Managing the Radio | 299 Protected Station: Maintenance > Licence This page provides the management and control of the Protected Station Maintenance Licence settings. PRIMARY / SECONDARY LICENCE See ‘Maintenance > Licence’ on page 216 for parameter details. Aprisa SR+ User Manual 1.6.
300 | Managing the Radio Protected Station: Maintenance > Advanced This page provides the management and control of the Protected Station Maintenance Advanced settings. NETWORK See ‘Maintenance > Advanced’ on page 217 for parameter details. RF Interface MAC address This parameter is only applicable when the radio is part of a Protected Station. This RF Interface MAC address is used to define the MAC address of the Protection Switch. This address is entered in the factory.
Managing the Radio | 301 PRIMARY / SECONDARY CONFIGURATION See ‘Maintenance > Advanced’ on page 217 for parameter details. PRIMARY / SECONDARY MAINTENANCE FILES See ‘Maintenance > Advanced’ on page 217 for parameter details. Aprisa SR+ User Manual 1.6.
302 | Managing the Radio Events The Events menu contains the setup and management of the alarms, alarm events and traps. Protected Station: Events > Alarm Summary There are two types of events that can be generated on the Aprisa SR+ radio. These are: 1. Alarm Events Alarm Events are generated to indicate a problem on the radio. 2. Informational Events Informational Events are generated to provide information on key activities that are occurring on the radio.
Managing the Radio | 303 Protected Station: Events > Primary History PRIMARY EVENT HISTORY See ‘Events > Event History’ on page 223 for parameter details. Aprisa SR+ User Manual 1.6.
304 | Managing the Radio Protected Station: Events > Secondary History SECONDARY EVENT HISTORY See ‘Events > Event History’ on page 223 for parameter details. Aprisa SR+ User Manual 1.6.
Managing the Radio | 305 Software The Software menu contains the setup and management of the system software including network software distribution and activation on a protected station. Single Radio Software Upgrade The radio software can be upgraded on a single radio single Aprisa SR+ radio (see ‘Single Radio Software Upgrade’ on page 362). This process would only be used if the radio was a replacement or a new station in an existing network.
306 | Managing the Radio Protected Station: Software > Summary This page provides a summary of the software versions installed on the radio, the setup options and the status of the File Transfers. PRIMARY / SECONDARY SOFTWARE VERSIONS See ‘Protected Station: Software > Primary File Transfer’ and ‘Protected Station: Software > Secondary File Transfer’ for parameter details. Aprisa SR+ User Manual 1.6.
Managing the Radio | 307 Protected Station: Software > Primary File Transfer This page provides the mechanism to transfer new software from a file source into the primary radio. SETUP FILE TRANSFER FOR PRIMARY UNIT Direction This parameter sets the direction of file transfer. In this software version, the only choice is ‘To Primary Radio’. Method This parameter sets the method of file transfer. Option Function Primary USB Transfer Transfers the software from the USB flash drive to the primary radio.
308 | Managing the Radio To transfer software into the Aprisa SR+ primary radio: Primary USB Transfer Method 1. Unzip the software release files in to the root directory of a USB flash drive. 2. Insert the USB flash drive into the primary radio host port . 3. Click on ‘Start Transfer’. 4. When the transfer is completed, remove the USB flash drive from the primary radio host port.
Managing the Radio | 309 Transfer from Secondary Unit 1. Select Transfer from Secondary Unit. 2. Click on ‘Start Transfer’. 3. Go to ‘Protected Station: Software > Manager’ on page 313 to activate the Software Pack. The radio will reboot automatically. If the file transfer fails, check the Event History page (see ‘Protected Station: Events > Secondary History’ on page 304) for more details of the transfer. Aprisa SR+ User Manual 1.6.
310 | Managing the Radio Protected Station: Software > Secondary File Transfer This page provides the mechanism to transfer new software from a file source into the secondary radio. SETUP FILE TRANSFER FOR SECONDARY UNIT Direction This parameter sets the direction of file transfer. In this software version, the only choice is ‘To Secondary Radio’. Method This parameter sets the method of file transfer.
Managing the Radio | 311 To transfer software into the Aprisa SR+ secondary radio: Secondary USB Transfer Method 1. Unzip the software release files in to the root directory of a USB flash drive. 2. Insert the USB flash drive into the secondary radio host port . 3. Click on ‘Start Transfer’. 4. When the transfer is completed, remove the USB flash drive from the secondary radio host port.
