial and Ethernet interface ports (3+1, 2+2, 4+0) Radio and user interface redundancy (provided with Aprisa SR+ Protected Station) Protected Station fully hot swappable and monitored hot standby Transparent to all common SCADA protocols; e.g. Modbus, IEC 60870-5-101/104, DNP3 or similar Complies with international standards, including ETSI, FCC, IC, EMC, safety and environmental standards Aprisa SR+ Product Description 14 | Introduction Performance Typical deployment of 30 remote stations from one base station with a practical limit of a few hundred remote stations Long distance operation High transmit power Low noise receiver Forward Error Correction Electronic tuning over the frequency band Thermal management for high power over a wide temperature range Usability Configuration / diagnostics via front panel Management Port USB interface, Ethernet interface Built-in webserver SuperVisor with full configuration, diagnostics and monitoring functionality, including remote station configuration / diagnostics over the radio link LED display for on-site diagnostics Dedicated alarm port Software upgrade and diagnostic reporting via the host port USB flash drive Over-the-air software distribution and upgrades Simple installation with integrated mounting holes for wall, DIN rail and rack shelf mounting Aprisa SR+ Product Description Introduction | 15 System Gain vs FEC Coding This table shows the relationship between modulation, FEC coding, system gain, capacity and coverage. Maximum FEC coding results in the highest system gain, the best coverage but the least capacity Minimum FEC coding results in lower system gain, lower coverage but higher capacity No FEC coding results in the lowest system gain, the lowest coverage but the highest capacity This table defines the modulation order based on gross capacity:
Modulation FEC Coding QPSK (High Gain) Max Coded FEC QPSK (Low Gain) Min Coded FEC 16QAM (High Gain) Max Coded FEC QPSK No FEC 16QAM (Low Gain) Min Coded FEC 16QAM No FEC 64QAM (High Gain) Max Coded FEC Capacity Minimum 64QAM (Low Gain) Min Coded FEC Maximum This table defines the modulation order based on receiver sensitivity:
Modulation FEC Coding QPSK (High Gain) Max Coded FEC QPSK (Low Gain) Min Coded FEC 16QAM (High Gain) Max Coded FEC QPSK No FEC 16QAM (Low Gain) Min Coded FEC 64QAM (High Gain) Max Coded FEC 16QAM No FEC Coverage Maximum 64QAM (Low Gain) Min Coded FEC Minimum Aprisa SR+ Product Description 16 | Introduction Architecture The Aprisa SR+ Architecture is based around a layered TCP/IP protocol stack:
Physical Proprietary wireless RS-232 and Ethernet interfaces Link Proprietary wireless (channel access, ARQ, segmentation) VLAN aware Ethernet bridge Network Standard IP Proprietary automatic radio routing table population algorithm Transport TCP, UDP Application HTTPS web management access through base station with proprietary management application software including management of remote stations over the radio link SNMPv1/2/3 for network management application software Aprisa SR+ Product Description Introduction | 17 Security The Aprisa SR+ provides security features to implement the key recommendations for industrial control systems. The security provided builds upon the best in class from multiple standards bodies, including:
IEC/TR 62443 (TC65) Industrial Communications Networks Network and System Security IEC/TS 62351 (TC57) Power System Control and Associated Communications Data and Communication Security FIPS PUB 197, NIST SP 800-38C, IETF RFC3394, RFC3610 and IEEE P1711/P1689/P1685 The security features implemented are:
Data encryption Counter Mode Encryption (CTR) using Advanced Encryption Standard (AES) 128, 192, 258 bit, based on FIPS PUB 197 AES encryption (using Rijndael version 3.0) Data authentication NIST SP 800-38C Cipher Block Chaining Message Authentication Code (CBC-MAC) based on RFC 3610 using Advanced Encryption Standard (AES) Data payload security CCM Counter with CBC-MAC integrity (NIST special publication 800-38C) Secured management interface protects configuration L2 / L3 / L4 Address filtering enables traffic source authorization Proprietary physical layer protocol and modified MAC layer protocol based on standardized IEEE 802.15.4 Licensed radio spectrum provides recourse against interference SNMPv3 with Encryption for NMS secure access Secure USB software upgrade Key Encryption Key (KEK) based on RFC 3394, for secure Over The Air Re-keying (OTAR) of encryption keys User privilege allows the accessibility control of the different radio network users and the user permissions Aprisa SR+ Product Description 18 | Introduction Interfaces Antenna Interface 2 x TNC, 50 ohm, female connectors Single or dual antenna ports (with or without the use of external duplexer/filter) Ethernet Interface 2, 3 or 4 ports 10/100 base-T Ethernet layer 2 switch using RJ45 Used for Ethernet user traffic and radio sub-network management. RS-232 Interface 2, 1 or 0 RS-232 asynchronous ports using RJ45 connector Optional 1x RS-232 asynchronous port using USB host port with USB to RS-232 converter Used for RS-232 asynchronous user traffic only. USB Interfaces 1 x Management port using USB micro type B connector Used for product configuration with the Command Line Interface (CLI). 1 x Host port using USB standard type A connector Used for software upgrade and diagnostic reporting. Protect Interface 1x Protect interface port Used for the Protected Station operation. Alarms Interface 1x Alarm port using RJ45 connector Used to provide 2 x hardware alarm inputs and 2 x hardware alarm outputs Aprisa SR+ Product Description Introduction | 19 Mounting The Aprisa SR+ has four threaded holes (M4) in the enclosure base and two holes (5.2 mm) through the enclosure for mounting. Mounting options include:
DIN rail mounting with the Aprisa SR+ DIN Rail Mounting Bracket Rack shelf mounting Wall mounting Outdoor enclosure mounting DIN Rail Mounting The Aprisa SR+ has an optional accessory to enable the radio to mount on a standard DIN rail:
Part Number Part Description APSB-MBRK-DIN 4RF SR+ Acc, Mounting, Bracket, DIN Rail Aprisa SR+ Product Description 20 | Introduction The Aprisa SR+ DIN rail mounting bracket can be mounted in four positions on a horizontal DIN rail:
Vertical Mount (vertical enclosure perpendicular to the mount) Horizontal Mount (horizontal enclosure perpendicular to the mount) Flat Vertical Mount (vertical enclosure parallel to the mount) Flat Horizontal Mount (horizontal enclosure parallel to the mount) Aprisa SR+ Product Description Rack Shelf Mounting The Aprisa SR+ can be mounted on a rack mount shelf using the four M4 threaded holes in the Aprisa SR+
enclosure base. The following picture shows two Aprisa SR+ radios mounted on 1 RU rack mount shelf. Introduction | 21 Part Number Part Description APSB-MR19-X1U 4RF SR+ Acc, Mounting, 19" Rack Mount Shelf, 1U WARNING:
If the Aprisa SR+ is operated in an environment where the ambient temperature exceeds 50C, the Aprisa SR+ convection air flow over the heat sinks must be considered. Aprisa SR+ Product Description 22 | Introduction Wall Mounting The Aprisa SR+ can be mounted on a wall using the two holes through the enclosure (5.2 mm diameter). Typically, M5 screws longer than 35 mm would be used. Aprisa SR+ Product Description Product Options | 23 2. Product Options Interface Ports The standard Aprisa SR+ provides multiple interface port options for combinations of Ethernet and RS-232 serial. The product shown below is the two Ethernet ports plus two RS-232 serial ports. Interface Port Option Part Number 4 Ethernet ports and no RS-232 serial ports APSQ-N400-SSC-HD-40-ENAA 3 Ethernet ports and 1 RS-232 serial port APSQ-N400-SSC-HD-31-ENAA 2 Ethernet ports and 2 RS-232 serial ports APSQ-N400-SSC-HD-22-ENAA Aprisa SR+ Product Description 24 | Product Options Protected Station The Aprisa SR+ Protected Station is full monitored hot-standby and fully hot-swappable. The Aprisa SR+ Protected Station provides radio and user interface protection for Aprisa SR+ radios when configured as a base station. The RF ports and interface ports from the active Aprisa SR+ radio are switched to the standby radio if there is a failure in the active radio. Option Example Part Number Part Description APSQ-R400-SSC-HD-22-ENAA 4RF SR+, PS, 400-470 MHz, SSC, Half Duplex, 2E2S, EN, AA The Aprisa SR+ Protected Station is comprised of an Aprisa SR+ Protection Switch and two standard Aprisa SR+ radios mounted in a 2U rack mounting chassis. The Aprisa SR+ Protected Station is full monitored hot-standby and fully hot-swappable. All interfaces (RF, data, etc.) are continually monitored on both the active and standby radio to ensure correct operation. The standby radio can be replaced without impacting traffic flow on the active radio. The Aprisa SR+ radios can be any of the currently available Aprisa SR+ radio frequency bands, channel sizes or interface port options. The Aprisa SR+ Protected Station can operate as a base station, repeater station or remote station. The protection behaviour and switching criteria between the active and standby radios is identical for the three configurations. By default, the Aprisa SR+ Protected Station is configured with the left hand radio (A) designated as the primary radio and the right hand radio (B) designated as the secondary radio. Each radio is configured with its own unique IP and MAC address and the address of the partner radio. On power-up, the primary radio will assume the active role and the secondary radio will assume the standby role. If, for some reason, only one radio is powered on it will automatically assume the active role. Protected Ports The protected ports are located on the protected station front panel. Switching occurs between the active radio ports and the standby radio ports based on the switching criteria described below. The protected ports include:
Antenna ports ANT/TX and RX (if dual antenna ports used) Ethernet ports 1 and 2 Serial port Aprisa SR+ Product Description Product Options | 25 Operation In hot-standby normal operation, the active radio carries all RS-232 serial and Ethernet traffic over the radio link and the standby radio transmit is on with its transmitter connected to an internal load. Both radios are continually monitored for correct operation including the transmitter and receiver and alarms are raised if an event occurs. The active radio sends regular keep alive messages to the standby radio to indicate it is operating correctly. In the event of a failure on the active radio, the RF link and user interface traffic is automatically switched to the standby radio. The failed radio can then be replaced in the field without interrupting user traffic (see Aprisa SR+ User Manual). Switch Over The switch over to the standby radio can be initiated automatically, on fault detection, or manually via the Hardware Manual Lock switch on the Protection Switch or the Software Manual Lock from SuperVisor. Additionally, it is possible to switch over the radios remotely without visiting the station site, via the remote control connector on the front of the Protection Switch. Configuration Management The Primary and Secondary radios are managed with the embedded web-based management tool, SuperVisor, by using either the Primary or Secondary IP address. Configuration changes in one of the radios will automatically be reflected in the partner radio. To ensure all remote stations are registered to the correct (active) base station, changes to the Network Table are automatically synchronized from the active radio to the standby radio. The Network Table is only visible on the active radio. This synchronization does not occur if the Hardware Manual Lock is active. Aprisa SR+ Product Description 26 | Product Options Data Driven Protected Station The Aprisa SR+ Data Driven Protected Station provides radio and RS-232 serial port user interface protection for Aprisa SR+ radios. Option Example Part Number Part Description APSQ-D400-SSC-HD-22-ENAA 4RF SR+, PD, 400-470 MHz, SSC, Half Duplex, 2E2S, EN, AA The Aprisa SR+ Data Driven Protected Station shown is comprised of two standard Aprisa SR+ dual antenna port option radios and two external duplexers mounted on 19" rack mounting shelves (as shown above). The Aprisa SR+ radios can be any of the currently available Aprisa SR+ radio frequency bands, channel sizes or single / dual antenna port options. By default, the Aprisa SR+ Data Driven Protected Station is configured with the left hand radio (A) designated as the primary radio and the right hand radio (B) designated as the secondary radio. Each radio is configured with its own unique IP and MAC address and the address of the partner radio. On power-up, the primary radio will assume the active role and the secondary radio will assume the standby role. If, for some reason, only one radio is powered on it will automatically assume the active role. Operation In normal operation, the active radio carries all RS-232 serial and Ethernet traffic over the radio link and the standby radio is unused with its transmitter turned off. Both radios are continually monitored for correct operation and alarms are raised if an event occurs. Both the active and standby radios send regular keep alive messages to each other to indicate if they are operating correctly. In the event of a failure on the active radio, the RF link and user interface traffic is automatically switched to the standby radio. The failed radio can then be replaced in the field without interrupting user traffic. Aprisa SR+ Product Description Product Options | 27 Duplexer Kits The Aprisa SR+ product range contains Duplexer Kit accessories for use with the Dual Antenna port Aprisa SR+ radios. UHF Duplexer Kits The Aprisa SR+ UHF Duplexer Kit contains:
1x 1U 19" rack mount shelf with duplexer mounting brackets and screws 1x Duplexer 2x TNC to SMA right angle 590mm cables Part Number Part Number APSB-KDUP-300-A1 4RF SR+ Acc, Kit, Duplexer, 320-400 MHz, s 5 MHz, p 0.5 MHz, ext APSB-KDUP-400-B1 4RF SR+ Acc, Kit, Duplexer, 400-470 MHz, s 5 MHz, p 0.5 MHz, ext APSB-KDUP-450-M0 4RF SR+ Acc, Kit, Duplexer, 450-520 MHz, s 5 MHz, p 0.5 MHz, ext APSB-KDUP-900-G2 4RF SR+ Acc, Kit, Duplexer, 928-960 MHz, s 9 MHz, p 1 MHz, ext APSB-KDUP-900-G4 4RF SR+ Acc, Kit, Duplexer, 928-960 MHz, s 3.6 MHz, p 0.5 MHz, ext Aprisa SR+ Product Description 28 | Product Options VHF Duplexer Kits The Aprisa SR+ VHF Duplexer Kit contains:
1x 1U 19" rack mount shelf with duplexer mounting brackets and screws 1xVHF Procom Duplexer 1x VHF Filter, Procom BPF 2/3 HX-150, 145 to 174 MHz 1x N type male to N type male 325mm 2x TNC to N type male right angle 590mm cable Part Number Part Number APSB-KDUP-VHF-R2 4RF SR+ Acc, Kit, Duplexer, 152-175 MHz, s4-6 MHz, p100 kHz, High APSB-KDUP-VHF-R3 4RF SR+ Acc, Kit, Duplexer, 152-175 MHz, s6-8 MHz, p100 kHz, High APSB-KDUP-VHF-R4 4RF SR+ Acc, Kit, Duplexer, 152-175 MHz, s8-10 MHz, p100 kHz, High APSB-KDUP-VHF-R5 4RF SR+ Acc, Kit, Duplexer, 138-156 MHz, s4-6 MHz, p100 kHz, Low APSB-KDUP-VHF-R6 4RF SR+ Acc, Kit, Duplexer, 138-156 MHz, s6-8 MHz, p100 kHz, Low APSB-KDUP-VHF-R7 4RF SR+ Acc, Kit, Duplexer, 138-156 MHz, s8-10 MHz, p100 kHz, Low Aprisa SR+ Product Description Product Options | 29 USB RS-232 Serial Port The Aprisa SR+ USB host port is predominantly used for software upgrade and diagnostic reporting. However, it can also be used to provide an additional RS-232 DCE serial port for customer traffic. This is accomplished with a USB to RS-232 serial converter cable. This plugs into the USB host port connector and can be terminated with the required customer connector. This additional RS-232 serial port is enabled with the SuperVisor mode setting in Serial Port Settings. The Aprisa SR+ USB port has driver support for these USB serial converters. Other USB serial converters may not operate correctly. USB RS-232 operation The USB serial converter buffers the received data frames into 64 byte blocks separated by a small inter-
frame gap. For the majority of applications, this fragmentation of egress frames is not an issue. However, there are some applications that may be sensitive to the inter-frame gap, therefore, these applications need consideration. A 5 ms inter-frame is recommended for the applications that are sensitive to inter-frame gap timings. On a USB RS-232 port, Modbus RTU can operate up to 9600 bit/s with all packet sizes and up to 115200 bit/s if the packet size is less than 64 bytes. The standard RS-232 port is fully compatible with Modbus RTU at all baud rates. Aprisa SR+ Product Description 30 | Specifications 3. Specifications RF Specifications Blocking (desensitization), intermodulation, spurious response rejection, and adjacent channel selectivity values determined according to the methods introduced in V1.7.1 of ETSI standards EN 300 113-1. Frequency Bands ETSI Compliant Broadcast Band Frequency Band Frequency Tuning Synthesizer Step Range Size UHF 320 MHz 320-400 MHz 6.250 kHz ETSI / FCC / IC Compliant Broadcast Band Frequency Band Frequency Tuning Synthesizer Step VHF UHF ETSI / FCC Compliant 135 MHz (1) 135-175 MHz Range Size 2.5 kHz 400 MHz 400-470 MHz 6.250 kHz Broadcast Band Frequency Band Frequency Tuning Synthesizer Step Range Size UHF 450 MHz (1) 450-520 MHz 6.250 kHz FCC / IC Compliant Broadcast Band Frequency Band Frequency Tuning Synthesizer Step UHF UHF UHF UHF 220 MHz 220 MHz
(1)
(1) 896 MHz (1) 928 MHz (1) Range 220-222 MHz 216-220 MHz 896-902 MHz 928-960 MHz Size 2.5 kHz 3.125 kHz 6.250 kHz 6.250 kHz Note 1: Please consult 4RF for availability. Aprisa SR+ Product Description Specifications | 31 Channel Sizes ETSI Compliant 135 / 320 / 400 / 450 MHz Bands No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 25 kHz 120.0 kbit/s 80.0 kbit/s 40.0 kbit/s 19.2 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 25 kHz 103.9 kbit/s 46.2 kbit/s 23.1 kbit/s 16.7 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 25 kHz 91.2 kbit/s 34.6 kbit/s 17.3 kbit/s 8.3 kbit/s Aprisa SR+ Product Description 32 | Specifications FCC / IC Compliant 135 / 400 / 450 MHz Bands No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 25 kHz 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 25 kHz 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 41.0 kbit/s 15.6 kbit/s 7.8 kbit/s 4.1 kbit/s 25 kHz 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s Aprisa SR+ Product Description Specifications | 33 220 / 896 / 928 MHz Bands No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 25 kHz 50 kHz 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 25 kHz 50 kHz 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 25 kHz 50 kHz 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Aprisa SR+ Product Description 34 | Specifications Receiver ETSI / FCC / IC Compliant Receiver Sensitivity 12.5 kHz 25 kHz 50 kHz FCC / IC only BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 64 QAM 64 QAM 64 QAM 16 QAM 16 QAM 16 QAM QPSK QPSK QPSK Max coded FEC
-106 dBm
-102 dBm
-99 dBm Min coded FEC
-105 dBm
-101 dBm
-98 dBm No FEC
-103 dBm
-99 dBm
-96 dBm Max coded FEC
-113 dBm
-110 dBm
-107 dBm Min coded FEC
-112 dBm
-109 dBm
-106 dBm No FEC
-109 dBm
-106 dBm
-103 dBm Max coded FEC
-118 dBm
-115 dBm
-112 dBm Min coded FEC
-117 dBm
-114 dBm
-111 dBm No FEC
-115 dBm
-112 dBm
-109 dBm 4-CPFSK Max coded FEC NA NA NA 4-CPFSK Min coded FEC
-117 dBm
-114 dBm
-111 dBm 4-CPFSK No FEC
-115 dBm
-112 dBm
-109 dBm 64 QAM 64 QAM 64 QAM 16 QAM 16 QAM 16 QAM QPSK QPSK QPSK Max coded FEC
-103 dBm
-99 dBm Min coded FEC
-101 dBm
-97 dBm
-96 dBm
-94 dBm No FEC
-96 dBm
-92 dBm
-89 dBm Max coded FEC
-110 dBm
-107 dBm
-104 dBm Min coded FEC
-108 dBm
-105 dBm
-102 dBm No FEC
-102 dBm
-99 dBm
-96 dBm Max coded FEC
-115 dBm
-112 dBm
-109 dBm Min coded FEC
-113 dBm
-110 dBm
-107 dBm No FEC
-108 dBm
-105 dBm
-102 dBm 4-CPFSK Max coded FEC NA NA NA 4-CPFSK Min coded FEC
-113 dBm
-110 dBm
-107 dBm 4-CPFSK No FEC
-108 dBm
-105 dBm
-102 dBm Aprisa SR+ Product Description ETSI / FCC / IC Compliant Adjacent Channel Selectivity Specifications | 35 12.5 kHz 25 kHz 50 kHz FCC / IC only Adjacent channel selectivity
> -47 dBm
> -37 dBm
> -37 dBm BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPFK 4-CPFSK
> 43 dB
> 43 dB
> 48 dB
> 55 dB
> 53 dB
> 53 dB
> 58 dB
> 65 dB
> 53 dB
> 53 dB
> 58 dB
> 65 dB ETSI / FCC / IC Compliant Co-Channel Rejection BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPFK 4-CPFSK 12.5 kHz 25 kHz 50 kHz
> 23 dB
> 19 dB
> 12 dB
> 17 dB
> 23 dB
> 19 dB
> 12 dB
> 17 dB FCC / IC only
> 23 dB
> 19 dB
> 12 dB
> 17 dB ETSI / FCC / IC Compliant Intermodulation Response Rejection 12.5 kHz 25 kHz 50 kHz FCC / IC only Intermodulation response rejection
> -35 dBm
> -35 dBm
> -35 dBm BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPFK 4-CPFSK
> 55 dB
> 55 dB
> 60 dB
> 65 dB
> 55 dB
> 55 dB
> 60 dB
> 65 dB
> 55 dB
> 55 dB
> 60 dB
> 65 dB ETSI / FCC / IC Compliant Blocking or Desensitization 12.5 kHz 25 kHz 50 kHz FCC / IC only Blocking or desensitization
> -17 dBm
> -17 dBm
> -17 dBm BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPFK 4-CPFSK
> 73 dB
> 73 dB
> 78 dB
> 85 dB
> 73 dB
> 73 dB
> 78 dB
> 85 dB
> 73 dB
> 73 dB
> 78 dB
> 85 dB Aprisa SR+ Product Description 36 | Specifications ETSI / FCC / IC Compliant Spurious Response Rejection 12.5 kHz 25 kHz 50 kHz FCC / IC only Spurious response rejection
> -32 dBm
> -32 dBm
> -32 dBm BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPFK 4-CPFSK
> 58 dB
> 58 dB
> 63 dB
> 70 dB
> 58 dB
> 58 dB
> 63 dB
> 70 dB
> 58 dB
> 58 dB
> 63 dB
> 70 dB ETSI / FCC / IC Compliant Receiver Spurious Radiation 12.5 kHz 25 kHz 50 kHz FCC / IC only Receiver spurious radiation
> -57 dBm
> -57 dBm
> -57 dBm Aprisa SR+ Product Description Specifications | 37 Transmitter Average Power output Note: The Peak Envelope Power
(PEP) at maximum set power level is +41 dBm. 64 QAM 16 QAM QPSK 0.01 to 2.5 W (+10 to +34 dBm, in 1 dB steps) 0.01 to 3.2 W (+10 to +35 dBm, in 1 dB steps) 0.01 to 5.0 W (+10 to +37 dBm, in 1 dB steps) 4-CPFSK (Note 1) 0.01 to 10.0 W (+10 to +40 dBm, in 1 dB steps) Note 1: Please consult 4RF for availability Note: The Aprisa SR+ transmitter contains power amplifier protection which allows the antenna to be disconnected from the antenna port without product damage. Adjacent channel power
< - 60 dBc Transient adjacent channel power
< - 60 dBc Spurious emissions Attack time Release time Data turnaround time Frequency stability
< - 37 dBm
< 1.5 ms
< 0.5 ms
< 2 ms 1.0 ppm 0.1 ppm Frequency aging
< 1 ppm / annum The 220 / 896 / 928 MHz products have a frequency stability option of 0.1 ppm. Modem Forward Error Correction Variable length concatenated Reed Solomon plus convolutional code Adaptive Burst Support Adaptive FEC Adaptive Coding Modulation Data Payload Security Data payload security CCM* Counter with CBC-MAC Data encryption Data authentication Counter Mode Encryption (CTR) using Advanced Encryption Standard (AES) 128, 192 or 256 Cipher Block Chaining Message Authentication Code (CBC-MAC) using Advanced Encryption Standard (AES) 128, 192 or 256 Aprisa SR+ Product Description 38 | Specifications Interface Specifications Ethernet Interface The Aprisa SR+ radio features an integrated 10Base-T/100Base-TX layer-2 Ethernet switch. To simplify network setup, each port supports auto-negotiation and auto-sensing MDI/MDIX. Operators can select from the following preset modes:
Auto negotiate 10Base-T half or full duplex 100Base-TX half or full duplex The Ethernet ports are IEEE 802.3-compatible. The L2 Bridge (Switch) is IEEE 802.1d/q/p compatible, and supports VLANs and VLAN manipulation of add/remove VLANs. General Interface RJ45 x 2 (Integrated 2-port switch) Cabling CAT-5/6 UTP, supports auto MDIX (Standard Ethernet) Maximum line length 100 metres on cat-5 or better Bandwidth allocation The Ethernet capacity maximum is determined by the available radio link capacity. Maximum transmission unit Option setting of 1522 or 1536 octets Address table size 1024 MAC addresses Ethernet mode Diagnostics Left Green LED Right Orange LED 10Base-T or 100Base-TX Full duplex or half duplex
(Auto-negotiating and auto-sensing) Off: no Ethernet signal received On: Ethernet signal received Off: no data present on the interface Flashing: data present on the interface Note: Do not connect Power over Ethernet (PoE) connections to the Aprisa SR+ Ethernet ports as this will damage the port. Aprisa SR+ Product Description Specifications | 39 RS-232 Asynchronous Interface The Aprisa SR+ radios ITU-T V.24 compliant RS-232 interface is configured as a Cisco pinout DCE. The interface terminates to a DTE using a straight-through cable or to a DCE with a crossover cable (null modem). The interface uses two handshaking control lines between the DTE and the DCE. General Interface ITU-T V.24 / EIA/TIA RS-232E Async parameters Interface direction DCE only Maximum line length 10 metres (dependent on baud rate) Standard mode data bits 7 or 8 bits Standard mode parity Configurable for None, Even or Odd Standard mode stop bits 1 or 2 bits Interface baud rates 300, 1200, 2400, 4800, 9600, 19200, 38400, 57600 and 115200 bit/s Control signals DCE to DTE CTS, RTS, DSR, DTR Diagnostics Left Green LED Right Orange LED Off: no RS-232 device connected On: RS-232 device connected Off: no data present on the interface Flashing: data present on the interface Aprisa SR+ Product Description 40 | Specifications Hardware Alarms Interface The hardware alarms interface supports two alarm inputs and two alarms outputs. Alarm Inputs The alarm connector provides two hardware alarm inputs for alarm transmission to the other radios in the network. Interface Detector type RJ45 connector Non-isolated ground referenced voltage detector Detection voltage - on Detection voltage - off Maximum applied input voltage Maximum input current limit
> +10 VDC
< +4 VDC 30 VDC 10 mA Alarm Outputs The alarm connector provides two hardware alarm outputs for alarm reception from other radios in the network. Interface Output type RJ45 connector Non-isolated ground referenced open collector output Maximum applied voltage Maximum drive current 30 VDC 100 mA Overload protection Thermally resettable fuse Protect Interface The Protect interface is used to connect the radios to the protection switch within a Protected Station. It is not a customer interface. Interface Female protect connector Protection Switch Specifications RF Insertion Loss
< 0.5 dB Remote Control inputs Logic 4700 ohms pullup to +3.3 VDC Aprisa SR+ Product Description Specifications | 41 Power Specifications Power Supply Aprisa SR+ Radio Nominal voltage
+13.8 VDC (negative earth) Absolute input voltage range
+10 to +30 VDC Maximum power input 35 W Connector Molex 2 pin male screw fitting 39526-4002 Aprisa SR+ Protected Station Nominal voltage
+13.8 VDC (negative earth) Absolute input voltage range
+10 to +30 VDC Maximum power input 35 W Connector 2x Molex 2 pin male screw fitting 39526-4002 Aprisa SR+ Data Driven Protected Station Nominal voltage
+13.8 VDC (negative earth) Absolute input voltage range
+10 to +30 VDC Maximum power input 35 W Connector 2x Molex 2 pin male screw fitting 39526-4002 Aprisa SR+ Product Description 42 | Specifications Power Consumption Note: The radio power consumption is very dependent on transmitter power, the type of traffic and network activity. Aprisa SR+ Radio Mode Power Consumption
(10 W radio with 4-CPFSK modulation) Transmit / Receive
< 35 W for 10 W transmit power
< 25.0 W for 1 W transmit power Receive only
< 7 W Aprisa SR+ Protected Station and Aprisa SR+ Data Driven Protected Station Mode Power Consumption
(10 W radios with 4-CPFSK modulation) Transmit / Receive
< 42 W for 10 W transmit power
< 32.0 W for 1 W transmit power Receive only
< 15 W Power Dissipation Aprisa SR+ Radio Transmit Power Power Dissipation
(10 W radio with 4-CPFSK modulation) 10 W transmit power 1 W transmit power
< 25 W
< 24 W Aprisa SR+ Protected Station and Aprisa SR+ Data Driven Protected Station Transmit Power Power Dissipation
(10 W radios with 4-CPFSK modulation) 10 W transmit power 1 W transmit power
< 32 W
< 31 W Aprisa SR+ Product Description Specifications | 43 General Specifications Environmental Operating temperature range
-40 to +70 C (-40 to +158 F) Storage temperature range
-40 to +80 C (-40 to +176 F) Operating humidity Maximum 95% non-condensing Acoustic noise emission No audible noise emission Mechanical Aprisa SR+ Radio Dimensions Width 210 mm (8.27) Depth 130 mm (5.12) and 146 mm (5.748) with TNC connectors Weight Colour Mounting Height 41.5 mm (1.63) 1.25 kg (2.81 lbs) Matt black Wall (2 x M5 screws) Rack shelf (2 x M4 screws) DIN rail bracket Aprisa SR+ Protected Station Dimensions Width 432.6 mm (17) Weight Colour Mounting Depth 372 mm (14.6) and 388 mm (15.276) with TNC connectors Height 2U plus external duplexer (if used) 12 kg (27 lbs) (includes the 2 radios) Matt black Rack mount (2 x M6 screws) Aprisa SR+ Product Description 44 | Specifications Compliance ETSI Radio EMI / EMC Safety EN 300 113-2 EN 301 489 Parts 1 & 5 EN 60950-1:2006 Class 1 div 2 for hazardous locations Environmental ETS 300 019 Class 3.4 Ingress Protection code IP51 Radio EMC Safety 47CFR part 24, part 90 and part 101 Private Land Mobile Radio Services 47CFR part 15 Radio Frequency Devices, EN 301 489 Parts 1 & 4 EN 60950-1:2006 Class 1 div 2 for hazardous locations Environmental ETS 300 019 Class 3.4 Ingress Protection code IP51 Radio EMC RSS-119 / RSS-134 This Class A digital apparatus complies with Canadian standard ICES-003. Cet appareil numrique de la classe A est conforme la norme NMB-003 du Canada. Safety EN 60950-1:2006 Class 1 div 2 for hazardous locations Environmental ETS 300 019 Class 3.4 Ingress Protection code IP51 Aprisa SR+ Product Description FCC IC Management | 45 4. Management SuperVisor The Aprisa SR+ contains an embedded web server application (SuperVisor) to enable element management with any major web browser (such as Mozilla Firefox or Microsoft Internet Explorer). SuperVisor enables operators to configure and manage the Aprisa SR+ base station radio and repeater /
remote station radios over the radio link. The key features of SuperVisor are:
Full element management, configuration and diagnostics Manage the entire network from the Base Station (remote management of elements) Managed network software distribution and upgrades Performance and alarm monitoring of the entire network, including RSSI, alarm states, time-
stamped events. View and set standard radio configuration parameters including frequencies, transmit power, channel access, serial, Ethernet port settings Set and view security parameters User management Operates over a secure HTTPS session on the access connection to the base station The following are three examples of SuperVisor screens:
Aprisa SR+ Product Description 46 | Management Viewing the Aprisa SR+ Terminal Settings The SuperVisor software enables operators to view the terminal settings:
Aprisa SR+ Product Description Configuring the Aprisa SR+ Terminal Details The SuperVisor software enables operators to set the terminal details including Terminal Name, Location, Contact Name and Contact Details with a maximum of 40 characters. Management | 47 Configuring the Aprisa SR+ RF Network Details The SuperVisor software enables operators to set the RF Network Details including:
Network ID Sets the network ID of this base station node and its remote nodes. Four hex chars Network Radius Sets the maximum number of hops in this network Network Repeaters Proximity Sets the proximity of repeaters in this network Inband Management Enables inband management of remotes / repeaters Inband Management Timeout (sec) Sets the inband management timeout period Aprisa SR+ Product Description 48 | Management Configuring the Aprisa SR+ Radio Settings The SuperVisor software enables operators to set the radio settings including:
TX Frequency Sets the transmit frequency in MHz TX Power RX Frequency Channel Size Sets the transmit Power in dBm Sets the receive frequency in MHz Sets the channel size 12.5 kHz, 25 kHz or 50 kHz (depending on variant) Antenna Port Configuration Sets the antenna port configuration to single port or dual port Modulation Type Sets the fixed TX Modulation Type for the base station radio ACM Control Modulation Range Enables / disables Adaptive Code Modulation for the remote to base direction of transmission (upstream) Sets the upper limit of the range that the base station willl recommmend to the remote radios Aprisa SR+ Product Description Command Line Interface The Aprisa SR+ has a Command Line Interface (CLI) which provides basic product setup and configuration. This interface can be accessed via an Ethernet Port (RJ45) or the Management Port (USB micro type B). The Terminal menu is shown in the following picture:
Management | 49 SNMP In addition to web-based management (SuperVisor) and the Command Line Interface, the Aprisa SR network can also be managed using the Simple Network Management Protocol (SNMP agent). MIB files are supplied which can be used by a dedicated SNMP Manager, such as Castle Rocks network management system, to support effective and flexible network monitoring and diagnostics. Alternatively, the user can use its own 3rd party NMS SNMP agent to manage the SR+ radio network. For communication between the SNMP manager and the radio, Access Controls and Community strings must be set up as described in the Aprisa SR+ User Manual. Aprisa SR+ Product Description 50 | Management LED Display Panel The Aprisa SR+ has an LED Display panel which provides on-site alarms / diagnostics without the need for PC. Normal Operation In normal radio operation, the LEDs indicate the following conditions:
Solid Red Flashing Red Solid Orange Flashing Orange Flashing Green Solid Green OK MODE AUX TX RX Alarm present with severity Critical, Major and Minor Alarm present with Warning Severity Stand-by radio Device detect in protected station Diagnostics Function Active OTA Firmware Distribution on the USB host port
(single flash) Tx Data or Rx Data on the USB management or host port TX path fail RX path fail Radio not Radio not connected to a connected to a base station base station RF path TX is RF path RX is active active Power on and functions OK and no alarms Processor Block is OK or active radio in protected station USB interface Tx path OK Rx path OK OK LED Colour Severity Green Orange Red No alarm information only Warning alarm Critical, major or minor alarm Aprisa SR+ Product Description Management | 51 Single Radio Software Upgrade During a radio software upgrade, the LEDs indicate the following conditions:
Software upgrade started - the OK LED flashes orange Software upgrade progress indicated by running RX to OK LEDs Software upgrade completed successfully - the OK LED solid orange Software upgrade failed - any LED flashing red during the upgrade Network Software Upgrade During a network software upgrade, the MODE LED flashes orange on the base station and all remote stations. Test Mode In Test Mode, the LED Display panel presents a real time visual display of the RSSI. This can be used to adjust the antenna for optimum signal strength. Aprisa SR+ Product Description 52 | Applications 5. Applications This section describes sample Aprisa SR+ radio applications. The following applications are described:
Basic point-to-multipoint application Advanced point-to-multipoint application with repeaters Multi-interface point-to-multipoint application Multi-hop Daisy chain repeaters in LBS mode application Pseudo Peer to Peer using base-repeater application Basic point-to-multipoint application Single base station with Ethernet SCADA data inputs to multiple geographically remote sites with Ethernet RTUs requiring control and data acquisition. The base station receives Ethernet frames from the SCADA server LAN and broadcasts all Ethernet frames to all remote stations Each remote site receives Ethernet frames from the RTU and unicasts over the air to the base station. The base station uses an omni directional antenna to provide wide coverage and the remote stations are fitted with directional Yagi antennas to provide higher gain. Aprisa SR+ Product Description Applications | 53 Advanced point-to-multipoint application with repeater Single base station with Ethernet SCADA data inputs to multiple geographically remote sites with Ethernet RTUs requiring control and data acquisition. A repeater is deployed to service remote sites beyond the reach of the base station. The base station receives Ethernet frames from the SCADA server LAN and broadcasts all Ethernet frames to the repeater and its remote stations. Three remote sites have direct radio communication with the base station but the other two remote sites operate via the repeater site. Each remote site receives Ethernet frames from the RTU and unicasts over the air to the repeater / base station. The base station and the repeater station use an omni directional antenna to provide wide coverage and the remote stations are fitted with directional Yagi antennas to provide higher gain. Aprisa SR+ Product Description 54 | Applications Multi-interface point-to-multipoint application Single base station with Ethernet and RS-232 SCADA data inputs to multiple geographically remote sites with Ethernet and RS-232 RTUs requiring control and data acquisition. The base station receives Ethernet / RS-232 frames from the SCADA servers and broadcasts all frames to all remote stations Each remote site receives Ethernet / RS-232 frames from the RTU and unicasts over the air to the base station. The base station uses an omni directional antenna to provide wide coverage and the remote stations are fitted with directional Yagi antennas to provide higher gain. Aprisa SR+ Product Description Applications | 55 Multi-hop Daisy Chain Repeaters in LBS Mode Application This application is used for daisy chain repeaters when remote stations are very far from base station coverage. Daisy chain repeaters can only be used in LBS channel access mode (and future release in AR mode). In the figure example below, the Base Station can communicate with any of the far remotes via the daisy chain repeaters. The SCADA master will communicate with RTU 2 using a source and destination IP address and the underlining SCADA protocol. On the downstream, the SCADA master would like to communicate with RTU-2 and sends a packet destined to RTU-2 (using RTU 2 destination address). This packet received by the Base Station will then broadcast OTA to Repeater 1. Repeater 1 will store-and-forward the received packet and re-transmit the packet to Repeater 2 and back to the Base Station, which will drop the duplicate packet as this packet is its own forward. Repeater 2 will store-and-forward the packet to the local Ethernet port to RTU 3 (which will drop the packet due to destination address mismatch) and it will also re-transmit the packet OTA to Repeater 3, Remote 1 and back to Repeater 1, which will drop the duplicate packet as this packet is its own forward. Remote-1 will forward the packet to its local Ethernet port and RTU-1 will drop the packet due to destination address mismatch. Repeater 3 will store-and-forward and re-transmit the packet OTA to Remote-2 and back to Repeater 2, which will drop the packet as duplicate packet as this packet is its own forward. Remote 2 will then forward the packet to its local Ethernet port and RTU 2 as the destined address which will process the packet accordingly. On the upstream, RTU 2 will send a packet to the SCADA master, and the radio network from Remote 2 sending a unicast packet destined to Base Station which will act with the same process mechanism as described above for downstream path. Aprisa SR+ Product Description 56 | Applications Pseudo Peer to Peer using Base-Repeater Application This application is used for remote peer to peer communication via a base-repeater or repeater configuration. In peer to peer, the source RTU will create a message with destination address of the destined RTU in the SCADA layer protocol (and/or IP layer, if applicable). Note, this address is only known by the RTUs as the SR+ radio is transparent to SCADA protocol messages. Although all messages sent from remotes are always destined to the base station, packets can be sent from one remote to the other using the packet filtering peer to peer feature (see the Aprisa SR+ User Manual Radio > Channel Setup) and base-repeater or repeater configuration. In the figure example below, RTU 1 would like to communicate with RTU 3, and thus, Remote 1 and Remote 3 will be configured with packet filtering set to disabled and the Base station configured as a Base-repeater. RTU 1 will create a message destined to RTU 3 and forward it to Remote 1, which in turn will forward it as a unicast message OTA to the Repeater Station, destined to the Base Station (all packets from a remote are destined to the base station). The Repeater Station will store-and-forward the message received from Remote 1 and re-transmit the message to Base Station, but it will also be received by Remote 2. Since, Remote 2 is not the destination and packet filtering is set to automatic (enabled), the packet will be dropped by Remote 2. Note, Remote 3 and Remote 4 cant hear the Repeater Station. The Base-Repeater will forward the packet to the local ports (Ethernet and/or serial), and will also re-
transmit the packet OTA to Remote 3 and Remote 4 and back to the Repeater (this is specific and default to Base-Repeater functionality, as packet filtering is not used in Base-Repeater operation and it can be left in default (automatic)). The Repeater will drop the duplicate packet as this packet is its own forward. Remote 3 will receive the packet and forward it to it local ports (Ethernet or Serial) and to its local RTU 3, as packet filtering is disabled which will then process the packet accordingly. Remote 4 will also receive the packet, but it will drop the packet as packet filtering is enabled. If Remote 4 had packet filtering disabled, the packet would be forwarded to the local port and dropped by RTU 4, due to SCADA protocol destination address mismatch (and/or IP destination address mismatch, if applicable). Aprisa SR+ Product Description Product Architecture | 57 6. Product Architecture Product Operation There are three components to the wireless interface: the Physical Layer (PHY), the Data Link Layer (DLL) and the Network Layer. These three layers are required to transport data across the wireless channel in the Point-to-multipoint (PMP) configuration. The Aprisa SR+ DLL is largely based on the 802.15.4 MAC layer using a proprietary implementation. Physical Layer The Aprisa SR+ PHY uses a one or two frequency half duplex transmission mode which eliminates the need for a duplexer. However, a Dual Antenna port option is available for separate transmit and receive antenna connection to support external duplexers or filters (half duplex operation). Remote nodes are predominantly in receive mode with only sporadic bursts of transmit data. This reduces power consumption. The Aprisa SR+ is a packet based radio. Data is sent over the wireless channel in discrete packets /
frames, separated in time. The PHY demodulates data within these packets with coherent detection. The Aprisa SR+ PHY provides carrier, symbol and frame synchronization predominantly through the use of preambles. This preamble prefixes all packets sent over the wireless channel which enables fast Synchronization. Data Link Layer / MAC layer The Aprisa SR+ PHY enables multiple users to be able to share a single wireless channel; however a DLL is required to manage data transport. The two key components to the DLL are channel access and hop by hop transmission. Channel Access The Aprisa SR+ radio has two modes of channel access, Access Request and Listen Before Send. Option Function Access Request Channel access scheme where the base stations controls the communication on the channel. Remotes ask for access to the channel, and the base station grants access if the channel is not occupied. Listen Before Send Channel access scheme where network elements listen to ensure the channel is clear, before trying to access the channel. Aprisa SR+ Product Description 58 | Product Architecture Access Request This scheme is particularly suited to digital SCADA systems where all data flows through the base station. In this case it is important that the base station has contention-free access as it is involved in every transaction. The channel access scheme assigns the base station as the channel access arbitrator and therefore inherently it has contention-free access to the channel. This means that there is no possibility of contention on data originating from the base station. As all data flows to or from the base station, this significantly improves the robustness of the system. All data messages are controlled via the AG (access grant) control message and therefore there is no possibility of contention on the actual end user data. If a remote station accesses the channel, the only contention risk is on the AR (access request) control message. These control messages are designed to be as short as possible and therefore the risk of collision of these control messages is significantly reduced. Should collisions occur these are resolved using a random back off and retry mechanism. As the base station controls all data transactions multiple applications can be effectively handled, including a mixture of polling and report by exception. Listen Before Send The Listen Before Send channel access scheme is realized using Carrier Sense Multiple Access (CSMA). In this mode, a pending transmission requires the channel to be clear. This is determined by monitoring the channel for other signals for a set time prior to transmission. This results in reduced collisions and improved channel capacity. There are still possibilities for collisions with this technique e.g. if two radios simultaneously determine the channel is clear and transmit at the same time. In this case an acknowledged transaction may be used. The transmitter requests an ACK to ensure that the transmission has been successful. If the transmitter does not receive an ACK, then random backoffs are used to reschedule the next transmission. Hop by Hop Transmission Hop by Hop Transmission is realized in the Aprisa SR+ by adding a MAC address header to the packet. For 802.15.4, there are 2 addresses, the source and destination addresses. Aprisa SR+ Product Description Product Architecture | 59 Adaptive Coding Modulation The Aprisa SR+ provides Adaptive Coding Modulation (ACM) which maximizes the use of the RF path to provide the highest radio capacity available. ACM automatically adjusts the modulation coding and FEC code rate in the remote to base direction of transmission over the defined modulation range based on the signal quality for each individual remote radio. When the RF path is healthy (no fading), modulation coding is increased and the FEC code rate is decreased to maximize the data capacity. If the RF path quality degrades, modulation coding is decreased and the FEC code rate is increased for maximum robustness to maintain path connectivity. Aprisa SR+ Product Description 60 | Product Architecture Network Layer Packet Routing Aprisa SR+ is a standard static IP router which routes and forwards IP packet based on standard IP address and routing table decisions. Aprisa SR+ router mode (see figure below), enables the routing of IP packets within the Aprisa SR+ wireless network and in and out to the external router / IP RTUs devices connected to the Aprisa SR+ wired Ethernet ports. Within the Aprisa SR+ Router mode, each incoming Ethernet packet on the Ethernet port is stripped from its Ethernet header to reveal the IP packet and to route the IP packet based on its routing table. If the destination IP address is one of the RTUs, the packet is then forwarded to the wireless ports and broadcasted as a PMP wireless packet to all the repeater / remotes stations. The appropriate remote then routes the IP packet and forwards it based on its routing table to the appropriate Ethernet port, encapsulating the appropriate next hop MAC header and forwarding it to the RTU. The RTU can then interpret and process the IP data and communication is established between the RTU and the initiating communication device. Aprisa SR+ Product Description Product Architecture | 61 Static IP Router The Aprisa SR+ works in the point-to-multipoint (PMP) network as a standard static IP router with the Ethernet and wireless / radio as interfaces and serial ports using terminal server as a virtual interface. The Aprisa SR+ static router is semi-automated operation, where the routing table is automatically created in the base station and populated with routes to all remotes and repeater stations in the network during the registration process and vice versa, where the routing table is automatically created in remote and repeater stations and populated with routes to base station during the registration process. Updates occur when remote is disconnected from network for any reason, with the routing table updated in a controlled fashion. Also, in decommission operation, the base station routing tables are completely flushed allowing an automatic rebuild. This avoids the user manually inserting / removing of multiple static routes to build /