312 | Managing the Radio Transfer from Primary Unit 1. Select Transfer from Primary Unit. 2. Click on ‘Start Transfer’. 3. Go to ‘Protected Station: Software > Manager’ on page 313 to activate the Software Pack. The radio will reboot automatically. If the file transfer fails, check the Event History page (see ‘Protected Station: Events > Primary History’ on page 303) for more details of the transfer. Aprisa SR+ User Manual 1.6.
Managing the Radio | 313 Protected Station: Software > Manager This page summaries and manages the software versions available in the primary and secondary radios. The manager is predominantly used to activate new software on single radios. Network activation is performed with ‘Protected Station: Software > Remote Activation’. Both the previous software (if available) and Software Pack versions can be activated on each radio from this page.
314 | Managing the Radio PRIMARY / SECONDARY SOFTWARE PACK Version This parameter displays the software pack version available for distribution on base station and activate on all stations. Status This parameter displays the status of the software pack version. Option Function Available On the base station, the software pack is available for distribution. On all stations, the software pack is available for activation. Activating The software pack is activating in the radio.
Managing the Radio | 315 Protected Station: Software > Remote Distribution This page provides the mechanism to distribute software to all remote protected stations into the Aprisa SR+ network (network) and then activate it. The Software Pack loaded into the base station with the file transfer process (see ‘Protected Station: Software > Primary File Transfer’ on page 307) is distributed via the radio link to all remote stations from the active radio. The distribution process is monitored from this page.
316 | Managing the Radio Start Transfer This parameter when activated distributes (broadcasts) the new Software Pack to all remote stations in the network. Note: The distribution of software to remote stations does not stop customer traffic from being transferred. However, due to the volume of traffic, the software distribution process may affect customer traffic. Software distribution traffic is classified as ‘management traffic’ but does not use the Ethernet management priority setting.
Managing the Radio | 317 Pause Transfer This parameter when activated, pauses the Over the Air Transfer Process and shows the distribution status. The distribution process will continue from where it was paused with Resume Transfer. Cancel Transfer This parameter when activated, cancels the Over the Air Transfer Process immediately. During the distribution process, it is possible to navigate away from this page and come back to it to check progress. The SuperVisor session will not timeout.
318 | Managing the Radio Protected Station: Software > Remote Activation This page provides the mechanism to activate software on all remote protected stations. The Software Pack has been loaded into the base station with the file transfer process (see ‘Protected Station: Software > Primary File Transfer’ on page 307) and distributed via the radio link to all remote stations from the active radio.
Managing the Radio | 319 Activation Date & Time This parameter sets the Date & Time when the software pack activation will occur. This setting can be any future date and 24 hour time. Skip Confirmation Step This parameter when enabled skips the confirmation step during the activation process. Normally, the confirmation step will require use intervention to accept the confirmation which will halt the activation process.
320 | Managing the Radio The remote stations will be polled to determine which radios require activation: Result Function (X of Y) Remote Radios Polled for Partners X is the number of radios polled to determine the number of protected stations in the network. Y is the number of remote radios registered with the base station. Remote Radios Polled for New Version X is the number of radios polled to determine the number of radios that contain the new software version.
Managing the Radio | 321 When all the remote radios have been activated, the base station radio must now be activated with (see ‘Software > Manager’ on page 242). 4. Click on ‘OK’ to start the activation on the base station. Aprisa SR+ User Manual 1.6.
322 | Managing the Radio Command Line Interface The Aprisa SR+ has a Command Line Interface (CLI) which provides basic product setup and configuration. This can be useful if you need to confirm the radio’s IP address, for example. You can password-protect the Command Line Interface to prevent unauthorized users from modifying radio settings. This interface can be accessed via an Ethernet Port (RJ45), the Management Port (USB micro type B) or the USB host port with a USB converter to RS-232 convertor.
Managing the Radio | 323 3. Go to your computer device manager (Win 7: Control Panel > Administrative Tools > Computer Management > Device Manager) 4. Click on ‘Ports (COM & LPT)’ 5. Make a note of the COM port which has been allocated to the ‘Silicon Labs CP210x USB to UART Bridge’ (COM3 in the example below) 6. Open HyperTerminal or an alternative type of terminal Emulator program e.g. TeraTerm or Putty. HyperTerminal Example 7. Enter a name for the connection (Aprisa SR+ CLI for example) and click OK.