change the routes in the network which might be tedious and introduce significant human error. The Aprisa SR+ works as a static IP router without using any routing protocol and therefore does not have the overhead of a routing protocol for better utilization of the narrow bandwidth network. In addition to the semi-automated routes, the user can manually add / remove routes in the routing table for the radio interface, Ethernet Interface and for routers which are connected to the radio network. The Aprisa SR+ base station is used as a gateway to other networks. Thus, a configurable IP address default gateway can be set using a static route in the routing table with a destination IP address of 0.0.0.0. It is used by the router when an IP address does not match any other routes in the routing table. The Aprisa SR+ sub-netting rules distinguish between the wireless interface and the remote Ethernet interface where RTUs are connected. The entire wireless network is set on a single IP subnet, while each Aprisa SR+ remotes Ethernet interface is set to a different subnet network. In this way, the user can easily distinguish between the remotes subnet IP addresses. Aprisa SR+ Product Description 62 | Product Architecture Static IP Router Human Error Free To ensure correct operation, the Aprisa SR+ router base station alerts when one (or more) of the devices is not configured for router mode or a duplicated IP is detected when manually added. When the user changes the base station IP address / subnet, the base station sends an ARP unsolicited announcement message and the remotes / repeaters auto-update their routing table accordingly. This also allows the router that is connected to the base station to update its next hop IP address and its routing table. When the user changes the remote / repeater station IP address / subnet, a re-registration process in the base station then auto-updates its routing table accordingly. Terminal Server - Transition to Converged Ethernet / IP Network Customers that are transitioning their SCADA network to an Ethernet / IP SCADA network, can simultaneously operate their legacy serial RTUs, not as a separate serial network to the new Ethernet / IP network, but as part of the Ethernet / IP network, by using the terminal server feature. The Aprisa SR+ terminal server is an application running in the radio that encapsulates serial traffic into Ethernet / IP traffic. For SCADA networks, this enables the use of both serial and Ethernet / IP RTUs within an Ethernet / IP based SCADA network. Aprisa SR+ Product Description Product Architecture | 63 Bridge Mode with VLAN Aware Ethernet VLAN Bridge / Switch Overview The Aprisa SR+ in Bridge mode of operation is a standard Ethernet Bridge based on IEEE 802.1d or VLAN Bridge based on IEEE 802.1q/p which forward / switch Ethernet packet based on standard MAC addresses and VLANs using FDB (forwarding database) table decisions. VLAN is short for Virtual LAN and is a virtual separate network, within its own broadcast domain, but across the same physical network. VLANs offer several important benefits such as improved network performance, increased security and simplified network management. The Aprisa SR+ Bridge mode (see figure below), is the default mode of operation and it enables the switching / bridging of Ethernet VLAN tagged or untagged packets within the Aprisa SR+ wireless network and in and out to the external Industrial LAN network and RTUs devices connected to the Aprisa SR+ wired Ethernet ports or serial ports through the terminal server function. Within the Aprisa SR+ Bridge mode, each incoming Ethernet packet is inspected for the destination MAC address (and VLAN) and looks up its FDB table for information on where to send the specific Ethernet frame. If the FDB table doesnt contain the specific MAC address, it will flood the Ethernet frame out to all ports in the broadcast domain and when using VLAN, the broadcast domain is narrowed to the specific VLAN used in the packet (i.e. broadcast will be done only to the ports which configured with that specific VLAN). The FDB table is used to store the MAC addresses that have been learnt and the ports associated with that MAC address. If the destination MAC address is one of the RTUs, the packet is then forwarded to the wireless ports and broadcast as a PMP wireless packet to all the repeater / remote stations. The appropriate remote then switches the Ethernet packet and forwards it based on its FDB table (based on the MAC or VLAN & MAC) to the appropriate Ethernet port to the RTU. The RTU can then interpret and process the Ethernet / IP data and communication is established between the RTU and the initiating communication device. Aprisa SR+ Product Description 64 | Product Architecture VLAN Bridge Mode Description General Aprisa SR+ VLAN Bridge Aprisa SR+ works in the point-to-multipoint (PMP) network as a standard VLAN bridge with the Ethernet and wireless / radio as interfaces and serial ports using terminal server as a virtual interface. The Aprisa SR+ is a standard IEEE 802.1q VLAN bridge, where the FDB table is created by the bridge learning / aging process. New MACs are learnt and the FDB table updated. Unused MACs are aged out and flushed automatically after aging period. VLANs are statically configured by the user on the ports where a Virtual LAN is required across the radio network. An example of VLAN isolation of traffic type is shown in the figure below, where RTUs #1, 4 and 6 together with SCADA meter master form a Virtual LAN which is isolated from the other devices, even though they are on the same physical network. VLAN management can be used to manage with external NMS all the Aprisa SR+ devices on the radio network, and is automatically created with a VLAN ID = 1 default value. The VLAN ID can be changed by the user later on. Each device in the Aprisa SR+ bridge is identified by its own IP address, as shown in the figure. Aprisa SR+ Product Description Product Architecture | 65 VLANs Single, Double and Trunk VLAN ports The Aprisa SR+ supports single VLAN (CVLAN), double VLAN (SVLAN) and trunk VLAN. A single VLAN can be used to segregate traffic type. A double VLAN can be used to distinguish between Aprisa SR+ sub-networks (base-repeater-remote), where the outer SVLAN is used to identify the sub-network and the CVLAN is used to identify the traffic type. In this case, a double tagged VLAN will be forwarded across the Industrial LAN network and switched based on the SVLAN to the appropriate Aprisa SR+ sub-network. When packet enters the Aprisa SR+
network, the SVLAN will be stripped off (removed) and the forwarding will be done based on the CVLAN, so only a single VLAN will pass through over the radio network and double VLAN will be valid on the borders of the radio network. Trunk VLAN is also supported by the Aprisa SR+ where the user can configure multiple VLANs on a specific Ethernet port, creating a trunk VLAN port. For example, in the above figure, a single trunk VLAN port is created between the switch and the Aprisa SR+ base station, carrying VLAN ID #1, 20, 30 and 40. VLAN Manipulation Add / Remove VLAN Tags In order to support double VLAN and different device types connected to the Aprisa SR+ e.g. switches, RTUs, etc, which can be VLAN tagged or untagged / plain Ethernet devices, add / remove VLAN manipulation is required. In an Aprisa SR+ VLAN tagged network, a remote Aprisa SR+ connected to a plain RTU without VLAN support, will remove (strip-off) the VLAN tag from the packet before sending it to the RTU. On the other direction, when the RTU is sending an untagged packet, the Aprisa SR+ will add (append) an appropriate user pre-configure VLAN tag before sending it over the air to the base station. This is shown in the above figure on untagged RTU #5 and 7. QoS using VLAN VLANs carry 3 priority bits (PCP field) in the VLAN tag allowing prioritization of VLAN tagged traffic types with 8 levels of priority (where 7 is the highest priority and 0 is the lowest priority). The Aprisa SR+
supports QoS (Quality of Service) where the priority bits in the VLAN tagged frame are evaluated and mapped to four priority levels and four queues supported by the Aprisa SR+ radio. Packets in the queues are then scheduled out in a strict priority fashion for transmission over-the-air as per the priority level from high to low. Aprisa SR+ Product Description 66 | Product Architecture Avoiding Narrow Band Radio Traffic Overloading The Aprisa SR+ supports mechanisms to prevent narrowband radio network overload:
1. L3/L4 Filtering The L3 filtering can be used to block undesired traffic from being transferred on the narrow band channel, occupying the channel and risking the SCADA critical traffic. L3/4 filtering has the ability to block a known IP address and applications using TCP/IP or UDP/IP protocols with multiple filtering rules. The L3 (/L4) filter can block/forward (discard/process) a specific IP address and a range of IP addresses. Each IP addressing filtering rule set can also be set to filter a L4 TCP or UDP port/s which in most cases relates to specific applications as per IANA official and unofficial well-known ports. For example, filter and block E-
mail SMTP or TFTP protocol as undesired traffic over the SCADA network. The user can block a specific or range of IP port addresses, examples SMTP (Simple Mail Transfer Protocol) TCP port 25 or TFTP (Simple Trivial File Transfer Protocol) UDP port 69. 2. L2 Address Filtering L2 Filtering (Bridge Mode) provides the ability to filter radio link traffic based on specified Layer 2 MAC addresses. Destination MAC (DA) addresses and a Source MAC (SA) addresses and protocol type (ARP, VLAN, IPv4, IPv6 or Any type) that meet the filtering criteria will be transmitted over the radio link. Traffic that does not meet the filtering criteria will not be transmitted over the radio link. 3. L2 Port VLANs Ingress Filtering and QoS Double VLAN (Bridge Mode) Double VLAN is used to distinguish/segregate between different radio sub-networks (Base-repeaters-
remotes). Traffic with double VLANs which are not destined to a specific sub-network will be discarded on the ingress of the radio sub-network, avoiding the overload of the radio sub-network. Single VLAN (Bridge Mode) Single VLAN is used to distinguish/segregate between different traffic types assigned by the user in its industrial corporate LAN. In order to avoid the overload of the radio network, traffic with single VLANs which are not destined to a specific radio network will be discarded on the Ethernet ingress port of the radio network. All single VLANs which set and are eligible will be transmitted over the radio link. QoS using 802.1p priority bits (Bridge Mode) The priority bits can be used in the VLAN tagged frames to prioritized critical mission SCADA traffic and assure SCADA operation related to any other unimportant traffic. In this case, traffic base on VLAN priority
(priority 0 to 7) entered to one of the four priority queues of the Aprisa SR/SR+ (Very High, High, Medium and Low). Traffic leaves the queues (to the radio network) from highest priority to lowest in a strict priority fashion. 4. Ethernet port QoS The Aprisa SR+ supports Ethernet Per Port Prioritization. Each Ethernet port can be assigned a priority and traffic shall be prioritized accordingly. This is quite useful in networks where customers do not use VLANs or cannot use 802.1p prioritization. Aprisa SR+ Product Description Product Architecture | 67 Ethernet Data and Management Priority and Background Bulk Data Transfer Rate 5. Alternatively to VLAN priority, users can control the Ethernet traffic priority (vs serial), management priority and rate in order to control the traffic load of the radio network, where important and high priority data (SCADA) will pass-through first assuring SCADA network operation. The user can set the use of the Ethernet Data Priority, which controls the priority of the Ethernet customer traffic relative to the serial customer traffic and can be set to one of the four queues. The Ethernet Management Priority controls the priority of the Ethernet management traffic relative to Ethernet customer traffic and can be set to one of the four queues. The Background Bulk Data Transfer Rate sets the data transfer rate (high, medium, low) for large amounts of management data. 6. Ethernet Packet Time to Live Another aspect of avoiding overload radio network is the Ethernet packet TTL, which is used to prevent old, redundant packets being transmitted through the radio network. This sets the time an Ethernet packet is allowed to live in the system before being dropped if it cannot be transmitted over the air. 7. Robust Header Compression (ROHC) and Payload Compression Aprisa SR+ supports ROHC (Robust Header Compression RFC3095). ROHC is a standard way to compress IP, UDP and TCP headers and this significantly increases IP traffic throughput especially in narrow band network. Aprisa SR+ supports payload compression. A LempelZiv (LZ) algorithm is used to efficiently compress up to 50% traffic with high percentage of repetitive strings. Both serial and Ethernet / IP payload traffic are compressed. Aprisa SR+ Product Description 68 | Product Architecture Product Architecture The following are the key components of the Aprisa SR+ design:
Dual high performance fractional-N synthesizers to allow for full duplex operation Wideband design electronically tunes over entire band Proven low noise and spurious technology with over 50dB of SNR easily achieved Power amplifier linearity Unique temperature compensated pre-distortion system improves the efficiency and linearity of the entire transmitter chain for non-constant envelope modulation systems Simple IQ modulation line up reduces part count and improves MTBF No mixing stages so no spurious responses present at the transmitter output Digital control loops used for controlling power amplifier current and transmit output power, allows for faster ramping and settling times with less error Tx turn-on time limited primarily by PA ramping Robust, closed-loop power control fast, accurate power ramp up and down Highly rugged N-Channel RF Power LDMOS transistors for the power amplifier High efficiency (>50% PAE at 10W) Very low thermal resistance (1.0C/W) Direct IQ down-conversion Excellent Intermodulation distortion characteristics as channel filter can be placed directly after the mixer without impacting noise figure Digital channel filtering allows for multiple bandwidths with the same hardware Low parts count and no crystal filters help to keep receiver performance extremely stable over temperature Integrated heat sink Limits number of mechanical interfaces Fin design optimized for natural convection Monitoring and software control Temperature control loop shuts down the transmitter when the temperature exceeds continuous operation at 70C Monitoring of RSSI and PA current to ensure the RF hardware is functioning to specification Aprisa SR+ Product Description Aprisa SR+ Radio Block Diagram Product Architecture | 69 Aprisa SR+ Protected Station Block Diagram Aprisa SR+ Product Description 70 | Contact Us 7. Contact Us For further information or assistance, please contact Customer Support or your local 4RF representative. Our area representative contact details are available from our website:
4RF Limited 26 Glover Street, Ngauranga PO Box 13-506 Wellington 6032 New Zealand Email address Website Phone number Fax number Attention support@4rf.com www.4rf.com
+64 4 499 6000
+64 4 473 4447 Customer Services Aprisa SR+ Product Description
| 1 2 3 4 | User Manual | Users Manual | 4.10 MiB |
EXHIBIT 10 USERS MANUAL Test Report S/N: 45461430 R3.0 Test Report Issue Date: 20 March 2018 See attached 2016 Celltech Labs Inc. This document is not to be reproduced in whole or in part without the expressed written permission of Celltech Labs Inc. Page 99 of 118 September 2016 Version 1.6.0
| 1 Copyright Copyright 2016 4RF Limited. All rights reserved. This document is protected by copyright belonging to 4RF Limited and may not be reproduced or republished in whole or part in any form without the prior written permission of 4RF Limited. Trademarks Aprisa and the 4RF logo are trademarks of 4RF Limited. Windows is a registered trademark of Microsoft Corporation in the United States and other countries. Java and all Java-related trademarks are trademarks or registered trademarks of Sun Microsystems, Inc. in the United States and other countries. All other marks are the property of their respective owners. Disclaimer Although every precaution has been taken preparing this information, 4RF Limited assumes no liability for errors and omissions, or any damages resulting from use of this information. This document or the equipment may change, without notice, in the interests of improving the product. RoHS and WEEE compliance The Aprisa SR+ is fully compliant with the European Commissions RoHS (Restriction of Certain Hazardous Substances in Electrical and Electronic Equipment) and WEEE (Waste Electrical and Electronic Equipment) environmental directives. Restriction of hazardous substances (RoHS) The RoHS Directive prohibits the sale in the European Union of electronic equipment containing these hazardous substances: lead, cadmium, mercury, hexavalent chromium, polybrominated biphenyls (PBBs), and polybrominated diphenyl ethers (PBDEs). 4RF has worked with its component suppliers to ensure compliance with the RoHS Directive which came into effect on the 1st July 2006. End-of-life recycling programme (WEEE) The WEEE Directive concerns the recovery, reuse, and recycling of electronic and electrical equipment. Under the Directive, used equipment must be marked, collected separately, and disposed of properly. 4RF has instigated a programme to manage the reuse, recycling, and recovery of waste in an environmentally safe manner using processes that comply with the WEEE Directive (EU Waste Electrical and Electronic Equipment 2002/96/EC). 4RF invites questions from customers and partners on its environmental programmes and compliance with the European Commissions Directives (sales@4RF.com). Aprisa SR+ Product Description 1.6.0 2 |
Compliance General The Aprisa SR+ radio predominantly operates within frequency bands that require a site license be issued by the radio regulatory authority with jurisdiction over the territory in which the equipment is being operated. It is the responsibility of the user, before operating the equipment, to ensure that where required the appropriate license has been granted and all conditions attendant to that license have been met. Changes or modifications not approved by the party responsible for compliance could void the users authority to operate the equipment. Equipment authorizations sought by 4RF are based on the Aprisa SR+ radio equipment being installed at a fixed restricted access location and operated in point-to-multipoint or point-to-point mode within the environmental profile defined by EN 300 019, Class 3.4. Operation outside these criteria may invalidate the authorizations and / or license conditions. The term Radio with reference to the Aprisa SR+ User Manual, is a generic term for one end station of a point-to-multipoint Aprisa SR+ network and does not confer any rights to connect to any public network or to operate the equipment within any territory. Compliance European Telecommunications Standards Institute The Aprisa SR+ radio is designed to comply with the European Telecommunications Standards Institute
(ETSI) specifications as follows:
12.5 kHz and 25 kHz Channel 50 kHz Channel Radio performance EN 300 113-2 EN 302 561 (pending) EMC Environmental Safety EN 301 489-1 and 5 EN 300 019, Class 3.4 Ingress Protection IP51 EN 60950-1:2006 Class 1 division 2 for hazardous locations Frequency band Channel size Power input 135-175 MHz 215-240 MHz 320-400 MHz 400-470 MHz 12.5 kHz, 25 kHz 12.5 kHz, 20 kHz, 25 kHz, 50 kHz 12.5 kHz, 20 kHz, 25 kHz, 50 kHz 12.5 kHz, 20 kHz, 25 kHz, 50 kHz 13.8 VDC 13.8 VDC 13.8 VDC 13.8 VDC 450-520 MHz 12.5 kHz, 25 kHz, 50 kHz 13.8 VDC Notified body Aprisa SR+ Product Description 1.6.0
| 3 Compliance Federal Communications Commission The Aprisa SR+ radio is designed to comply with the Federal Communications Commission (FCC) specifications as follows:
Radio EMC Environmental Safety 47CFR part 24, part 27, part 90 and part 101 Private Land Mobile Radio Services 47CFR part 15 Radio Frequency Devices, EN 301 489-1 and 5 EN 300 019, Class 3.4 Ingress Protection IP51 EN 60950-1:2006 Class 1 division 2 for hazardous locations Frequency Band *
Channel size Power input Authorization FCC ID 135-175 MHz 15 kHz, 30 kHz 13.8 VDC Part 90 UIPSQ135M150 215-240 MHz 400-470 MHz 12.5 kHz, 15 kHz, 25 kHz, 50 kHz 12.5 kHz, 25 kHz, 50 kHz 13.8 VDC Part 90 UIPSQ215M141 13.8 VDC Part 90 UIPSQ400M1311 450-520 MHz 12.5 kHz, 25 kHz 13.8 VDC Part 90 757-758 MHz and 787-788 MHz 25 kHz, 50 kHz, 75 kHz 13.8 VDC Part 27 896-902 MHz 12.5 kHz, 25 kHz, 50 kHz 13.8 VDC 928-960 MHz 12.5 kHz, 25 kHz, 50 kHz 13.8 VDC Part 24 /
Part 90 /
Part 101 Part 24 /
Part 90 /
Part 101 Pending Pending UIPSQ896M141 UIPSQ928M141 NOTE: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense.