324 | Managing the Radio 8. Select the COM port from the Connect Using drop-down box that was allocated to the UART USB. 9. Set the COM port settings as follows: 10. Click OK. The HyperTerminal window will open. 11. Press the Enter key to initiate the session. 12. Login to the Aprisa SR+ CLI with a default Username ‘admin’ and Password ‘admin’. The Aprisa SR+ CLI menu is shown: Aprisa SR+ User Manual 1.6.
Managing the Radio | 325 CLI Commands To enter a CLI command: 1. Type the first few characters of the command and hit Tab. This auto completes the command. 2. Enter the command string and enter. Note: All CLI commands are case sensitive. The top level CLI command list is displayed by typing a ? at the command prompt.
326 | Managing the Radio Viewing the CLI Terminal Summary At the command prompt, type: cd APRISASR-MIB-4RF MPA APRISASR-MIB-4RF >>ls Terminal Changing the Radio IP Address with the CLI At the command prompt, type ‘set termEthController1IpAddress xxx.xxx.xxx.xxx’ Aprisa SR+ User Manual 1.6.
In-Service Commissioning | 327 8. In-Service Commissioning Before You Start When you have finished installing the hardware, RF and the traffic interface cabling, the system is ready to be commissioned. Commissioning the radio is a simple process and consists of: 1. Powering up the radios. 2. Configuring all radios in the network using SuperVisor. 3. Aligning the antennas. 4. Testing that the links are operating correctly. 5. Connecting up the client or user interfaces.
328 | In-Service Commissioning Antenna Alignment A base station omni-directional collinear antenna has a vertical polarization. The remote station yagi antennas must also have vertical polarization. Aligning the Antennas Align the remote station yagi antennas by making small adjustments while monitoring the RSSI. The Aprisa SR+ has a Test Mode which presents a real time visual display of the RSSI on the front panel LEDs.
Product Options | 329 9. Product Options Data Interface Ports The standard Aprisa SR+ provides multiple interface port options for combinations of Ethernet and RS-232 serial for a total of four interface ports i.e. port options of 2E2S, 3E1S or 4E0S, where E=Ethernet, S=Serial port. The product shown below is the two Ethernet ports plus two RS-232 serial ports.
330 | Product Options Protected Station The Aprisa SR+ Protected Station is fully monitored hot-standby and fully hot-swappable product providing radio and user interface protection for Aprisa SR+ radios. The RF ports and interface ports from the active radio are switched to the standby radio if there is a failure in the active radio.
Product Options | 331 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.
332 | Product Options Switching Criteria The Protected Station will switch-over operation from the active to the standby radio if any of the configurable alarm events occur, or if there is a loss of the ‘keep alive’ signal from the active radio. It is possible to configure the alarm events which will trigger the switch-over. It is also possible to prevent an alarm event triggering a switch-over through the configuration of blocking criteria.
Product Options | 333 Monitored Alarms The following alarms are monitored by default on the active / standby radio. The monitored alarms are dependent on the Protection Type selected.
334 | Product Options Protection Type All Protection Types Redundant Alarm Type Monitored on Active Radio Monitored on Standby Radio Modem FEC Disable Modem ACM Lock Alarm Input 1 Alarm Input 2 Monitored Hot Standby Monitored on Standby Radio TX Monitored on Standby Radio RX Protection Peer Comms Lost Protection Hardware Failure VDC Power Supply 3.3 Volts Power Supply 5.
Product Options | 335 Hardware Manual Lock The Hardware Manual Lock switch on the Protection Switch provides a manual override of the active / standby radio. When this lock is activated, the selected radio (A or B) becomes the active radio regardless of the Software Manual Lock and the current switching or block criteria. When the lock is deactivated (set to the Auto position), the protection will become automatic and switching will be governed by normal switching and blocking criteria.
336 | Product Options L2 / L3 Protection Operation The Aprisa SR+ Protected Station has selectable L2 Bridge or L3 Router modes, with VLAN, QoS and L2/3/4 address filtering attributes. Each Radio is configured with its own unique IP and MAC address and partner radio address. On switch-over failure, the new active radio sends out a gratuitous ARP to update the MAC learning tables / ARP tables of upstream bridge/router for appropriate traffic flow.
Product Options | 337 Antenna and Duplexer Options Option 1 - single antenna without a duplexer In this configuration, a single antenna is used and connected directly to the Aprisa SR+ Protected Station TX/ANT (A/B side) TNC port on the front panel. In this option Protected Station can operate in: Half duplex RF operation only If single frequency used, standby radio TX is OFF/Mute (as RX/TX on same connector).