* The Frequency Band is not an indication of the exact frequencies approved by FCC. Aprisa SR+ Product Description 1.6.0 4 |
Compliance Industry Canada The Aprisa SR+ radio is designed to comply with Industry Canada (IC) specifications as follows:
Radio EMC Environmental Safety RSS-119 / RSS-134 This Class A digital apparatus complies with Canadian standard ICES-003. Cet appareil numrique de la classe A est conforme la norme NMB-003 du Canada. EN 300 019, Class 3.4 Ingress Protection IP51 EN 60950-1:2006 Class 1 division 2 for hazardous locations Frequency Band *
Channel size Power input Authorization IC 135-175 MHz 15 kHz, 30 kHz 13.8 VDC RSS-119 6772A-SQ135M150 215-240 MHz 400-470 MHz 896-902 MHz 928-960 MHz 12.5 kHz, 15 kHz, 25 kHz, 50 kHz 12.5 kHz, 25 kHz, 50 kHz 12.5 kHz, 25 kHz, 50 kHz 12.5 kHz, 25 kHz, 50 kHz 13.8 VDC RSS-119 Pending 13.8 VDC RSS-119 6772A-SQ400M1311 13.8 VDC 13.8 VDC RSS-119 and RSS-134 RSS-119 and RSS-134 Pending Pending
* The Frequency Band is not an indication of the exact frequencies approved by IC. Compliance Brazil Este produto ser comercializado no Brasil com as configuraes abaixo:
Faixa de frequncia: 406,10 a 413,05, 423,05 a 430 MHz, 451,00625 a 452,0065 MHz, 459 a 460 MHz, 461,0025 a 462,00625 MHz e 469 a 470 MHz. Modulaes: QPSK, 16QAM e 64QAM BW: 12,5 e 25 KHz. Aprisa SR+ Product Description 1.6.0
| 5 Compliance Hazardous Locations Notice This product is suitable for use in Class 1, Division 2, Groups A - D hazardous locations or non-hazardous locations. The following text is printed on the Aprisa SR+ fascia:
WARNING: EXPLOSION HAZARD - Do not connect or disconnect while circuits are live unless area is known to be non-hazardous. The following text is printed on the Aprisa SR+ where the end user is in Canada:
AVERTISSEMENT: RISQUE D'EXPLOSION - Ne pas brancher ou dbrancher tant que le circuit est sous tension, moins qu'il ne s'agisse d'un emplacement non dangereux. The USB service ports are not to be used unless the area is known to be non-hazardous. Compliance IEEE 1613 class 2 Users requiring compliance to IEEE 1613 class 2 should use screened cables and connectors to connect to the serial ports. Aprisa SR+ Product Description 1.6.0 6 |
RF Exposure Warning WARNING:
The installer and / or user of Aprisa SR+ radios shall ensure that a separation distance as given in the following table is maintained between the main axis of the terminals antenna and the body of the user or nearby persons. Minimum separation distances given are based on the maximum values of the following methodologies:
1. Maximum Permissible Exposure non-occupational limit (B or general public) of 47 CFR 1.1310 and the methodology of FCCs OST/OET Bulletin number 65. 2. Reference levels as given in Annex III, European Directive on the limitation of exposure of the general public to electromagnetic fields (0 Hz to 300 GHz)
(1999/519/EC). These distances will ensure indirect compliance with the requirements of EN 50385:2002. Frequency (MHz) Maximum Power Maximum Antenna Minimum Separation
(dBm) Note 1 Gain (dBi) Distance
(m) 135 175 215 240 320 400 450 470 520 896 902 928 960
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37
+ 37 15 15 15 15 15 15 15 15 15 28 28 28 28 3.5 3.5 3.5 3.5 3.5 3.0 3.0 3.0 3.0 10.0 10.0 9.5 9.5 Note 1: The Peak Envelope Power (PEP) at maximum set power level is +41 dBm. Aprisa SR+ Product Description 1.6.0 Contents Contents | 7 1. Introduction ............................................................................ 11 The 4RF Aprisa SR+ Radio ...................................................................... 11 Product Overview ............................................................................... 12 Network Coverage and Capacity ....................................................... 12 Automatic Registration .................................................................. 12 Remote Messaging ........................................................................ 12 Store and Forward Repeater ............................................................ 13 Repeater Packet Forwarding..................................................... 13 Repeater Messaging ............................................................... 16 Peer To Peer Communication Between Remote Radios ...................... 17 Product Features ......................................................................... 18 Functions .................................................................................. 18 Security .................................................................................... 19 Performance .............................................................................. 20 Usability ................................................................................... 20 System Gain vs FEC Coding ............................................................. 21 Architecture ...................................................................................... 22 Interfaces ......................................................................................... 23 Antenna Interface ........................................................................ 23 Ethernet Interface ....................................................................... 23 RS-232 / RS-485 Interface ............................................................... 23 USB Interfaces ............................................................................ 23 Protect Interface ......................................................................... 23 Alarms Interface .......................................................................... 23 Mounting .......................................................................................... 24 DIN Rail Mounting ........................................................................ 24 Rack Shelf Mounting ..................................................................... 26 Wall Mounting ............................................................................. 27 2. Product Options ....................................................................... 28 Interface Ports ................................................................................... 28 Full Duplex Base Station ....................................................................... 28 Protected Station ............................................................................... 29 Protected Ports ........................................................................... 29 Operation .................................................................................. 30 Switch Over ........................................................................ 30 Configuration Management ...................................................... 30 Power ............................................................................... 31 Data Driven Protected Station................................................................. 32 Operation .................................................................................. 32 Over The Air Compatibility ...................................................... 32 Switch Over ........................................................................ 33 Configuration Management ...................................................... 33 Power ............................................................................... 33 Duplexer Kits ..................................................................................... 34 Radio Duplexer Kits ...................................................................... 34 Protected Station Duplexer Kits ........................................................ 36 USB RS-232 / RS-485 Serial Port ............................................................... 39 USB RS-232 / RS-485 operation ......................................................... 39 Aprisa SR+ Product Description 1.6.0 8 | Contents 3. Specifications .......................................................................... 40 RF Specifications ................................................................................ 40 Frequency Bands ......................................................................... 40 Channel Sizes ............................................................................. 41 Receiver ................................................................................... 54 Transmitter ............................................................................... 57 Modem ..................................................................................... 58 Data Payload Security ................................................................... 58 Interface Specifications ........................................................................ 59 Ethernet Interface ....................................................................... 59 RS-232 Asynchronous Interface ......................................................... 60 Hardware Alarms Interface ............................................................. 61 Protection Switch Specifications ....................................................... 61 Power Specifications ............................................................................ 62 Power Supply .............................................................................. 62 Power Consumption ...................................................................... 63 Power Dissipation ........................................................................ 63 General Specifications .......................................................................... 64 Environmental ............................................................................ 64 Mechanical ................................................................................ 64 Compliance ................................................................................ 65 4. Management ........................................................................... 66 SuperVisor ........................................................................................ 66 Viewing the Aprisa SR+ Terminal Settings ............................................ 67 Configuring the Aprisa SR+ Terminal Details ......................................... 68 Configuring the Aprisa SR+ RF Network Details ...................................... 68 Configuring the Aprisa SR+ Radio Settings ............................................ 69 Command Line Interface ....................................................................... 70 SNMP .............................................................................................. 70 LED Display Panel ............................................................................... 71 Normal Operation ........................................................................ 71 Single Radio Software Upgrade ......................................................... 72 Network Software Upgrade ............................................................. 72 Test Mode ................................................................................. 72 5. Applications ............................................................................ 73 Basic point-to-multipoint application ........................................................ 73 Advanced point-to-multipoint application with repeater ................................. 74 Multi-interface point-to-multipoint application ............................................ 75 Multi-hop Daisy Chain Repeaters in LBS Mode Application ................................ 76 Pseudo Peer to Peer using Base-Repeater Application .................................... 77 Aprisa SR+ Product Description 1.6.0 6. Contents | ix Product Architecture ................................................................. 78 Product Operation .............................................................................. 78 Physical Layer ............................................................................. 78 Data Link Layer / MAC layer ............................................................ 78 Channel Access .................................................................... 78 Adaptive Coding Modulation ..................................................... 80 Network Layer ............................................................................ 81 Packet Routing ..................................................................... 81 Static IP Router .................................................................... 82 Bridge Mode with VLAN Aware .................................................. 85 VLAN Bridge Mode Description .................................................. 86 Avoiding Narrow Band Radio Traffic Overloading .................................... 88 Product Architecture ........................................................................... 90 Aprisa SR+ Radio Block Diagram ........................................................ 91 Aprisa SR+ Protected Station Block Diagram ......................................... 91 7. Contact Us .............................................................................. 92 Aprisa SR+ Product Description 1.6.0 Introduction | 11 1. Introduction The 4RF Aprisa SR+ Radio The 4RF Aprisa SR+ is a Point-To-Multipoint (PMP) and Point-To-Point (PTP) digital radio providing secure narrowband wireless data connectivity for SCADA, infrastructure and telemetry applications. The radios carry a combination of serial data and Ethernet data between the base station, repeater stations and remote stations. A single Aprisa SR+ is configurable as a:
Point-To-Multipoint base station, remote station, repeater station or a base-repeater station Point-To-Point local or remote radio Aprisa SR+ Product Description 1.6.0 12 | Introduction Product Overview Network Coverage and Capacity The Aprisa SR+ has a typical link range of up to 120 km, however, geographic features, such as hills, mountains, trees and foliage, or other path obstructions, such as buildings, will limit radio coverage. Additionally, geography may reduce network capacity at the edge of the network where errors may occur and require retransmission. However, the Aprisa SR+ uses 10W output power and Forward Error Correction
(FEC) which greatly improves the sensitivity and system gain performance of the radio resulting in less retries and minimal reduction in capacity. Ultimately, the overall performance of any specific network will be defined by a range of factors including the RF output power, the modulation used and its related receiver sensitivity, the geographic location, the number of remote stations in the base station coverage area and the traffic profile across the network. Effective network design will distribute the total number of remote stations across the available base stations to ensure optimal geographic coverage and network capacity. One base station can register and operate with up to 500 remote / repeater stations. The practical limit of remote / repeater stations that can operate with one base station is determined by a range of factors including the number of services, the packet sizes, the protocols used, the message types and network timeouts. Automatic Registration On start-up, the remote station transmits a registration message to the base station which responds with a registration response. This allows the base station to record the details of all the remote stations active in the network. If a remote station cannot register with the base station after multiple attempts within 10 minutes, it will automatically reboot. If remote is not able to register with base station in 5 attempts, then a Network Configuration Warning alarm event will be raised indicating that a remote is not registered with the base station. If a remote station has registered with the base station but then loses communication, it will automatically reboot within 2 minutes. Remote Messaging There are two message types in the Aprisa SR+ network, broadcast messages and unicast messages. Broadcast messages are transmitted by the base station to the remote stations and unicast messages are transmitted by the remote station to the base station. These messages are commonly referred to as uplink
(unicast remote to base) and downlink (broadcast base to remote). All remotes within the coverage area will receive broadcast messages and pass them on to either the Ethernet or serial interface. The RTU determines if the message is intended for it and will accept it or discard it. Aprisa SR+ Product Description 1.6.0 Store and Forward Repeater The Aprisa SR+ in Repeater mode is used to link remote stations to the base station when direct communication is not possible due to terrain, distance, fade margin or other obstructions in the network. The following example depicts a repeater on the hill top to allow communication between the base station and the remote stations on the other side of hilly terrain. Introduction | 13 Repeater Packet Forwarding The Aprisa SR+ works in packet Store and Forward (S&F) for simple and low cost repeater network. Repeater mode is available in both Access Request (AR) and Listen Before Send (LBS/CSMA) MAC operating modes. It allows a radio in Repeater mode to store a received packet and retransmit it. Single Repeater Single Hop The following example depicts an Aprisa SR+ single repeater single hop Store and Forward network. Aprisa SR+ Product Description 1.6.0 14 | Introduction Multiple Repeater Single Hop The following example depicts an Aprisa SR+ multiple repeater single hop store and forward network supporting both overlapping and non-overlapping coverage repeater networks. An overlapped RF coverage area creates radio interference and might affect network performance and reduce throughput, as show in figure (a), where Remote 1 is in overlapped RF coverage with Repeater 1 and Repeater 2. The Aprisa SR+ functionality allows repeaters in Bridge mode to forward Ethernet packets based on Repeater Network Segment ID. The base station translates the destination address (DA) to the Repeater Network Segment ID. This improves repeater performance by forwarding the packet if the Repeater Network Segment ID belongs to the repeater branch and discards the packet if it doesnt. Router mode supports repeater packet forwarding based on IP destination address. This improves repeater performance by forwarding the packet if the IP destination address belongs to the repeater branch and discards the packet if it doesnt Aprisa SR+ Product Description 1.6.0 Multiple Repeater Multiple Hop The following example depicts an Aprisa SR+ daisy chain multiple repeater multiple hop store and forward network i.e. multiple hops and multiple repeaters in non-overlapping RF coverage. The Aprisa SR+ daisy chain store and forward repeaters are currently supported in LBS MAC mode only. Introduction | 15 In any type of store and forward repeater network base, repeater and remote radios must have their Tx/Rx frequencies sets to match to their appropriate linking devices as shown in the figures. Note: Frequencies shown in the figures relates to the device on the left where {Tx, Rx} = {fx, fy}. In this example, the Base Station, Repeater 2 and remotes are deployed with Tx=f1 and Rx=f2. On the other hand Repeater 1 and Repeater 3 are deployed with Tx=f2 and Rx=f1, creating the required linking for daisy chain operation. Aprisa SR+ Product Description 1.6.0 16 | Introduction Repeater Messaging The Aprisa SR+ uses a routed protocol throughout the network whereby messages contain source and destination addresses. The remote and repeater stations will register with a base station. In networks with a repeater, the repeater must register with the base station before the remotes can register with the base station. Additionally, based on destination address, messages are designated as either a broadcast message,
(mostly originating from a base station) or a unicast message (mostly originating from a remote station). In a network with a repeater, or multiple repeaters, the base station broadcasts a message which contains a source address and a destination address. The repeater receives the message and recognizes it as a broadcast message, from the destination address and re-broadcasts the message across the network. In IP routing mode all remote stations in the coverage area will receive the message but only the radio with the destination address will act upon the message. Similarly, the remote station will send a unicast message which contains a unicast destination address (the base station). The repeater will receive this message; recognize the destination address and forward it to the appropriate destination address. In order to prevent repeater-repeater loops, a detection mechanism of duplicate message and use of unicast messaging in remote to base/repeater direction is used. For example, in the Multiple Repeater Single Hop figure above, the topology is of Base, Repeater 1, Repeater 2 and Remote 1 connected to Repeater 1 in overlapping coverage, where Remote 1 can also hear Repeater 2. When the Base station broadcasts a message, Remote1 will receive this message from both Repeater 1 and Repeater 2 but will drop one of them as duplicate message. It is possible that Repeater 1, for example, can also hear the broadcast sent out by Repeater 2. In this case, Repeater 1 will drop this broadcast as a duplicate message. These phenomena will not happen in the upstream direction as all messages are sent unicast. Remote 1 will send a packet to Base station, setting the destination address in packet to Base station and next hop address in packet to Repeater 1. Thus, only Repeater 1 will forward the packet to Base station and Repeater 2 will drop the packet as the next hop address is not Repeater 2. Aprisa SR+ Product Description 1.6.0 Introduction | 17 Peer To Peer Communication Between Remote Radios The Aprisa SR+ peer to peer communication between remote radios is used to enable communication between remote radios via the repeater or base-repeater. It is useful if the SCADA server or base station fails or when in some industries like the water industry, where a reservoir remote station might send a direct message to a valve remote station to close or open the valve without the intervention of the SCADA server. The Aprisa SR+ has a special operating mode for peer to peer communication between remote radios and requires the following settings:
1. If peer to peer communication between remote radios is required to operate via the base station, then the SuperVisor > Terminal > Operating Mode > Terminal operating mode must be set to Base-
Repeater. Base-Repeater operating mode doesnt change the Network Radius parameter as the base-repeater is considered to be like a regular base station. 2. The remote radios participating in peer to peer communication must set the SuperVisor > Radio >
Channel Setup > Packet Filtering to Disable to allow a repeated packet received from peer to peer remote radios by the repeater or base-repeater to forward the packet to the relevant interface and not to discard it. 3. IP Header Compression must be disabled on all radios (base, repeater, remotes) for this feature to operate correctly (see Aprisa SR+ User Manual for settings). 4. The Network Repeaters Proximity must be set to Base Repeater on all remote radios for this feature to operate correctly (see Aprisa SR+ User Manual for settings). 5. Note: In Router Mode setup a static route for any required peer to peer path. The following example depicts peer to peer communication between remote radios via a base-repeater and via a repeater station where remote-1 and remote-2 communicate with each other via the base-
repeater station and remote-3 and remote-4 communicate with each other via the repeater station. All the remote radios are configured with packet filtering disabled and all radios in the network are configured with IP header compression ratio disabled. Note: The Aprisa SR+ network is transparent to the protocol being transmitted; therefore the Packet Filtering parameter is based on the Aprisa SR+ addressing and network protocols, not the user (SCADA, etc.) traffic protocols. Aprisa SR+ Product Description 1.6.0 18 | Introduction Product Features Functions Point-to-Point (PTP) or Point-to-Multipoint (PMP) operation Licensed frequency bands:
VHF 135 VHF 220 UHF 320 UHF 400 UHF 450 UHF 700 UHF 896 UHF 928 135-175 MHz 215-240 MHz 320-400 MHz 400-470 MHz 450-520 MHz 757-758 MHz and 787-788 MHz 896-902 MHz 928-960 MHz Channel sizes software selectable:
12.5 kHz 20 kHz 25 kHz 50 kHz 75 kHz Adaptive Coding and Modulation (ACM): QPSK to 64 QAM Half duplex or full duplex RF Point-To-Multipoint operation Full duplex RF Point-To-Point operation Ethernet data interface and RS-232 / RS-485 asynchronous multiple port options Software selectable dual / single antenna port options (dual antenna port for external duplexers or filters) Data encryption and authentication using 128,192 and 256 bit AES and CCM security standards Terminal server operation for transporting RS-232 / RS-485 traffic over IP or Ethernet and converting IP packets to a local physical serial port Mirrored Bits and SLIP support for RS-232 IEEE 802.1Q VLAN support with single and double VLAN tagged and add/remove VLAN manipulation to adapt to the appropriate RTU / PLCs QoS supports using IEEE 802.1p VLAN priority bits to prioritize and handle the VLAN / traffic types QoS per port (Ethernet, serial, management) L2 / L3 / L4 filtering for security and avoiding narrow band radio network overload L3 Gateway Router mode with standard static IP route for simple routing network integration L3 Router mode with per Ethernet interface IP address and subnet L2 Bridge mode with VLAN aware for standard Industrial LAN integration Ethernet header and IP/TCP / UDP ROHC header compression to increase the narrow band radio capacity Ethernet and serial payload compression to increase the narrow band radio capacity Pseudo peer to peer communication between remote stations through base-repeater or repeater stations SuperVisor web management support for element and sub-network (base-repeater-remotes) management SNMPv1/2/3 & encryption MIB supports for 4RF SNMP manager or third party SNMP agent network management Aprisa SR+ Product Description 1.6.0 Introduction | 19 SNMP context addressing for compressed SNMP access to remote stations SNTP for accurate wide radio network time and date RADIUS security for remote user authorization, authentication and accounting Build-configuration / flexibility of serial and Ethernet interface ports (3+1, 2+2, 4+0) Radio and user interface redundancy (provided with Aprisa SR+ Protected Station) Protected Station fully hot swappable and monitored hot standby Power optimized with sleep modes Transparent to all common SCADA protocols; e.g. Modbus, IEC 60870-5-101/104, DNP3 or similar Complies with international standards, including ETSI, FCC, IC, ACMA, EMC, safety and environmental standards Security The Aprisa SR+ provides security features to implement the key recommendations for industrial control systems. The security provided builds upon the best in class from multiple standards bodies, including:
IEC/TR 62443 (TC65) Industrial Communications Networks Network and System Security IEC/TS 62351 (TC57) Power System Control and Associated Communications Data and Communication Security FIPS PUB 197, NIST SP 800-38C, IETF RFC3394, RFC3610 and IEEE P1711/P1689/P1685 FIPS 140-2: Security Requirements for Cryptographic Modules The security features implemented are:
Data encryption Counter Mode Encryption (CTR) using Advanced Encryption Standard (AES) 128, 192, 256 bit, based on FIPS PUB 197 AES encryption (using Rijndael version 3.0) Data authentication NIST SP 800-38C Cipher Block Chaining Message Authentication Code (CBC-MAC) based on RFC 3610 using Advanced Encryption Standard (AES) Data payload security CCM Counter with CBC-MAC integrity (NIST special publication 800-38C) Secured management interface protects configuration L2 / L3 / L4 Address filtering enables traffic source authorization Proprietary physical layer protocol and modified MAC layer protocol based on standardized IEEE 802.15.4 Licensed radio spectrum provides recourse against interference SNMPv3 with Encryption for NMS secure access Secure USB software upgrade Key Encryption Key (KEK) based on RFC 3394, for secure Over The Air Re-keying (OTAR) of encryption keys User privilege allows the accessibility control of the different radio network users and the user permissions Aprisa SR+ Product Description 1.6.0 20 | Introduction Performance Typical deployment of 30 remote stations from one base station with a practical limit of a few hundred remote stations Long distance operation High transmit power Low noise receiver Forward Error Correction Electronic tuning over the frequency band Thermal management for high power over a wide temperature range Usability Configuration / diagnostics via front panel Management Port USB interface, Ethernet interface Built-in webserver SuperVisor with full configuration, diagnostics and monitoring functionality, including remote station configuration / diagnostics over the radio link LED display for on-site diagnostics Dedicated alarm port Software upgrade and diagnostic reporting via the host port USB flash drive Over-the-air software distribution and upgrades Simple installation with integrated mounting holes for wall, DIN rail and rack shelf mounting Aprisa SR+ Product Description 1.6.0 Introduction | 21 System Gain vs FEC Coding This table shows the relationship between modulation, FEC coding, system gain, capacity and coverage. Maximum FEC coding results in the highest system gain, the best coverage but the least capacity Minimum FEC coding results in lower system gain, lower coverage but higher capacity No FEC coding results in the lowest system gain, the lowest coverage but the highest capacity This table defines the modulation order based on gross capacity:
Modulation FEC Coding QPSK (High Gain) Max Coded FEC QPSK (Low Gain) Min Coded FEC 16QAM (High Gain) Max Coded FEC QPSK No FEC 16QAM (Low Gain) Min Coded FEC 16QAM No FEC 64QAM (High Gain) Max Coded FEC Capacity Minimum 64QAM (Low Gain) Min Coded FEC Maximum This table defines the modulation order based on receiver sensitivity:
Modulation FEC Coding QPSK (High Gain) Max Coded FEC QPSK (Low Gain) Min Coded FEC 16QAM (High Gain) Max Coded FEC QPSK No FEC 16QAM (Low Gain) Min Coded FEC 64QAM (High Gain) Max Coded FEC 16QAM No FEC Coverage Maximum 64QAM (Low Gain) Min Coded FEC Minimum Aprisa SR+ Product Description 1.6.0 22 | Introduction Architecture The Aprisa SR+ Architecture is based around a layered TCP/IP protocol stack:
Physical Proprietary wireless RS-232 and Ethernet interfaces Link Proprietary wireless (channel access, ARQ, segmentation) VLAN aware Ethernet bridge Network Standard IP Proprietary automatic radio routing table population algorithm Transport TCP, UDP Application HTTPS web management access through base station with proprietary management application software including management of remote stations over the radio link SNMPv1/2/3 for network management application software Aprisa SR+ Product Description 1.6.0 Introduction | 23 Interfaces Antenna Interface 2 x TNC, 50 ohm, female connectors Single or dual antenna ports (with or without the use of external duplexer / filter) Ethernet Interface 2, 3 or 4 ports 10/100 base-T Ethernet layer 2 switch using RJ45 Used for Ethernet user traffic and radio sub-network management. RS-232 / RS-485 Interface 2, 1 or 0 RS-232 asynchronous ports using RJ45 connector Optional 1x RS-232 or RS-485 asynchronous port using USB host port with USB to RS-232 or USB to RS-485 converters USB Interfaces 1 x Management port using USB micro type B connector Used for product configuration with the Command Line Interface (CLI). 1 x Host port using USB standard type A connector Used for software upgrade, diagnostic reporting and configuration save / restore. Protect Interface 1x Protect interface port Used for the Protected Station operation. Alarms Interface 1x Alarm port using RJ45 connector Used to provide 2 x hardware alarm inputs and 2 x hardware alarm outputs Aprisa SR+ Product Description 1.6.0 24 | Introduction Mounting The Aprisa SR+ has four threaded holes (M4) in the enclosure base and two holes (5.2 mm) through the enclosure for mounting. Mounting options include:
DIN rail mounting with the Aprisa SR+ DIN Rail Mounting Bracket Rack shelf mounting Wall mounting Outdoor enclosure mounting DIN Rail Mounting The Aprisa SR+ has an optional accessory to enable the radio to mount on a standard DIN rail:
Part Number Part Description APSB-MBRK-DIN 4RF SR+ Acc, Mounting, Bracket, DIN Rail Aprisa SR+ Product Description 1.6.0 The Aprisa SR+ DIN rail mounting bracket can be mounted in four positions on a horizontal DIN rail:
Introduction | 25 Vertical Mount (vertical enclosure perpendicular to the mount) Horizontal Mount (horizontal enclosure perpendicular to the mount) Flat Vertical Mount (vertical enclosure parallel to the mount) Flat Horizontal Mount (horizontal enclosure parallel to the mount) Aprisa SR+ Product Description 1.6.0 26 | Introduction Rack Shelf Mounting The Aprisa SR+ can be mounted on a rack mount shelf using the four M4 threaded holes in the Aprisa SR+
enclosure base. The following picture shows two Aprisa SR+ radios mounted on 1 RU rack mount shelf. Part Number Part Description APSB-MR19-X1U 4RF SR+ Acc, Mounting, 19" Rack Mount Shelf, 1U WARNING:
If the Aprisa SR+ is operated in an environment where the ambient temperature exceeds 50C, the Aprisa SR+ convection air flow over the heat sinks must be considered. Aprisa SR+ Product Description 1.6.0 Wall Mounting The Aprisa SR+ can be mounted on a wall using the two holes through the enclosure (5.2 mm diameter). Typically, M5 screws longer than 35 mm would be used. Introduction | 27 Aprisa SR+ Product Description 1.6.0 28 | Product Options 2. Product Options Interface Ports The standard Aprisa SR+ provides multiple interface port options for combinations of Ethernet and RS-232 serial. The product shown below is the two Ethernet ports plus two RS-232 serial ports. Interface Port Option Part Number 4 Ethernet ports and no RS-232 serial ports APSQ-N400-SSC-HD-40-ENAA 3 Ethernet ports and 1 RS-232 serial port APSQ-N400-SSC-HD-31-ENAA 2 Ethernet ports and 2 RS-232 serial ports APSQ-N400-SSC-HD-22-ENAA Full Duplex Base Station The Aprisa SR+ supports Full Duplex base / master station hardware. This option works with half duplex repeater / remote radios. The base / master station can transmit while simultaneously receiving from the repeater /remote radios. Example of a 400 MHz full duplex Aprisa SR+. Part Number Part Description APSQ-N400-SSC-FD-22-ENAA 4RF SR+, BR, 400-470 MHz, SSC, Full Duplex, 2E2S, EN, STD Aprisa SR+ Product Description 1.6.0 Protected Station The Aprisa SR+ Protected Station is full monitored hot-standby and fully hot-swappable. The Aprisa SR+ Protected Station provides radio and user interface protection for Aprisa SR+ radios when configured as a base station. The RF ports and interface ports from the active Aprisa SR+ radio are switched to the standby radio if there is a failure in the active radio. Product Options | 29 Option Example Part Number Part Description APSQ-R400-SSC-HD-22-ENAA 4RF SR+, PS, 400-470 MHz, SSC, Half Duplex, 2E2S, EN, AA The Aprisa SR+ Protected Station is comprised of an Aprisa SR+ Protection Switch and two standard Aprisa SR+ radios mounted in a 2U rack mounting chassis. The Aprisa SR+ Protected Station is full monitored hot-standby and fully hot-swappable. All interfaces (RF, data, etc.) are continually monitored on both the active and standby radio to ensure correct operation. The standby radio can be replaced without impacting traffic flow on the active radio. The Aprisa SR+ radios can be any of the currently available Aprisa SR+ radio frequency bands, channel sizes or interface port options. The Aprisa SR+ Protected Station can operate as a base station, repeater station or remote station. The protection behaviour and switching criteria between the active and standby radios is identical for the three configurations. By default, the Aprisa SR+ Protected Station is configured with the left hand radio (A) designated as the primary radio and the right hand radio (B) designated as the secondary radio. Each radio is configured with its own unique IP and MAC address and the address of the partner radio. On power-up, the primary radio will assume the active role and the secondary radio will assume the standby role. If, for some reason, only one radio is powered on it will automatically assume the active role. Protected Ports The protected ports are located on the protected station front panel. Switching occurs between the active radio ports and the standby radio ports based on the switching criteria described below. The protected ports include:
Antenna ports ANT/TX and RX (if dual antenna ports used) Ethernet ports 1 and 2 Serial port Aprisa SR+ Product Description 1.6.0 30 | Product Options Operation In hot-standby normal operation, the active radio carries all RS-232 serial and Ethernet traffic over the radio link and the standby radio transmit is on with its transmitter connected to an internal load. Both radios are continually monitored for correct operation including the transmitter and receiver and alarms are raised if an event occurs. The active radio sends regular keep alive messages to the standby radio to indicate it is operating correctly. In the event of a failure on the active radio, the RF link and user interface traffic is automatically switched to the standby radio. The failed radio can then be replaced in the field without interrupting user traffic (see Aprisa SR+ User Manual). Switch Over The switch over to the standby radio can be initiated automatically, on fault detection, or manually via the Hardware Manual Lock switch on the Protection Switch or the Software Manual Lock from SuperVisor. Additionally, it is possible to switch over the radios remotely without visiting the station site, via the remote control connector on the front of the Protection Switch. Configuration Management The Primary and Secondary radios are managed with the embedded web-based management tool, SuperVisor, by using either the Primary or Secondary IP address. Configuration changes in one of the radios will automatically be reflected in the partner radio. To ensure all remote stations are registered to the correct (active) base station, changes to the Network Table are automatically synchronized from the active radio to the standby radio. The Network Table is only visible on the active radio. This synchronization does not occur if the Hardware Manual Lock is active. Aprisa SR+ Product Description 1.6.0 Product Options | 31 Power The external power source must be connected to both the A and B Molex 2 pin male power connectors located on the protected station front panel. The A power input powers the A radio and the B power input powers the B radio. The protection switch is powered from the A power input or the B power input (whichever is available). The maximum combined power consumption is 42 Watts for 10 W transmit peak power. The Aprisa SR+ Protected station has two DC power options, 13.8 VDC and 48 VDC. 13.8 VDC The 13.8 VDC nominal external power source can operate over the voltage range of +10.5 to +30 V DC
(negative earth). An example of the 13.8 VDC option part number is:
Part Number Part Description APSQ-R400-SSC-HD-22-ENAA 4RF SR+, PS, 400-470 MHz, SSC, Half Duplex, 2E2S, EN, STD 48 VDC The 48 VDC nominal external power source can operate over the voltage range of 18 to 60 V DC (floating). An example of the 48 VDC option part number is:
Part Number Part Description APSQ-R400-SSC-HD-22-ENAB 4RF SR+, PS, 400-470 MHz, SSC, Half Duplex, 2E2S, EN, 48VDC Aprisa SR+ Product Description 1.6.0 32 | Product Options Data Driven Protected Station The Aprisa SR+ Data Driven Protected Station provides radio and RS-232 serial port user interface protection for Aprisa SR+ radios. Example Part:
Part Number Part Description APSQ-D400-SSC-HD-22-ENAA 4RF SR+, PD, 400-470 MHz, SSC, Half Dup, 2E2S, EN, STD The Aprisa SR+ Data Driven Protected Station shown is comprised of two standard Aprisa SR+ setup as dual antenna port, half duplex radios and two external duplexers mounted on 19" rack mounting shelves. The Aprisa SR+ radios can be any of the currently available Aprisa SR+ radio frequency band options. By default, the Aprisa SR+ Data Driven Protected Station is configured with the left hand radio (A) designated as the primary radio and the right hand radio (B) designated as the secondary radio. Each radio is configured with its own unique IP and MAC address and the address of the partner radio. On power-up, the primary radio will assume the active role and the secondary radio will assume the standby role. If, for some reason, only one radio is powered on it will automatically assume the active role. Operation The active radio is determined explicitly by which radio receives data on its RS-232 serial port input from the interface. The active radio carries all RS-232 serial traffic over its radio link and the standby radio is unused with its transmitter turned off. If data is received on the RS-232 serial port interface input of the standby radio, it will immediately become the active radio and the radio which was active will become the standby radio. Over The Air Compatibility If the Aprisa SR+ Data Driven Protected Station is to be used in a network of New Aprisa SR radios, the SR Compatible option must be enabled (see Aprisa SR+ User Manual 1.5.0). Aprisa SR+ Product Description 1.6.0 Product Options | 33 Switch Over The active radio is determined explicitly by which radio receives data on its RS-232 serial port. The switching and blocking criteria used for the standard Protected Station do not apply. This means that events and alarms on the unit are not used as switching criteria. Configuration Management The Primary and Secondary radios are managed with the embedded web-based management tool, SuperVisor by using either the Primary or Secondary IP address. Configuration changes in one of the radios will automatically be reflected in the partner radio. Changes to the Network Table are automatically synchronized from the active radio to the standby radio but the Network Table is only visible on the active radio. Power A +10.5 to +30 V DC external power source must be connected to both the A and B Phoenix Contact 2 pin male power connectors. The maximum combined power consumption is 32.0 W for 1 W transmit power. Aprisa SR+ Product Description 1.6.0 34 | Product Options Duplexer Kits The Aprisa SR+ product range contains Duplexer Kit accessories for use with the Dual Antenna port Aprisa SR+ radios. Radio Duplexer Kits Example of part number: APSB-KDUP-928-G2-BR Part Number Description APSB-KDUP-135-N0-BR APSB-KDUP-320-A1-BR APSB-KDUP-400-B1-BR APSB-KDUP-450-M0-BR APSB-KDUP-450-P0-BR Aprisa SR+ Duplexer Kit for a SR+ Radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x N0 Duplexer 135 MHz, s4.6 MHz, p0.5 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a Aprisa SR+ radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x A1 Duplexer 300 MHz, s 5 MHz, p 0.5 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ Radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x B1 Duplexer 400 MHz, s 5 MHz, p 0.5 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x M0 Duplexer 450 MHz, s 5 MHz, p 0.5 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1 or 2 Aprisa SR+ radios and 1 duplexer 1x P0 Duplexer 450 MHz, s 3 MHz, p 0.5 MHz 2x TNC to SMA right angle 640mm cab Aprisa SR+ Product Description 1.6.0 Part Number Description Product Options | 35 APSB-KDUP-700-E0-BR APSB-KDUP-928-G0-BR APSB-KDUP-928-G2-BR-MM APSB-KDUP-928-G2-BR APSB-KDUP-928-G3-BR APSB-KDUP-928-G3-BR-MM Aprisa SR+ Duplexer Kit for a SR+ radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1 or 2 Aprisa SR+ radios and 1 duplexer 1x E0 Duplexer 700 MHz, min s 30 MHz, p 7.0 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x G0 Duplexer 900 MHz, s 40 MHz, p 7 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ radio containing:
1x 1U 19" rack mid mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x G2 Duplexer 900 MHz, s 9 MHz, p 1 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x G2 Duplexer 900 MHz, s 9 MHz, p 1 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ radio containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x G3 Duplexer 900 MHz, s5.5 MHz, p0.5 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ radio containing:
1x 1U 19" rack mid mount shelf with duplexer mounting brackets and screws to mount 1x SR+ radio and 1x duplexer 1x G3 Duplexer 900 MHz, s5.5 MHz, p0.5 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Product Description 1.6.0 36 | Product Options Protected Station Duplexer Kits Example of part number: APSB-KDUP-928-G2-PS Part Number Description APSB-KDUP-135-N0-PS Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x N0 Duplexer 135 MHz, s4.6 MHz, p0.5 MHz 2x right angle TNC to SMA right angle 640mm cables Rack front mounted APSB-KDUP-135-N0-PS-DA APSB-KDUP-320-A1-PS APSB-KDUP-320-A1-PS-DA APSB-KDUP-400-B1-PS-DA Aprisa SR+ Duplexer Kit for a dual antenna SR+ Protected Station containing:
2x N0 Duplexer 135 MHz, s4.6 MHz, p0.5 MHz 4x right angle TNC to SMA right angle 640mm cables Rack front mounted Aprisa SR+ Duplexer Kit for a Aprisa SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 1x A1 Duplexer 300 MHz, s 5 MHz, p 0.5 MHz 2x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a dual antenna Aprisa SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 2x A1 Duplexer 300 MHz, s 5 MHz, p 0.5 MHz 4x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a dual antenna SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 2x B1 Duplexers 400 MHz, s 5 MHz, p 0.5 MHz 4x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Product Description 1.6.0 Part Number Description Product Options | 37 APSB-KDUP-400-B1-PS APSB-KDUP-450-M0-PS APSB-KDUP-450-M0-PS-DA APSB-KDUP-450-P0-PS APSB-KDUP-450-P0-PS-DA APSB-KDUP-700-E0-PS-DA APSB-KDUP-928-G0-PS APSB-KDUP-928-G2-PS Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 1x B1 Duplexer 400 MHz, s 5 MHz, p 0.5 MHz 2x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 1x M0 Duplexer 450 MHz, s 5 MHz, p 0.5 MHz 2x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a dual antenna SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 2x M0 Duplexer 450 MHz, s 5 MHz, p 0.5 MHz 4x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 1x P0 Duplexer 450 MHz, s 3 MHz, p 0.5 MHz 2x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a dual antenna SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 2x P0 Duplexer 450 MHz, s 3 MHz, p 0.5 MHz 4x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a dual antenna SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 2x E0 Duplexer 700 MHz, min s 30 MHz, p 7.0 MHz 4x right angle TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 1x G0 Duplexer 900 MHz, s 40 MHz, p 7 MHz 2x TNC to SMA right angle 590mm cables Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x 1U 19" rack front mount shelf with duplexer mounting brackets and screws 1x G2 Duplexer 900 MHz, s 9 MHz, p 1 MHz 2x TNC to SMA right angle 590mm cables Aprisa SR+ Product Description 1.6.0 38 | Product Options Part Number Description APSB-KDUP-928-G2-PS-MM APSB-KDUP-928-G3-PS-MM APSB-KDUP-928-G3-PS Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x 1U 19" rack mid mount shelf with duplexer mounting brackets and screws 1x G2 Duplexer 900 MHz, s 9 MHz, p 1 MHz 2x TNC to SMA right angle 590mm cables Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x 2U 19" rack mid mount shelf with duplexer mounting brackets and screws 1x G3 Duplexer 900 MHz, s5.5 MHz, p0.5 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Duplexer Kit for a SR+ Protected Station containing:
1x 2U 19" rack front mount shelf with duplexer mounting brackets and screws 1x G3 Duplexer 900 MHz, s5.5 MHz, p0.5 MHz 2x TNC to SMA right angle 640mm cables Aprisa SR+ Product Description 1.6.0 Product Options | 39 USB RS-232 / RS-485 Serial Port The Aprisa SR+ USB host port is predominantly used for software upgrade and diagnostic reporting. However, it can also be used to provide an additional RS-232 DCE or RS-485 serial port for customer traffic. This is accomplished with a USB to RS-232 / RS-485 serial converter cable. This plugs into the USB host port connector and can be terminated with the required customer connector. This additional RS-232 / RS-485 serial port is enabled with the SuperVisor mode setting in Serial Port Settings. The Aprisa SR+ USB port has driver support for these USB serial converters. Other USB serial converters may not operate correctly. USB RS-232 / RS-485 operation The USB serial converter buffers the received data frames into 64 byte blocks separated by a small inter-
frame gap. For the majority of applications, this fragmentation of egress frames is not an issue. However, there are some applications that may be sensitive to the inter-frame gap, therefore, these applications need consideration. A 5 ms inter-frame is recommended for the applications that are sensitive to inter-frame gap timings. On a USB RS-232 port, Modbus RTU can operate up to 9600 bit/s with all packet sizes and up to 115200 bit/s if the packet size is less than 64 bytes. The standard RS-232 port is fully compatible with Modbus RTU at all baud rates. Aprisa SR+ Product Description 1.6.0 40 | Specifications 3. Specifications RF Specifications Blocking (desensitization), intermodulation, spurious response rejection, and adjacent channel selectivity values determined according to the methods introduced in V1.7.1 of ETSI standards EN 300 113-1. Frequency Bands ETSI Compliant Broadcast Band Frequency Band Frequency Tuning Synthesizer Step VHF UHF UHF UHF UHF 135 MHz 220 MHz 320 MHz 400 MHz 450 MHz Range 135-175 MHz 215-240 MHz 320-400 MHz 400-470 MHz 450-520 MHz Size 0.625 kHz 0.625 kHz 6.250 kHz 6.250 kHz 6.250 kHz FCC Compliant Broadcast Band Frequency Band Frequency Tuning Synthesizer Step VHF UHF UHF UHF UHF UHF UHF 135 MHz 220 MHz 400 MHz 450 MHz 700 MHz 896 MHz 928 MHz Range 135-175 MHz 215-240 MHz 400-470 MHz 450-520 MHz Size 0.625 kHz 0.625 kHz 6.250 kHz 6.250 kHz 757-758 MHz and 6.250 kHz 787-788 MHz 896-902 MHz (Note 1) 928-960 MHz (Note 1) 6.250 kHz 6.250 kHz IC Compliant Broadcast Band Frequency Band Frequency Tuning Synthesizer Step VHF UHF UHF UHF UHF UHF 135 MHz 220 MHz 220 MHz 400 MHz 896 MHz 928 MHz Range 135-175 MHz 215-240 MHz 215-240 MHz 400-470 MHz 896-902 MHz (Note 1) 928-960 MHz (Note 1) Size 0.625 kHz 0.625 kHz 3.125 kHz 6.250 kHz 6.250 kHz 6.250 kHz The Frequency Tuning Range is not an indication of the exact frequencies approved by FCC / IC. Note 1: The receive tuning range is specified. The transmit tuning range is 896 - 960 MHz. Aprisa SR+ Product Description 1.6.0 Specifications | 41 Channel Sizes ETSI Compliant ETSI: 135 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 25 kHz 120.0 kbit/s 80.0 kbit/s 40.0 kbit/s 19.2 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 25 kHz 103.9 kbit/s 46.2 kbit/s 23.1 kbit/s 16.7 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 25 kHz 91.2 kbit/s 34.6 kbit/s 17.3 kbit/s 8.3 kbit/s Aprisa SR+ Product Description 1.6.0 42 | Specifications ETSI: 220 / 320 / 400 MHz Bands No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 20 kHz 25 kHz 50 kHz (1) 84.0 kbit/s 56.0 kbit/s 28.0 kbit/s 9.6 kbit/s 120.0 kbit/s 80.0 kbit/s 40.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 20 kHz 25 kHz 50 kHz (1) 72.7 kbit/s 32.4 kbit/s 16.2 kbit/s 8.4 kbit/s 103.9 kbit/s 46.2 kbit/s 23.1 kbit/s 16.7 kbit/s 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 20 kHz 25 kHz 50 kHz (1) 63.8 kbit/s 24.2 kbit/s 12.1 kbit/s 4.1 kbit/s 91.2 kbit/s 34.6 kbit/s 17.3 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Note 1: It is the responsibility of the user to check for country regulatory of 50 kHz availability in this frequency band. Aprisa SR+ Product Description 1.6.0 Specifications | 43 ETSI: 450 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 25 kHz 120.0 kbit/s 80.0 kbit/s 40.0 kbit/s 19.2 kbit/s 50 kHz (1) 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 25 kHz 103.9 kbit/s 46.2 kbit/s 23.1 kbit/s 16.7 kbit/s 50 kHz (1) 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 25 kHz 50 kHz (1) 91.2 kbit/s 34.6 kbit/s 17.3 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Note 1: It is the responsibility of the user to check for country regulatory of 50 kHz availability in this frequency band. Aprisa SR+ Product Description 1.6.0 44 | Specifications FCC Compliant FCC: 135 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 15 kHz 30 kHz 64 QAM 16 QAM QPSK 4-CPFSK 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 15 kHz 30 kHz 64 QAM 16 QAM QPSK 4-CPFSK 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 15 kHz 30 kHz 64 QAM 16 QAM QPSK 4-CPFSK 41.0 kbit/s 15.6 kbit/s 7.8 kbit/s 4.1 kbit/s 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s Aprisa SR+ Product Description 1.6.0 Specifications | 45 FCC: 220 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 15 kHz 25 kHz 50 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 15 kHz 25 kHz 50 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 41.0 kbit/s 15.6 kbit/s 7.8 kbit/s 4.1 kbit/s 15 kHz 25 kHz 50 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Aprisa SR+ Product Description 1.6.0 46 | Specifications FCC: 400 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 25 kHz 50 kHz (1) 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 25 kHz 50 kHz (1) 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 41.0 kbit/s 15.6 kbit/s 7.8 kbit/s 4.1 kbit/s 25 kHz 50 kHz (1) 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Note 1: It is the responsibility of the user to check for country regulatory of 50 kHz availability in this frequency band. Aprisa SR+ Product Description 1.6.0 Specifications | 47 FCC: 450 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 25 kHz 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 25 kHz 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 41.0 kbit/s 15.6 kbit/s 7.8 kbit/s 4.1 kbit/s 25 kHz 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s Aprisa SR+ Product Description 1.6.0 48 | Specifications FCC: 700 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 25 kHz 50 kHz 75 kHz (1) 64 QAM 16 QAM QPSK 4-CPFSK (2) 120.0 kbit/s 80.0 kbit/s 40.0 kbit/s 19.2 kbit/s 240.0 kbit/s 160.0 kbit/s 80.0 kbit/s 38.4 kbit/s 360.0 kbit/s 240.0 kbit/s 120.0 kbit/s 57.6 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 25 kHz 50 kHz 75 kHz (1) 64 QAM 16 QAM QPSK 4-CPFSK (2) 103.9 kbit/s 46.2 kbit/s 23.1 kbit/s 16.7 kbit/s 207.8 kbit/s 92.5 kbit/s 46.2 kbit/s 33.4 kbit/s 311.8 kbit/s 138.7 kbit/s 69.4 kbit/s 50.1 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 25 kHz 50 kHz 75 kHz (1) 64 QAM 16 QAM QPSK 4-CPFSK (2) 91.2 kbit/s 34.6 kbit/s 17.3 kbit/s 8.3 kbit/s 182.4 kbit/s 69.3 kbit/s 34.6 kbit/s 16.5 kbit/s 273.6 kbit/s 103.9 kbit/s 52.0 kbit/s 24.8 kbit/s Note 1: Available in future software release. Note 2: Please consult 4RF for availability. Aprisa SR+ Product Description 1.6.0 Specifications | 49 FCC: 896 / 928 MHz Bands No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 25 kHz 50 kHz 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 25 kHz 50 kHz 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 25 kHz 50 kHz 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Aprisa SR+ Product Description 1.6.0 50 | Specifications IC Compliant IC: 135 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 15 kHz 30 kHz 64 QAM 16 QAM QPSK 4-CPFSK 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 15 kHz 30 kHz 64 QAM 16 QAM QPSK 4-CPFSK 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 15 kHz 30 kHz 64 QAM 16 QAM QPSK 4-CPFSK 41.0 kbit/s 15.6 kbit/s 7.8 kbit/s 4.1 kbit/s 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s Aprisa SR+ Product Description 1.6.0 Specifications | 51 IC: 220 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 15 kHz 25 kHz 50 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 15 kHz 25 kHz 50 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 41.0 kbit/s 15.6 kbit/s 7.8 kbit/s 4.1 kbit/s 15 kHz 25 kHz 50 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Aprisa SR+ Product Description 1.6.0 52 | Specifications IC: 400 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 25 kHz 50 kHz (1) 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 25 kHz 50 kHz (1) 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 41.0 kbit/s 15.6 kbit/s 7.8 kbit/s 4.1 kbit/s 25 kHz 50 kHz (1) 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Note 1: It is the responsibility of the user to check for country regulatory of 50 kHz availability in this frequency band. Aprisa SR+ Product Description 1.6.0 Specifications | 53 IC: 896 / 928 MHz Bands No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 25 kHz 50 kHz 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 52.0 kbit/s 23.1 kbit/s 11.6 kbit/s 8.4 kbit/s 25 kHz 50 kHz 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.7 kbit/s 187.1 kbit/s 83.2 kbit/s 41.6 kbit/s 33.4 kbit/s Maximum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 64 QAM 16 QAM QPSK 4-CPFSK 12.5 kHz 45.6 kbit/s 17.3 kbit/s 8.7 kbit/s 4.1 kbit/s 25 kHz 50 kHz 73.0 kbit/s 27.7 kbit/s 13.9 kbit/s 8.3 kbit/s 164.2 kbit/s 62.4 kbit/s 31.2 kbit/s 16.5 kbit/s Aprisa SR+ Product Description 1.6.0 54 | Specifications Receiver Receiver Sensitivity 12.5 kHz 25 kHz 50 kHz 75 kHz Max coded FEC
-106 dBm
-102 dBm
-99 dBm
-96 dBm Min coded FEC
-105 dBm
-101 dBm
-98 dBm
-95 dBm No FEC
-103 dBm
-99 dBm
-96 dBm
-93 dBm Max coded FEC
-113 dBm
-110 dBm
-107 dBm
-104 dBm Min coded FEC
-112 dBm
-109 dBm
-106 dBm
-103 dBm No FEC
-109 dBm
-106 dBm
-103 dBm
-100 dBm Max coded FEC
-118 dBm
-115 dBm
-112 dBm
-109 dBm Min coded FEC
-117 dBm
-114 dBm
-111 dBm
-108 dBm No FEC
-115 dBm
-112 dBm
-109 dBm
-106 dBm 64 QAM 64 QAM 64 QAM 16 QAM 16 QAM 16 QAM QPSK QPSK QPSK 4-CPFSK Max coded FEC NA NA NA NA 4-CPFSK Min coded FEC
-117 dBm
-114 dBm
-111 dBm
-108 dBm 4-CPFSK No FEC
-115 dBm
-112 dBm
-109 dBm
-106 dBm 64 QAM 64 QAM 64 QAM 16 QAM 16 QAM 16 QAM QPSK QPSK QPSK Max coded FEC
-103 dBm
-99 dBm
-96 dBm
-93 dBm Min coded FEC
-101 dBm
-97 dBm
-94 dBm
-91 dBm No FEC
-96 dBm
-92 dBm
-89 dBm
-86 dBm Max coded FEC
-110 dBm
-107 dBm
-104 dBm
-101 dBm Min coded FEC
-108 dBm
-105 dBm
-102 dBm
-99 dBm No FEC
-102 dBm
-99 dBm
-96 dBm
-93 dBm Max coded FEC
-115 dBm
-112 dBm
-109 dBm
-106 dBm Min coded FEC
-113 dBm
-110 dBm
-107 dBm
-104 dBm No FEC
-108 dBm
-105 dBm
-102 dBm
-99 dBm 4-CPFSK Max coded FEC NA NA NA NA 4-CPFSK Min coded FEC
-113 dBm
-110 dBm
-107 dBm
-104 dBm 4-CPFSK No FEC
-108 dBm
-105 dBm
-102 dBm
-99 dBm Aprisa SR+ Product Description 1.6.0 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 BER < 10-6 Adjacent Channel Selectivity Specifications | 55 12.5 kHz 25 kHz 50 kHz 75 kHz Adjacent channel selectivity
> -47 dBm
> -37 dBm
> -37 dBm
> -37 dBm BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 Co-Channel Rejection BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPSK 4-CPFSK 64 QAM 16 QAM QPSK 4-CPFSK
> 43 dB
> 53 dB
> 53 dB
> 53 dB
> 43 dB
> 53 dB
> 53 dB
> 53 dB
> 48 dB
> 58 dB
> 58 dB
> 58 dB
> 55 dB
> 65 dB
> 65 dB
> 65 dB 12.5 kHz 25 kHz 50 kHz 75 kHz
> 23 dB
> 23 dB
> 23 dB
> 23 dB
> 19 dB
> 19 dB
> 19 dB
> 19 dB
> 12 dB
> 12 dB
> 12 dB
> 12 dB
> 17 dB
> 17 dB
> 17 dB
> 17 dB Intermodulation Response Rejection 12.5 kHz 25 kHz 50 kHz 75 kHz Intermodulation response rejection
> -35 dBm
> -35 dBm
> -35 dBm
> -35 dBm BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPSK 4-CPFSK
> 55 dB
> 55 dB
> 55 dB
> 55 dB
> 55 dB
> 55 dB
> 55 dB
> 55 dB
> 60 dB
> 60 dB
> 60 dB
> 60 dB
> 65 dB
> 65 dB
> 65 dB
> 65 dB Blocking or Desensitization 12.5 kHz 25 kHz 50 kHz 75 kHz Blocking or desensitization
> -17 dBm
> -17 dBm
> -17 dBm
> -17 dBm BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPSK 4-CPFSK
> 73 dB
> 73 dB
> 73 dB
> 73 dB
> 73 dB
> 73 dB
> 73 dB
> 73 dB
> 78 dB
> 78 dB
> 78 dB
> 78 dB
> 85 dB
> 85 dB
> 85 dB
> 85 dB Aprisa SR+ Product Description 1.6.0 56 | Specifications Spurious Response Rejection 12.5 kHz 25 kHz 50 kHz 75 kHz Spurious response rejection
> -32 dBm
> -32 dBm
> -32 dBm
> -32 dBm BER < 10-2 BER < 10-2 BER < 10-2 BER < 10-2 64 QAM 16 QAM QPSK 4-CPFSK
> 58 dB
> 58 dB
> 58 dB
> 58 dB
> 58 dB
> 58 dB
> 58 dB
> 58 dB
> 63 dB
> 63 dB
> 63 dB
> 63 dB
> 70 dB
> 70 dB
> 70 dB
> 70 dB Receiver Spurious Radiation 12.5 kHz 25 kHz 50 kHz 75 kHz Receiver spurious radiation
> -57 dBm
> -57 dBm
> -57 dBm
> -57 dBm Aprisa SR+ Product Description 1.6.0 Specifications | 57 Transmitter Max peak envelope power
(PEP) 12.5 W (+41 dBm) Average Power output 64 QAM 16 QAM QPSK 0.01 to 2.5 W (+10 to +34 dBm, in 1 dB steps) 0.01 to 3.2 W (+10 to +35 dBm, in 1 dB steps) 0.01 to 5.0 W (+10 to +37 dBm, in 1 dB steps) 4-CPFSK (Note 1) 0.01 to 10.0 W (+10 to +40 dBm, in 1 dB steps) Note 1: Please consult 4RF for availability Note: The Aprisa SR+ transmitter contains power amplifier protection which allows the antenna to be disconnected from the antenna port without product damage. Adjacent channel power
< - 60 dBc Transient adjacent channel power
< - 60 dBc Spurious emissions Attack time Release time Data turnaround time Frequency stability Frequency aging
< - 37 dBm
< 1.5 ms
< 0.5 ms
< 2 ms 1.0 ppm
< 1 ppm / annum Emission Designator Suffix QPSK G1D, QAM D1D Aprisa SR+ Product Description 1.6.0 58 | Specifications Modem Forward Error Correction Variable length concatenated Reed Solomon plus convolutional code Adaptive Burst Support Adaptive FEC Adaptive Coding and Modulation Data Payload Security Data payload security CCM* Counter with CBC-MAC Data encryption Data authentication Counter Mode Encryption (CTR) using Advanced Encryption Standard (AES) 128, 192 or 256 Cipher Block Chaining Message Authentication Code (CBC-MAC) using Advanced Encryption Standard (AES) 128, 192 or 256 Aprisa SR+ Product Description 1.6.0 Specifications | 59 Interface Specifications Ethernet Interface The Aprisa SR+ radio features an integrated 10Base-T/100Base-TX layer-2 Ethernet switch. To simplify network setup, each port supports auto-negotiation and auto-sensing MDI/MDIX. Operators can select from the following preset modes:
Auto negotiate 10Base-T half or full duplex 100Base-TX half or full duplex The Ethernet ports are IEEE 802.3-compatible. The L2 Bridge (Switch) is IEEE 802.1d/q/p compatible, and supports VLANs and VLAN manipulation of add/remove VLANs. General Interface RJ45 x 2 (Integrated 2-port switch) Cabling CAT-5/6 UTP, supports auto MDIX (Standard Ethernet) Maximum line length 100 metres on cat-5 or better Bandwidth allocation The Ethernet capacity maximum is determined by the available radio link capacity. Maximum transmission unit Option setting of 1522 or 1536 octets Address table size 1024 MAC addresses Ethernet mode Diagnostics Left Green LED Right Orange LED 10Base-T or 100Base-TX Full duplex or half duplex
(Auto-negotiating and auto-sensing) Off: no Ethernet signal received On: Ethernet signal received Off: no data present on the interface Flashing: data present on the interface Note: Do not connect Power over Ethernet (PoE) connections to the Aprisa SR+ Ethernet ports as this will damage the port. Aprisa SR+ Product Description 1.6.0 60 | Specifications RS-232 Asynchronous Interface The Aprisa SR+ radios ITU-T V.24 compliant RS-232 interface is configured as a Cisco pinout DCE. The interface terminates to a DTE using a straight-through cable or to a DCE with a crossover cable (null modem). The interface uses two handshaking control lines between the DTE and the DCE. General Interface ITU-T V.24 / EIA/TIA RS-232E Async parameters Interface direction DCE only Maximum line length 10 metres (dependent on baud rate) Standard mode data bits 7 or 8 bits Standard mode parity Configurable for None, Even or Odd Standard mode stop bits 1 or 2 bits Interface baud rates 300, 600, 1200, 2400, 4800, 9600, 19200, 38400, 57600 and 115200 bit/s Control signals DCE to DTE CTS, RTS, DSR, DTR Diagnostics Left Green LED Right Orange LED Off: no RS-232 device connected On: RS-232 device connected Off: no data present on the interface Flashing: data present on the interface Aprisa SR+ Product Description 1.6.0 Specifications | 61 Hardware Alarms Interface The hardware alarms interface supports two alarm inputs and two alarms outputs. Alarm Inputs The alarm connector provides two hardware alarm inputs for alarm transmission to the other radios in the network. Interface Detector type RJ45 connector Non-isolated ground referenced voltage detector Detection voltage - on Detection voltage - off Maximum applied input voltage Maximum input current limit
> +10 VDC
< +4 VDC 30 VDC 10 mA Alarm Outputs The alarm connector provides two hardware alarm outputs for alarm reception from other radios in the network. Interface Output type RJ45 connector Non-isolated ground referenced open collector output Maximum applied voltage Maximum drive current 30 VDC 100 mA Overload protection Thermally resettable fuse Protect Interface The Protect interface is used to connect the radios to the protection switch within a Protected Station. It is not a customer interface. Protection Switch Specifications RF Insertion Loss
< 0.5 dB (switch and connecting cables) Remote Control inputs Logic 4700 ohms pullup to +3.3 VDC Aprisa SR+ Product Description 1.6.0 62 | Specifications Power Specifications Power Supply Aprisa SR+ Radio Nominal voltage
+13.8 VDC (negative earth) Absolute input voltage range
+10 to +30 VDC Maximum power input 35 W Connector Molex 2 pin male screw fitting 39526-4002 Aprisa SR+ Protected Station Power Input 13.8 VDC 48 VDC Nominal voltage
+13.8 VDC (negative 48 VDC (floating) earth) Absolute input voltage range
+10 to +30 VDC 18 to 60 VDC Maximum power input 42 W Connector 2x Molex 2 pin male screw fitting 39526-4002 Aprisa SR+ Migration Master Station Power Input 13.8 VDC 48 VDC Nominal voltage
+13.8 VDC (negative 48 VDC (floating) earth) Absolute input voltage range
+10 to +30 VDC 18 to 60 VDC Maximum power input 48 W Connector 4x Molex 2 pin male screw fitting 39526-4002 Aprisa SR+ Product Description 1.6.0 Power Consumption Specifications | 63 Note: The radio power consumption is very dependent on transmitter power, the type of traffic and network activity. Aprisa SR+ Radio Mode Power Consumption Transmit / Receive
< 35 W for 10 W transmit peak power
< 25.0 W for 1 W transmit power Receive only Standard
< 7 W Power Optimized
< 3 W in active receive state
< 2 W in idle receive state
< 0.5 W in sleep mode Aprisa SR+ Protected Station and Aprisa SR+ Data Driven Protected Station Mode Power Consumption Transmit / Receive
< 42 W for 10 W transmit peak power
< 32.0 W for 1 W transmit power Receive only
< 15 W Aprisa SR+ Migration Master Station Mode Power Consumption Transmit / Receive
< 48 W for 10 W transmit peak power
< 38.0 W for 1 W transmit power Receive only
< 21 W Power Dissipation Aprisa SR+ Radio Transmit Power Power Dissipation 10 W transmit power 1 W transmit power
< 25 W
< 24 W Aprisa SR+ Protected Station and Aprisa SR+ Data Driven Protected Station Transmit Power Power Dissipation 10 W transmit power 1 W transmit power
< 32 W
< 31 W Aprisa SR+ Product Description 1.6.0 64 | Specifications General Specifications Environmental Operating temperature range
-40 to +70 C (-40 to +158 F) Storage temperature range
-40 to +80 C (-40 to +176 F) Operating humidity Maximum 95% non-condensing Acoustic noise emission No audible noise emission Mechanical Aprisa SR+ Radio Dimensions Width 210 mm (8.27) Depth 130 mm (5.12) and 146 mm (5.748) with TNC connectors Weight Colour Mounting Height 41.5 mm (1.63) 1.25 kg (2.81 lbs) Matt black Wall (2 x M5 screws) Rack shelf (4 x M4 screws) DIN rail bracket Aprisa SR+ Protected Station Dimensions Width 432.6 mm (17) Weight Colour Mounting Depth 372 mm (14.6) and 388 mm (15.276) with TNC connectors Height 2U plus external duplexer (if used) 9.4 kg (22 lbs) (includes the 2 radios) Matt black Rack mount (4 x M6 screws) Aprisa SR+ Migration Master Station Dimensions Width 432.6 mm (17) Weight Colour Mounting Depth 372 mm (14.6) and 388 mm (15.276) with TNC connectors Height 3U plus external duplexer (if used) 13.8 kg (31 lbs) (includes the 2 radios) Matt black Rack mount (8 x M6 screws) Aprisa SR+ Product Description 1.6.0 Compliance Specifications | 65 ETSI FCC IC Radio EMI / EMC Safety Environmental Radio EMC Safety EN 300 113-2 EN 301 489-1 and 5 EN 60950-1:2006 Class 1 division 2 for hazardous locations ETS 300 019 Class 3.4 Ingress Protection IP51 47CFR part 24, part 27, part 90 and part 101 Private Land Mobile Radio Services 47CFR part 15 Radio Frequency Devices, EN 301 489-1 and 5 EN 60950-1:2006 Class 1 division 2 for hazardous locations Environmental ETS 300 019 Class 3.4 Ingress Protection IP51 Radio EMC RSS-119 / RSS-134 This Class A digital apparatus complies with Canadian standard ICES-003. Cet appareil numrique de la classe A est conforme la norme NMB-003 du Canada. Safety EN 60950-1:2006 Class 1 division 2 for hazardous locations Environmental ETS 300 019 Class 3.4 Ingress Protection IP51 Aprisa SR+ Product Description 1.6.0 66 | Management 4. Management SuperVisor The Aprisa SR+ contains an embedded web server application (SuperVisor) to enable element management with any major web browser (such as Mozilla Firefox or Microsoft Internet Explorer). SuperVisor enables operators to configure and manage the Aprisa SR+ base station radio and repeater /
remote station radios over the radio link. The key features of SuperVisor are:
Full element management, configuration and diagnostics Manage the entire network from the Base Station (remote management of elements) Managed network software distribution and upgrades Performance and alarm monitoring of the entire network, including RSSI, alarm states, time-
stamped events. View and set standard radio configuration parameters including frequencies, transmit power, channel access, serial, Ethernet port settings Set and view security parameters User management Operates over a secure HTTPS session on the access connection to the base station The following are three examples of SuperVisor screens:
Aprisa SR+ Product Description 1.6.0 Viewing the Aprisa SR+ Terminal Settings The SuperVisor software enables operators to view the terminal settings:
Management | 67 Aprisa SR+ Product Description 1.6.0 68 | Management Configuring the Aprisa SR+ Terminal Details The SuperVisor software enables operators to set the terminal details including Terminal Name, Location, Contact Name and Contact Details with a maximum of 40 characters. Configuring the Aprisa SR+ RF Network Details The SuperVisor software enables operators to set the RF Network Details including:
Network ID Sets the network ID of this base station node and its remote nodes. Four hex chars Network Radius Sets the maximum number of hops in this network Network Repeaters Proximity Sets the proximity of repeaters in this network Inband Management Enables inband management of remotes / repeaters Inband Management Timeout (sec) Sets the inband management timeout period Aprisa SR+ Product Description 1.6.0 Configuring the Aprisa SR+ Radio Settings Management | 69 The SuperVisor software enables operators to set the radio settings including:
TX Frequency Sets the transmit frequency in MHz TX Power RX Frequency Channel Size Sets the transmit Power in dBm Sets the receive frequency in MHz Sets the channel size 12.5 kHz, 25 kHz or 50 kHz (depending on variant) Antenna Port Configuration Sets the antenna port configuration to single port or dual port Modem Mode Sets the modem / compliance for the radio Modulation Type Sets the fixed TX Modulation Type for the base station radio ACM Control Enables / disables Adaptive Code Modulation for the remote to base direction of transmission (upstream) Aprisa SR+ Product Description 1.6.0 70 | Management Command Line Interface The Aprisa SR+ has a Command Line Interface (CLI) which provides basic product setup and configuration. This interface can be accessed via an Ethernet Port (RJ45) or the Management Port (USB micro type B). The Terminal menu is shown in the following picture:
SNMP In addition to web-based management (SuperVisor) and the Command Line Interface, the Aprisa SR network can also be managed using the Simple Network Management Protocol (SNMP agent). MIB files are supplied which can be used by a dedicated SNMP Manager, such as Castle Rocks network management system, to support effective and flexible network monitoring and diagnostics. Alternatively, the user can use its own 3rd party NMS SNMP agent to manage the SR+ radio network. For communication between the SNMP manager and the radio, Access Controls and Community strings must be set up as described in the Aprisa SR+ User Manual. Aprisa SR+ Product Description 1.6.0 LED Display Panel The Aprisa SR+ has an LED Display panel which provides on-site alarms / diagnostics without the need for PC. Management | 71 Normal Operation In normal radio operation, the LEDs indicate the following conditions:
OK MODE AUX TX RX Flashing Red Radio has not registered Solid Red Alarm present with severity Critical, Major and Minor Flashing Orange Diagnostics Function Active OTA Firmware Distribution Solid Orange Alarm present with Warning Severity TX path fail RX path fail Management traffic on the USB MGMT port Device detect on the USB host port
(momentary) Flashing Green Software Upgrade Successful Stand-by radio in protected station Tx / Rx Data on the USB host port RF path TX is RF path RX is active active Solid Green Power on and functions OK and no alarms Processor Block is OK or active radio in protected station USB interface OK Tx path OK Rx path OK LED Colour Severity Green Orange Red No alarm information only Warning alarm Critical, major or minor alarm Aprisa SR+ Product Description 1.6.0 72 | Management Single Radio Software Upgrade During a radio software upgrade, the LEDs indicate the following conditions:
Software upgrade started - the OK LED flashes orange Software upgrade progress indicated by running RX to OK LEDs Software upgrade completed successfully - the OK LED flashes green Software upgrade failed - any LED flashing red during the upgrade Network Software Upgrade During a network software upgrade, the MODE LED flashes orange on the base station and all remote stations. Test Mode In Test Mode, the LED Display panel presents a real time visual display of the RSSI. This can be used to adjust the antenna for optimum signal strength. Aprisa SR+ Product Description 1.6.0 Applications | 73 5. Applications This section describes sample Aprisa SR+ radio applications. The following applications are described:
Basic point-to-multipoint application Advanced point-to-multipoint application with repeaters Multi-interface point-to-multipoint application Multi-hop Daisy chain repeaters in LBS mode application Pseudo Peer to Peer using base-repeater application Basic point-to-multipoint application Single base station with Ethernet SCADA data inputs to multiple geographically remote sites with Ethernet RTUs requiring control and data acquisition. The base station receives Ethernet frames from the SCADA server LAN and broadcasts all Ethernet frames to all remote stations Each remote site receives Ethernet frames from the RTU and unicasts over the air to the base station. The base station uses an omni directional antenna to provide wide coverage and the remote stations are fitted with directional Yagi antennas to provide higher gain. Aprisa SR+ Product Description 1.6.0 74 | Applications Advanced point-to-multipoint application with repeater Single base station with Ethernet SCADA data inputs to multiple geographically remote sites with Ethernet RTUs requiring control and data acquisition. A repeater is deployed to service remote sites beyond the reach of the base station. The base station receives Ethernet frames from the SCADA server LAN and broadcasts all Ethernet frames to the repeater and its remote stations. Three remote sites have direct radio communication with the base station but the other two remote sites operate via the repeater site. Each remote site receives Ethernet frames from the RTU and unicasts over the air to the repeater / base station. The base station and the repeater station use an omni directional antenna to provide wide coverage and the remote stations are fitted with directional Yagi antennas to provide higher gain. Aprisa SR+ Product Description 1.6.0 Applications | 75 Multi-interface point-to-multipoint application Single base station with Ethernet and RS-232 SCADA data inputs to multiple geographically remote sites with Ethernet and RS-232 RTUs requiring control and data acquisition. The base station receives Ethernet / RS-232 frames from the SCADA servers and broadcasts all frames to all remote stations Each remote site receives Ethernet / RS-232 frames from the RTU and unicasts over the air to the base station. The base station uses an omni directional antenna to provide wide coverage and the remote stations are fitted with directional Yagi antennas to provide higher gain. Aprisa SR+ Product Description 1.6.0 76 | Applications Multi-hop Daisy Chain Repeaters in LBS Mode Application This application is used for daisy chain repeaters when remote stations are very far from base station coverage. Daisy chain repeaters can only be used in LBS channel access mode (and future release in AR mode). In the figure example below, the Base Station can communicate with any of the far remotes via the daisy chain repeaters. The SCADA master will communicate with RTU 2 using a source and destination IP address and the underlining SCADA protocol. On the downstream, the SCADA master would like to communicate with RTU-2 and sends a packet destined to RTU-2 (using RTU 2 destination address). This packet received by the Base Station will then broadcast OTA to Repeater 1. Repeater 1 will store-and-forward the received packet and re-transmit the packet to Repeater 2 and back to the Base Station, which will drop the duplicate packet as this packet is its own forward. Repeater 2 will store-and-forward the packet to the local Ethernet port to RTU 3 (which will drop the packet due to destination address mismatch) and it will also re-transmit the packet OTA to Repeater 3, Remote 1 and back to Repeater 1, which will drop the duplicate packet as this packet is its own forward. Remote-1 will forward the packet to its local Ethernet port and RTU-1 will drop the packet due to destination address mismatch. Repeater 3 will store-and-forward and re-transmit the packet OTA to Remote-2 and back to Repeater 2, which will drop the packet as duplicate packet as this packet is its own forward. Remote 2 will then forward the packet to its local Ethernet port and RTU 2 as the destined address which will process the packet accordingly. On the upstream, RTU 2 will send a packet to the SCADA master, and the radio network from Remote 2 sending a unicast packet destined to Base Station which will act with the same process mechanism as described above for downstream path. Aprisa SR+ Product Description 1.6.0 Applications | 77 Pseudo Peer to Peer using Base-Repeater Application This application is used for remote peer to peer communication via a base-repeater or repeater configuration. In peer to peer, the source RTU will create a message with destination address of the destined RTU in the SCADA layer protocol (and/or IP layer, if applicable). Note, this address is only known by the RTUs as the SR+ radio is transparent to SCADA protocol messages. Although all messages sent from remotes are always destined to the base station, packets can be sent from one remote to the other using the packet filtering peer to peer feature (see the Aprisa SR+ User Manual Radio > Channel Setup) and base-repeater or repeater configuration. In the figure example below, RTU 1 would like to communicate with RTU 3, and thus, Remote 1 and Remote 3 will be configured with packet filtering set to disabled and the Base station configured as a Base-repeater. RTU 1 will create a message destined to RTU 3 and forward it to Remote 1, which in turn will forward it as a unicast message OTA to the Repeater Station, destined to the Base Station (all packets from a remote are destined to the base station). The Repeater Station will store-and-forward the message received from Remote 1 and re-transmit the message to Base Station, but it will also be received by Remote 2. Since, Remote 2 is not the destination and packet filtering is set to automatic (enabled), the packet will be dropped by Remote 2. Note, Remote 3 and Remote 4 cant hear the Repeater Station. The Base-Repeater will forward the packet to the local ports (Ethernet and/or serial), and will also re-
transmit the packet OTA to Remote 3 and Remote 4 and back to the Repeater (this is specific and default to Base-Repeater functionality, as packet filtering is not used in Base-Repeater operation and it can be left in default (automatic)). The Repeater will drop the duplicate packet as this packet is its own forward. Remote 3 will receive the packet and forward it to it local ports (Ethernet or Serial) and to its local RTU 3, as packet filtering is disabled which will then process the packet accordingly. Remote 4 will also receive the packet, but it will drop the packet as packet filtering is enabled. If Remote 4 had packet filtering disabled, the packet would be forwarded to the local port and dropped by RTU 4, due to SCADA protocol destination address mismatch (and/or IP destination address mismatch, if applicable). Aprisa SR+ Product Description 1.6.0 78 | Product Architecture 6. Product Architecture Product Operation There are three components to the wireless interface: the Physical Layer (PHY), the Data Link Layer (DLL) and the Network Layer. These three layers are required to transport data across the wireless channel in the Point-to-multipoint (PMP) configuration. The Aprisa SR+ DLL is largely based on the 802.15.4 MAC layer using a proprietary implementation. Physical Layer The Aprisa SR+ PHY uses a one or two frequency half duplex transmission mode which eliminates the need for a duplexer. However, a Dual Antenna port option is available for separate transmit and receive antenna connection to support external duplexers or filters (half duplex operation). Remote nodes are predominantly in receive mode with only sporadic bursts of transmit data. This reduces power consumption. The Aprisa SR+ is a packet based radio. Data is sent over the wireless channel in discrete packets /
frames, separated in time. The PHY demodulates data within these packets with coherent detection. The Aprisa SR+ PHY provides carrier, symbol and frame synchronization predominantly through the use of preambles. This preamble prefixes all packets sent over the wireless channel which enables fast Synchronization. Data Link Layer / MAC layer The Aprisa SR+ PHY enables multiple users to be able to share a single wireless channel; however a DLL is required to manage data transport. The two key components to the DLL are channel access and hop by hop transmission. Channel Access The Aprisa SR+ radio has two modes of channel access, Access Request and Listen Before Send. Option Function Access Request Channel access scheme where the base stations controls the communication on the channel. Remotes ask for access to the channel, and the base station grants access if the channel is not occupied. Listen Before Send Channel access scheme where network elements listen to ensure the channel is clear, before trying to access the channel. Aprisa SR+ Product Description 1.6.0 Product Architecture | 79 Access Request This scheme is particularly suited to digital SCADA systems where all data flows through the base station. In this case it is important that the base station has contention-free access as it is involved in every transaction. The channel access scheme assigns the base station as the channel access arbitrator and therefore inherently it has contention-free access to the channel. This means that there is no possibility of contention on data originating from the base station. As all data flows to or from the base station, this significantly improves the robustness of the system. All data messages are controlled via the AG (access grant) control message and therefore there is no possibility of contention on the actual end user data. If a remote station accesses the channel, the only contention risk is on the AR (access request) control message. These control messages are designed to be as short as possible and therefore the risk of collision of these control messages is significantly reduced. Should collisions occur these are resolved using a random back off and retry mechanism. As the base station controls all data transactions multiple applications can be effectively handled, including a mixture of polling and report by exception. Access Request Full Duplex This scheme is used in a network with a full duplex base / master station and half duplex repeater /
remote stations. Full duplex Access Request utilizes the existing (half duplex) Access Request scheme as described in the section above. The base / master station can transmit while simultaneously receiving from the remote / repeaters. This increases Access Request efficiency, especially in the report by exception scheme (spontaneous messages). This feature can be operated on full duplex hardware only. If the Access Scheme is set to full duplex on a repeater, packets start to egress a repeater before the entire packet has been received by the repeater. This scheme reduces latency on long packets through a repeater and improves performance in Overlapping Coverage mode. To allow this new MAC scheme to operate, two new RF Network Detail parameters have been added; Base Station ID and Repeater Network Segment ID. Listen Before Send The Listen Before Send channel access scheme is realized using Carrier Sense Multiple Access (CSMA). In this mode, a pending transmission requires the channel to be clear. This is determined by monitoring the channel for other signals for a set time prior to transmission. This results in reduced collisions and improved channel capacity. There are still possibilities for collisions with this technique e.g. if two radios simultaneously determine the channel is clear and transmit at the same time. In this case an acknowledged transaction may be used. The transmitter requests an ACK to ensure that the transmission has been successful. If the transmitter does not receive an ACK, then random backoffs are used to reschedule the next transmission. Hop by Hop Transmission Hop by Hop Transmission is realized in the Aprisa SR+ by adding a MAC address header to the packet. For 802.15.4, there are 2 addresses, the source and destination addresses. Aprisa SR+ Product Description 1.6.0 80 | Product Architecture Adaptive Coding Modulation The Aprisa SR+ provides Adaptive Coding Modulation (ACM) which maximizes the use of the RF path to provide the highest radio capacity available. ACM automatically adjusts the modulation coding and FEC code rate in the remote to base direction of transmission over the defined modulation range based on the signal quality for each individual remote radio. When the RF path is healthy (no fading), modulation coding is increased and the FEC code rate is decreased to maximize the data capacity. If the RF path quality degrades, modulation coding is decreased and the FEC code rate is increased for maximum robustness to maintain path connectivity. Aprisa SR+ Product Description 1.6.0 Product Architecture | 81 Network Layer Packet Routing Aprisa SR+ is a standard static IP router which routes and forwards IP packet based on standard IP address and routing table decisions. Aprisa SR+ router mode (see figure below), enables the routing of IP packets within the Aprisa SR+ wireless network and in and out to the external router / IP RTUs devices connected to the Aprisa SR+ wired Ethernet ports. Within the Aprisa SR+ Router mode, each incoming Ethernet packet on the Ethernet port is stripped from its Ethernet header to reveal the IP packet and to route the IP packet based on its routing table. If the destination IP address is one of the RTUs, the packet is then forwarded to the wireless ports and broadcasted as a PMP wireless packet to all the repeater / remotes stations. The appropriate remote then routes the IP packet and forwards it based on its routing table to the appropriate Ethernet port, encapsulating the appropriate next hop MAC header and forwarding it to the RTU. The RTU can then interpret and process the IP data and communication is established between the RTU and the initiating communication device. Aprisa SR+ Product Description 1.6.0 82 | Product Architecture Static IP Router The Aprisa SR+ works in the point-to-multipoint (PMP) network as a standard static IP router with the Ethernet and wireless / radio as interfaces and serial ports using terminal server as a virtual interface. The Aprisa SR+ static router is semi-automated operation, where the routing table is automatically created in the base station and populated with routes to all remotes and repeater stations in the network during the registration process and vice versa, where the routing table is automatically created in remote and repeater stations and populated with routes to base station during the registration process. Updates occur when remote is disconnected from network for any reason, with the routing table updated in a controlled fashion. Also, in decommission operation, the base station routing tables are completely flushed allowing an automatic rebuild. This avoids the user manually inserting / removing of multiple static routes to build /
change the routes in the network which might be tedious and introduce significant human error. The Aprisa SR+ works as a static IP router without using any routing protocol and therefore does not have the overhead of a routing protocol for better utilization of the narrow bandwidth network. In addition to the semi-automated routes, the user can manually add / remove routes in the routing table for the radio interface, Ethernet Interface and for routers which are connected to the radio network. The Aprisa SR+ base station is used as a gateway to other networks. Thus, a configurable IP address default gateway can be set using a static route in the routing table with a destination IP address of the destination network address. It is recommended to use a real network IP address (actual device IP) for the gateway and not 0.0.0.0. The Aprisa SR+ sub-netting rules distinguish between the wireless interface and the remote Ethernet interface where RTUs are connected. The entire wireless network is set on a single IP subnet, while each Aprisa SR+ remotes Ethernet interface is set to a different subnet network. In this way, the user can easily distinguish between the remotes subnet IP addresses. Aprisa SR+ Product Description 1.6.0 Product Architecture | 83 The Radio Network as a Gateway Router The Aprisa SR+ point-to-multipoint radio network can be considered as a gateway router where the network Ethernet interface on each radio in the network is the router port. The routing table for all directly attached devices to the Aprisa SR+ network, at the Base or the Remote stations is automatically built and no static routes are required to be entered for those device routes. The Radio interface IP address is used internally for the radio network and automatic routes. It is not used when setting static routes or default gateways. Static route IP addresses or the default gateway should use the network Ethernet interface IP address. External network routers should be set with a high metric for the SR+ path, to prevent route updates being sent over the radio network. The Radio Network as a Router Example The purpose of this example is to determine the static route setting for router R2 in the base station and remote station in the following network. Since the Aprisa SR+ network should be considered as a router where the network Ethernet interface is the router port, the network configuration for setting the static routes or the default gateway IP addresses is described in the follow figure:
Thus, the static route setting for router R2 at the Aprisa SR+ base station and remote station will be:
Destination Address Destination Mask Gateway Address Static Route Setting at ?
192.168.3.0 192.168.3.0 255.255.255.0 192.168.2.1 Base station 255.255.255.0 192.168.2.2 Remote station Note: The radio network (base station and remote stations) will automatically build routes to the attached device e.g. SCADA Master station or attached router e.g. router R1 so static routes are not required for these devices. Aprisa SR+ Product Description 1.6.0 84 | Product Architecture Static IP Router Human Error Free To ensure correct operation, the Aprisa SR+ router base station alerts when one (or more) of the devices is not configured for router mode or a duplicated IP is detected when manually added. When the user changes the base station IP address / subnet, the base station sends an ARP unsolicited announcement message and the remotes / repeaters auto-update their routing table accordingly. This also allows the router that is connected to the base station to update its next hop IP address and its routing table. When the user changes the remote / repeater station IP address / subnet, a re-registration process in the base station then auto-updates its routing table accordingly. Terminal Server - Transition to Converged Ethernet / IP Network Customers that are transitioning their SCADA network to an Ethernet / IP SCADA network, can simultaneously operate their legacy serial RTUs, not as a separate serial network to the new Ethernet / IP network, but as part of the Ethernet / IP network, by using the terminal server feature. The Aprisa SR+ terminal server is an application running in the radio that encapsulates serial traffic into Ethernet / IP traffic. For SCADA networks, this enables the use of both serial and Ethernet / IP RTUs within an Ethernet / IP based SCADA network. Aprisa SR+ Product Description 1.6.0 Product Architecture | 85 Bridge Mode with VLAN Aware Ethernet VLAN Bridge / Switch Overview The Aprisa SR+ in Bridge mode of operation is a standard Ethernet Bridge based on IEEE 802.1d or VLAN Bridge based on IEEE 802.1q/p which forward / switch Ethernet packet based on standard MAC addresses and VLANs using FDB (forwarding database) table decisions. VLAN is short for Virtual LAN and is a virtual separate network, within its own broadcast domain, but across the same physical network. VLANs offer several important benefits such as improved network performance, increased security and simplified network management. The Aprisa SR+ Bridge mode (see figure below), is the default mode of operation and it enables the switching / bridging of Ethernet VLAN tagged or untagged packets within the Aprisa SR+ wireless network and in and out to the external Industrial LAN network and RTUs devices connected to the Aprisa SR+ wired Ethernet ports or serial ports through the terminal server function. Within the Aprisa SR+ Bridge mode, each incoming Ethernet packet is inspected for the destination MAC address (and VLAN) and looks up its FDB table for information on where to send the specific Ethernet frame. If the FDB table doesnt contain the specific MAC address, it will flood the Ethernet frame out to all ports in the broadcast domain and when using VLAN, the broadcast domain is narrowed to the specific VLAN used in the packet (i.e. broadcast will be done only to the ports which configured with that specific VLAN). The FDB table is used to store the MAC addresses that have been learnt and the ports associated with that MAC address. If the destination MAC address is one of the RTUs, the packet is then forwarded to the wireless ports and broadcast as a PMP wireless packet to all the repeater / remote stations. The appropriate remote then switches the Ethernet packet and forwards it based on its FDB table (based on the MAC or VLAN & MAC) to the appropriate Ethernet port to the RTU. The RTU can then interpret and process the Ethernet / IP data and communication is established between the RTU and the initiating communication device. Aprisa SR+ Product Description 1.6.0 86 | Product Architecture VLAN Bridge Mode Description General Aprisa SR+ VLAN Bridge The Aprisa SR+ works in a point-to-multipoint (PMP) network as a standard VLAN bridge with the Ethernet and wireless / radio as interfaces and serial ports using terminal server as a virtual interface. The Aprisa SR+ is a standard IEEE 802.1q VLAN bridge, where the FDB table is created by the bridge learning / aging process. New MACs are learnt and the FDB table updated. Unused MACs are aged out and flushed automatically after aging period. VLANs are statically configured by the user on the ports where a Virtual LAN is required across the radio network. An example of VLAN isolation of traffic type is shown in the figure below, where RTUs #1, 4 and 6 together with SCADA meter master form a Virtual LAN which is isolated from the other devices, even though they are on the same physical network. VLAN management can be used to manage with external NMS all the Aprisa SR+ devices on the radio network and is automatically created with a VLAN ID = 1 default value. The VLAN ID can be changed by the user later on. Each device in the Aprisa SR+ bridge is identified by its own IP address, as shown in the figure. Aprisa SR+ Product Description 1.6.0 Product Architecture | 87 VLANs Single, Double and Trunk VLAN ports The Aprisa SR+ supports single VLAN (CVLAN), double VLAN (SVLAN) and trunk VLAN. A single VLAN can be used to segregate traffic type. A double VLAN can be used to distinguish between Aprisa SR+ sub-networks (base-repeater-remote), where the outer SVLAN is used to identify the sub-network and the CVLAN is used to identify the traffic type. In this case, a double tagged VLAN will be forwarded across the Industrial LAN network and switched based on the SVLAN to the appropriate Aprisa SR+ sub-network. When packet enters the Aprisa SR+
network, the SVLAN will be stripped off (removed) and the forwarding will be done based on the CVLAN, so only a single VLAN will pass through over the radio network and double VLAN will be valid on the borders of the radio network. Trunk VLAN is also supported by the Aprisa SR+ where the user can configure multiple VLANs on a specific Ethernet port, creating a trunk VLAN port. For example, in the above figure, a single trunk VLAN port is created between the switch and the Aprisa SR+ base station, carrying VLAN ID #1, 20, 30 and 40. VLAN Manipulation Add / Remove VLAN Tags In order to support double VLAN and different device types connected to the Aprisa SR+ e.g. switches, RTUs, etc, which can be VLAN tagged or untagged / plain Ethernet devices, add / remove VLAN manipulation is required. In an Aprisa SR+ VLAN tagged network, a remote Aprisa SR+ connected to a plain RTU without VLAN support, will remove (strip-off) the VLAN tag from the packet before sending it to the RTU. On the other direction, when the RTU is sending an untagged packet, the Aprisa SR+ will add (append) an appropriate user pre-configure VLAN tag before sending it over the air to the base station. This is shown in the above figure on untagged RTU #5 and 7. QoS using VLAN VLANs carry 3 priority bits (PCP field) in the VLAN tag allowing prioritization of VLAN tagged traffic types with 8 levels of priority (where 7 is the highest priority and 0 is the lowest priority). The Aprisa SR+
supports QoS (Quality of Service) where the priority bits in the VLAN tagged frame are evaluated and mapped to four priority levels and four queues supported by the Aprisa SR+ radio. Packets in the queues are then scheduled out in a strict priority fashion for transmission over-the-air as per the priority level from high to low. Aprisa SR+ Product Description 1.6.0 88 | Product Architecture Avoiding Narrow Band Radio Traffic Overloading The Aprisa SR+ supports mechanisms to prevent narrowband radio network overload:
1. L3/L4 Filtering The L3 filtering can be used to block undesired traffic from being transferred on the narrow band channel, occupying the channel and risking the SCADA critical traffic. L3/4 filtering has the ability to block a known IP address and applications using TCP/IP or UDP/IP protocols with multiple filtering rules. The L3 (/L4) filter can block/forward (discard/process) a specific IP address and a range of IP addresses. Each IP addressing filtering rule set can also be set to filter a L4 TCP or UDP port/s which in most cases relates to specific applications as per IANA official and unofficial well-known ports. For example, filter and block E-
mail SMTP or TFTP protocol as undesired traffic over the SCADA network. The user can block a specific or range of IP port addresses, examples SMTP (Simple Mail Transfer Protocol) TCP port 25 or TFTP (Simple Trivial File Transfer Protocol) UDP port 69. 2. L2 Address Filtering L2 Filtering (Bridge Mode) provides the ability to filter radio link traffic based on specified Layer 2 MAC addresses. Destination MAC (DA) addresses and a Source MAC (SA) addresses and protocol type (ARP, VLAN, IPv4, IPv6 or Any type) that meet the filtering criteria will be transmitted over the radio link. Traffic that does not meet the filtering criteria will not be transmitted over the radio link. 3. L2 Port VLANs Ingress Filtering and QoS Double VLAN (Bridge Mode) Double VLAN is used to distinguish/segregate between different radio sub-networks (Base-repeaters-
remotes). Traffic with double VLANs which are not destined to a specific sub-network will be discarded on the ingress of the radio sub-network, avoiding the overload of the radio sub-network. Single VLAN (Bridge Mode) Single VLAN is used to distinguish/segregate between different traffic types assigned by the user in its industrial corporate LAN. In order to avoid the overload of the radio network, traffic with single VLANs which are not destined to a specific radio network will be discarded on the Ethernet ingress port of the radio network. All single VLANs which set and are eligible will be transmitted over the radio link. QoS using 802.1p priority bits (Bridge Mode) The priority bits can be used in the VLAN tagged frames to prioritized critical mission SCADA traffic and ensure SCADA traffic transmission relative to any other unimportant traffic. In this case, traffic based on VLAN priority (priority 0 to 7) enters one of the four priority queues of the Aprisa SR+ (Very High, High, Medium and Low). Traffic leaves the queues (to the radio network) from highest priority to lowest in a strict priority fashion. 4. Ethernet port QoS The Aprisa SR+ supports Ethernet Per Port Prioritization. Each Ethernet port can be assigned a priority and traffic shall be prioritized accordingly. This is quite useful in networks where customers do not use VLANs or cannot use 802.1p prioritization. Aprisa SR+ Product Description 1.6.0 Product Architecture | 89 5. Ethernet Data and Management Priority and Background Bulk Data Transfer Rate Alternatively to VLAN priority, users can control the Ethernet traffic priority (vs serial), management priority and rate in order to control the traffic load of the radio network, where important and high priority data (SCADA) will pass-through first assuring SCADA network operation. The user can set the use of the Ethernet Data Priority, which controls the priority of the Ethernet customer traffic relative to the serial customer traffic and can be set to one of the four queues. The Ethernet Management Priority controls the priority of the Ethernet management traffic relative to Ethernet customer traffic and can be set to one of the four queues. The Background Bulk Data Transfer Rate sets the data transfer rate (high, medium, low) for large amounts of management data. 6. Ethernet Packet Time to Live Another aspect of avoiding overload radio network is the Ethernet packet TTL, which is used to prevent old, redundant packets being transmitted through the radio network. This sets the time an Ethernet packet is allowed to live in the system before being dropped if it cannot be transmitted over the air. 7. Robust Header Compression (ROHC) and Payload Compression Aprisa SR+ supports ROHC (Robust Header Compression RFC3095). ROHC is a standard way to compress IP, UDP and TCP headers and this significantly increases IP traffic throughput especially in narrow band network. Aprisa SR+ supports payload compression. A LempelZiv (LZ) algorithm is used to efficiently compress up to 50% traffic with high percentage of repetitive strings. Both serial and Ethernet / IP payload traffic are compressed. Aprisa SR+ Product Description 1.6.0 90 | Product Architecture Product Architecture The following are the key components of the Aprisa SR+ design:
Dual high performance fractional-N synthesizers to allow for full duplex operation Wideband design electronically tunes over entire band Proven low noise and spurious technology with over 50dB of SNR easily achieved Power amplifier linearity Unique temperature compensated pre-distortion system improves the efficiency and linearity of the entire transmitter chain for non-constant envelope modulation systems Simple IQ modulation line up reduces part count and improves MTBF No mixing stages so no spurious responses present at the transmitter output Digital control loops used for controlling power amplifier current and transmit output power, allows for faster ramping and settling times with less error Tx turn-on time limited primarily by PA ramping Robust, closed-loop power control fast, accurate power ramp up and down Highly rugged N-Channel RF Power LDMOS transistors for the power amplifier High efficiency (>50% PAE at 10W) Very low thermal resistance (1.0C/W) Direct IQ down-conversion Excellent Intermodulation distortion characteristics as channel filter can be placed directly after the mixer without impacting noise figure Digital channel filtering allows for multiple bandwidths with the same hardware Low parts count and no crystal filters help to keep receiver performance extremely stable over temperature Integrated heat sink Limits number of mechanical interfaces Fin design optimized for natural convection Monitoring and software control Temperature control loop shuts down the transmitter when the temperature exceeds continuous operation at 70C Monitoring of RSSI and PA current to ensure the RF hardware is functioning to specification Aprisa SR+ Product Description 1.6.0 Aprisa SR+ Radio Block Diagram Product Architecture | 91 Aprisa SR+ Protected Station Block Diagram Aprisa SR+ Product Description 1.6.0 92 | Contact Us 7. Contact Us For further information or assistance, please contact Customer Support or your local 4RF representative. Our area representative contact details are available from our website:
4RF Limited 26 Glover Street, Ngauranga PO Box 13-506 Wellington 6032 New Zealand Email address Website Phone number Fax number Attention support@4rf.com www.4rf.com
+64 4 499 6000
+64 4 473 4447 Customer Services Aprisa SR+ Product Description 1.6.0
| frequency | equipment class | purpose | ||
|---|---|---|---|---|
| 1 | 2018-03-23 | 220 ~ 222 | TNB - Licensed Non-Broadcast Station Transmitter | Class II permissive change or modification of presently authorized equipment |
| 2 | 2014-08-15 | 220 ~ 222 | TNB - Licensed Non-Broadcast Station Transmitter | |
| 3 | 2014-04-09 | JBP - Part 15 Class B Computing Device Peripheral | Original Equipment | |
| 4 | 217 ~ 220 | TNB - Licensed Non-Broadcast Station Transmitter |
| app s | Applicant Information | |||||
|---|---|---|---|---|---|---|
| 1 2 3 4 | Effective |
2018-03-23
|
||||
| 1 2 3 4 |
2014-08-15
|
|||||
| 1 2 3 4 |
2014-04-09
|
|||||
| 1 2 3 4 | Applicant's complete, legal business name |
4RF Limited
|
||||
| 1 2 3 4 | FCC Registration Number (FRN) |
0021732375
|
||||
| 1 2 3 4 | Physical Address |
PO Box 13-506 Wellington 6440
|
||||
| 1 2 3 4 |
13-506
|
|||||
| 1 2 3 4 |
Wellington 6440, N/A
|
|||||
| 1 2 3 4 |
New Zealand
|
|||||
| app s | TCB Information | |||||
| 1 2 3 4 | TCB Application Email Address |
T******@TIMCOENGR.COM
|
||||
| 1 2 3 4 |
t******@timcoengr.com
|
|||||
| 1 2 3 4 | TCB Scope |
B2: General Mobile Radio And Broadcast Services equipment in the following 47 CFR Parts 22 (non-cellular) 73, 74, 90, 95, 97, & 101 (all below 3 GHz)
|
||||
| 1 2 3 4 |
A1: Low Power Transmitters below 1 GHz (except Spread Spectrum), Unintentional Radiators, EAS (Part 11) & Consumer ISM devices
|
|||||
| app s | FCC ID | |||||
| 1 2 3 4 | Grantee Code |
UIP
|
||||
| 1 2 3 4 | Equipment Product Code |
SQ215M141
|
||||
| app s | Person at the applicant's address to receive grant or for contact | |||||
| 1 2 3 4 | Name |
P**** Y****
|
||||
| 1 2 3 4 | Telephone Number |
+64 4********
|
||||
| 1 2 3 4 | Fax Number |
+64 4********
|
||||
| 1 2 3 4 |
p******@4rf.com
|
|||||
| app s | Technical Contact | |||||
| n/a | ||||||
| app s | Non Technical Contact | |||||
| n/a | ||||||
| app s | Confidentiality (long or short term) | |||||
| 1 2 3 4 | 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 | Long-Term Confidentiality Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?: | No | ||||
| if no date is supplied, the release date will be set to 45 calendar days past the date of grant. | ||||||
| app s | Cognitive Radio & Software Defined Radio, Class, etc | |||||
| 1 2 3 4 | Is this application for software defined/cognitive radio authorization? | No | ||||
| 1 2 3 4 | Equipment Class | TNB - Licensed Non-Broadcast Station Transmitter | ||||
| 1 2 3 4 | JBP - Part 15 Class B Computing Device Peripheral | |||||
| 1 2 3 4 | Description of product as it is marketed: (NOTE: This text will appear below the equipment class on the grant) | Digital Transceiver | ||||
| 1 2 3 4 | Point to Multi Point Digital Transceiver | |||||
| 1 2 3 4 | Class B computer peripheral | |||||
| 1 2 3 4 | VHF POINT TO MULTI POINT DIGITAL TRANSCEIVER | |||||
| 1 2 3 4 | Related OET KnowledgeDataBase Inquiry: Is there a KDB inquiry associated with this application? | No | ||||
| 1 2 3 4 | Modular Equipment Type | Does not apply | ||||
| 1 2 3 4 | Purpose / Application is for | Class II permissive change or modification of presently authorized equipment | ||||
| 1 2 3 4 | Original Equipment | |||||
| 1 2 3 4 | Composite Equipment: Is the equipment in this application a composite device subject to an additional equipment authorization? | Yes | ||||
| 1 2 3 4 | 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 | Grant Comments | Power listed is conducted. Maximum conducted output power is 5W according to 90.205(s). The antenna(s) used for this transmitter must be fixed mounted on outdoor permanent structures. Users must be provided with antenna installation and transmitter operating conditions for satisfying RF exposure compliance. The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 2.51 m from all persons. | ||||
| 1 2 3 4 | Power listed is conducted. Maximum conducted output power is 5W according to 90.205(s). The antenna(s) used for this transmitter must be fixed mounted on outdoor permanent structures. Users must be provided with antenna installation and transmitter operating conditions for satisfying RF exposure compliance. The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 2.5m from all persons. (Date of Grant: 04/09/2014) Class II Permissive Change: This Class II Permissive Change is to add the 220-222 MHz band for part 90. | |||||
| 1 2 3 4 | Power listed is conducted. Maximum conducted output power is 5W according to 90.205(s). The antenna(s) used for this transmitter must be fixed mounted on outdoor permanent structures. Users must be provided with antenna installation and transmitter operating conditions for satisfying RF exposure compliance. The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 2.5m from all persons. | |||||
| 1 2 3 4 | Is there an equipment authorization waiver associated with this application? | No | ||||
| 1 2 3 4 | 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 | Firm Name |
CELLTECH LABS INC.
|
||||
| 1 2 3 4 |
EMC Technologies NZ Ltd.
|
|||||
| 1 2 3 4 | Name |
B**** H****
|
||||
| 1 2 3 4 |
A******** C****
|
|||||
| 1 2 3 4 | Telephone Number |
250-7********
|
||||
| 1 2 3 4 |
64-9-********
|
|||||
| 1 2 3 4 | Fax Number |
250-7********
|
||||
| 1 2 3 4 |
64-9-********
|
|||||
| 1 2 3 4 |
b******@celltechlabs.com
|
|||||
| 1 2 3 4 |
a******@ihug.co.nz
|
|||||
| Equipment Specifications | |||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
| 1 | 1 | 95F | 218.00625 | 218.49375 | 5 | 0.96 ppm | 11K1G1D | ||||||||||||||||||||||||||||||||||
| 1 | 2 | 95F | 218.00625 | 218.49375 | 3.2 | 0.96 ppm | 11K1D1D | ||||||||||||||||||||||||||||||||||
| 1 | 3 | 95F | 218.507 | 218.99375 | 5 | 0.96 ppm | 11K1G1D | ||||||||||||||||||||||||||||||||||
| 1 | 4 | 95F | 218.507 | 218.99375 | 3.2 | 0.96 ppm | 11K1D1D | ||||||||||||||||||||||||||||||||||
| 1 | 5 | 95F | 218.0125 | 218.4875 | 5 | 0.96 ppm | 19K5G1D | ||||||||||||||||||||||||||||||||||
| 1 | 6 | 95F | 218.0125 | 218.4875 | 3.2 | 0.96 ppm | 19K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 7 | 95F | 218.5125 | 218.9875 | 5 | 0.96 ppm | 19K5G1D | ||||||||||||||||||||||||||||||||||
| 1 | 8 | 95F | 218.5125 | 218.9875 | 3.2 | 0.96 ppm | 19K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 9 | 8 | 216.0125 | 216.4875 | 5 | 0.96 ppm | 11K1G1D | ||||||||||||||||||||||||||||||||||
| 1 | 1 | 8 | 216.0125 | 216.4875 | 3.2 | 0.96 ppm | 11K1D1D | ||||||||||||||||||||||||||||||||||
| 1 | 11 | 8 | 216.0125 | 216.4875 | 5 | 0.96 ppm | 19K5G1D | ||||||||||||||||||||||||||||||||||
| 1 | 12 | 8 | 216.0125 | 216.4875 | 3.2 | 0.96 ppm | 19K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 13 | 8 | 216.5125 | 216.9875 | 5 | 0.96 ppm | 11K1G1D | ||||||||||||||||||||||||||||||||||
| 1 | 14 | 8 | 216.5125 | 216.9875 | 3.2 | 0.96 ppm | 11K1D1D | ||||||||||||||||||||||||||||||||||
| 1 | 15 | 8 | 216.5125 | 216.9875 | 5 | 0.96 ppm | 19K5G1D | ||||||||||||||||||||||||||||||||||
| 1 | 16 | 8 | 216.5125 | 216.9875 | 3.2 | 0.96 ppm | 19K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 17 | 8 | 217.0125 | 217.4875 | 5 | 0.96 ppm | 11K1G1D | ||||||||||||||||||||||||||||||||||
| 1 | 18 | 8 | 217.0125 | 217.4875 | 3.2 | 0.96 ppm | 11K1D1D | ||||||||||||||||||||||||||||||||||
| 1 | 19 | 8 | 217.0125 | 217.4875 | 5 | 0.96 ppm | 19K5G1D | ||||||||||||||||||||||||||||||||||
| 1 | 2 | 8 | 217.0125 | 217.4875 | 3.2 | 0.96 ppm | 19K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 21 | 8 | 217.5125 | 217.9875 | 5 | 0.96 ppm | 11K1G1D | ||||||||||||||||||||||||||||||||||
| 1 | 22 | 8 | 217.5125 | 217.9875 | 3.2 | 0.96 ppm | 11K1D1D | ||||||||||||||||||||||||||||||||||
| 1 | 23 | 8 | 217.5125 | 217.9875 | 5 | 0.96 ppm | 19K5G1D | ||||||||||||||||||||||||||||||||||
| 1 | 24 | 8 | 217.5125 | 217.9875 | 3.2 | 0.96 ppm | 19K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 25 | 8 | 219.0125 | 219.4875 | 5 | 0.96 ppm | 11K1G1D | ||||||||||||||||||||||||||||||||||
| 1 | 26 | 8 | 219.0125 | 219.4875 | 3.2 | 0.96 ppm | 11K1D1D | ||||||||||||||||||||||||||||||||||
| 1 | 27 | 8 | 219.0125 | 219.4875 | 5 | 0.96 ppm | 19K5G1D | ||||||||||||||||||||||||||||||||||
| 1 | 28 | 8 | 219.0125 | 219.4875 | 3.2 | 0.96 ppm | 19K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 29 | 8 | 219.5125 | 219.9875 | 5 | 0.96 ppm | 11K1G1D | ||||||||||||||||||||||||||||||||||
| 1 | 3 | 8 | 219.5125 | 219.9875 | 3.2 | 0.96 ppm | 11K1D1D | ||||||||||||||||||||||||||||||||||
| 1 | 31 | 8 | 219.5125 | 219.9875 | 5 | 0.96 ppm | 19K5G1D | ||||||||||||||||||||||||||||||||||
| 1 | 32 | 8 | 219.5125 | 219.9875 | 3.2 | 0.96 ppm | 19K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 33 | 9 | 216 | 217 | 5 | 1 ppm | 10K8G1D | ||||||||||||||||||||||||||||||||||
| 1 | 34 | 9 | 216 | 217 | 5 | 1 ppm | 17K8G1D | ||||||||||||||||||||||||||||||||||
| 1 | 35 | 9 | 216 | 217 | 5 | 1 ppm | 39K0G1D | ||||||||||||||||||||||||||||||||||
| 1 | 36 | 9 | 216 | 217 | 2 | 1 ppm | 10K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 37 | 9 | 216 | 217 | 2 | 1 ppm | 17K3D1D | ||||||||||||||||||||||||||||||||||
| 1 | 38 | 9 | 216 | 217 | 2 | 1 ppm | 39K0D1D | ||||||||||||||||||||||||||||||||||
| 1 | 39 | 9 | 217 | 220 | 5 | 1 ppm | 10K8G1D | ||||||||||||||||||||||||||||||||||
| 1 | 4 | 9 | 217 | 220 | 5 | 1 ppm | 17K8G1D | ||||||||||||||||||||||||||||||||||
| 1 | 41 | 9 | 217 | 220 | 5 | 1 ppm | 39K0G1D | ||||||||||||||||||||||||||||||||||
| 1 | 42 | 9 | 217 | 220 | 2 | 1 ppm | 10K4D1D | ||||||||||||||||||||||||||||||||||
| 1 | 43 | 9 | 217 | 220 | 2 | 1 ppm | 17K3D1D | ||||||||||||||||||||||||||||||||||
| 1 | 44 | 9 | 217 | 220 | 2 | 1 ppm | 39K0D1D | ||||||||||||||||||||||||||||||||||
| 1 | 45 | 9 | 220 | 222 | 5 | 0.24 ppm | 11K8G1D | ||||||||||||||||||||||||||||||||||
| 1 | 46 | 9 | 220 | 222 | 2 | 0.24 ppm | 11K6D1D | ||||||||||||||||||||||||||||||||||
| 1 | 47 | 9 | 220 | 222 | 2 | 0.24 ppm | 11K2D1D | ||||||||||||||||||||||||||||||||||
| Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
| 2 | 1 | 9 | 216 | 217 | 5 | 1 ppm | 10K8G1D | ||||||||||||||||||||||||||||||||||
| 2 | 2 | 9 | 216 | 217 | 5 | 1 ppm | 17K8G1D | ||||||||||||||||||||||||||||||||||
| 2 | 3 | 9 | 216 | 217 | 5 | 1 ppm | 39K0G1D | ||||||||||||||||||||||||||||||||||
| 2 | 4 | 9 | 216 | 217 | 5 | 1 ppm | 10K4D1D | ||||||||||||||||||||||||||||||||||
| 2 | 5 | 9 | 216 | 217 | 5 | 1 ppm | 17K3D1D | ||||||||||||||||||||||||||||||||||
| 2 | 6 | 9 | 216 | 217 | 5 | 1 ppm | 39K0D1D | ||||||||||||||||||||||||||||||||||
| 2 | 7 | 9 | 217 | 220 | 2 | 1 ppm | 10K8G1D | ||||||||||||||||||||||||||||||||||
| 2 | 8 | 9 | 217 | 220 | 2 | 1 ppm | 17K8G1D | ||||||||||||||||||||||||||||||||||
| 2 | 9 | 9 | 217 | 220 | 2 | 1 ppm | 39K0G1D | ||||||||||||||||||||||||||||||||||
| 2 | 1 | 9 | 217 | 220 | 2 | 1 ppm | 10K4D1D | ||||||||||||||||||||||||||||||||||
| 2 | 11 | 9 | 217 | 220 | 2 | 1 ppm | 17K3D1D | ||||||||||||||||||||||||||||||||||
| 2 | 12 | 9 | 217 | 220 | 2 | 1 ppm | 39K0D1D | ||||||||||||||||||||||||||||||||||
| 2 | 13 | 9 | 220 | 222 | 5 | 0.24 ppm | 11K8G1D | ||||||||||||||||||||||||||||||||||
| 2 | 14 | 9 | 220 | 222 | 5 | 0.24 ppm | 11K6D1D | ||||||||||||||||||||||||||||||||||
| 2 | 15 | 9 | 220 | 222 | 5 | 0.24 ppm | 11K2D1D | ||||||||||||||||||||||||||||||||||
| Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
| 3 | 1 | 15B | |||||||||||||||||||||||||||||||||||||||
| Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
| 4 | 1 | 9 | 216 | 217 | 5 | 1 ppm | 10K8G1D | ||||||||||||||||||||||||||||||||||
| 4 | 2 | 9 | 216 | 217 | 5 | 1 ppm | 17K8G1D | ||||||||||||||||||||||||||||||||||
| 4 | 3 | 9 | 216 | 217 | 5 | 1 ppm | 39K0G1D | ||||||||||||||||||||||||||||||||||
| 4 | 4 | 9 | 216 | 217 | 5 | 1 ppm | 10K4D1D | ||||||||||||||||||||||||||||||||||
| 4 | 5 | 9 | 216 | 217 | 5 | 1 ppm | 17K3D1D | ||||||||||||||||||||||||||||||||||
| 4 | 6 | 9 | 216 | 217 | 5 | 1 ppm | 39K0D1D | ||||||||||||||||||||||||||||||||||
| 4 | 7 | 9 | 217 | 220 | 2 | 1 ppm | 10K8G1D | ||||||||||||||||||||||||||||||||||
| 4 | 8 | 9 | 217 | 220 | 2 | 1 ppm | 17K8G1D | ||||||||||||||||||||||||||||||||||
| 4 | 9 | 9 | 217 | 220 | 2 | 1 ppm | 39K0G1D | ||||||||||||||||||||||||||||||||||
| 4 | 1 | 9 | 217 | 220 | 2 | 1 ppm | 10K4D1D | ||||||||||||||||||||||||||||||||||
| 4 | 11 | 9 | 217 | 220 | 2 | 1 ppm | 17K3D1D | ||||||||||||||||||||||||||||||||||
| 4 | 12 | 9 | 217 | 220 | 2 | 1 ppm | 39K0D1D | ||||||||||||||||||||||||||||||||||
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