338 | Product Options Option 3 - dual antenna without a duplexer In this configuration, antenna redundancy is supported with dual antennas connected to the Aprisa SR+ Protected Station TX/ANT (A/B side) and TX/ANT (B side) TNC ports on the front panel. In this option, the Protected Station can operate in: Half duplex RF operation only If single frequency used, standby radio RX (TX is off) can’t be monitored as it will receive the active TX.
Product Options | 339 Installation Mounting The Aprisa SR+ Protected Station is designed to mount in a standard 19 inch rack. Aprisa SR+ User Manual 1.6.
340 | Product Options Cabling The Aprisa SR+ Protected Station is delivered pre-cabled with power, interface, management and RF cables. There are two options for the pre-cabled Protected Station (see ‘Antenna and Duplexer Options’): 1. Standard Protected Station- suitable for options #1 and #2 (single antenna operation) Part Number Part Description APSQ-R400-SSC-HD-22-ENAA 4RF SR+, PS, 400-470 MHz, SSC, Half Duplex, 2E2S, EN, STD 2.
Product Options | 341 Users can change an existing Protected Station from one option to the other option by following the procedure: To change a pre-cabled Protected Station from one option to the other option: 1. Disconnect the power supply, antenna/s, interface cables and any other connections 2. Remove the Protected Station shelf from the rack 3. Turn the Protected Station shelf upside down 4. Remove the securing screws and remove the bottom panel 5. Unscrew the four coaxial cable clamp screws 6.
342 | Product Options 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.
Product Options | 343 Maintenance Changing the Protected Station IP Addresses To change the IP address of a Protected Station radio: 1. Change the IP address of either or both the Primary Radio and Secondary radio (see ‘Protected Station: IP > IP Setup’ on page 289). Changes in these parameters are automatically changed in the partner radio. Aprisa SR+ User Manual 1.6.
344 | Product Options Creating a Protected Station When a Protected Station is ordered from 4RF, it will be delivered complete with radios installed, precabled and pre-configured for Redundant operation. The following process will not be required. This process is to create a protected station from two individual SR+ radios and a new spare Aprisa SR+ Protection Switch. It assumes that the SR+ radios are currently setup for non-protected operation. 1.
Product Options | 345 Replacing a Faulty Power Supply Replacing one of the power supplies can be achieved without disruption to traffic. If a power supply has failed, the associated radio will have failed which will have caused the protection switch to switch-over to the other radio. It will not have switched back unless the power was restored and another problem occurred which caused a switch-over. 1.
346 | 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.
Product Options | 347 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.
348 | Product Options Installation Mounting The Aprisa SR+ Data Driven Protected Station is designed to mount in a standard 19” rack on two 1U rack mounting shelves (total of 3RU). Cabling The Aprisa SR+ Data Driven Protected Station is delivered with the radios, duplexers, rack mounting shelves and interconnect cables. The set of interconnect cables is available as a spare part. Part Number Part Description APST-XPSC-ST6 4RF SR+ Spare, Protection Switch Cables, Set Of 6 Aprisa SR+ User Manual 1.6.
Product Options | 349 Duplexer Kits The Aprisa SR+ product range contains Duplexer Kit accessories for use with Aprisa SR+ radios configured for Single Antenna Dual Port operation. Radio Duplexer Kits Example of part number: APSB-KDUP-400-B1-BR Part Number Description APSB-KDUP-135-N0-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.
350 | Product Options Part Number Description APSB-KDUP-928-G0-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 G0 Duplexer 900 MHz, s 40 MHz, p 7 MHz 2x TNC to SMA right angle 640mm cables APSB-KDUP-928-G2-BR-MM 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
Product Options | 351 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 Aprisa SR+ Duplexer Kit for a dual antenna SR+ Protected Station containing: 2x N0 Duplexer 135 MHz, s4.6 MHz, p0.
352 | Product Options Part Number Description APSB-KDUP-450-M0-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 M0 Duplexer 450 MHz, s 5 MHz, p 0.
Product Options | 353 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.
354 | Product Options USB RS-232 Cabling Options The following converter cables are available as Aprisa SR+ accessories to provide the customer interface. The kit contains a USB connector retention clip (see ‘USB Retention Clip’ on page 355). 1. USB Converter to 1.8 metre multi-strand cable 6 wire for termination of customer connector Part Number Part Description APSB-KFCA-USB-23-MS-18 4RF SR+ Acc, Kit, Interface, USB Conv, RS-232, Multi-strand, 1.8m 2.
Product Options | 355 USB Retention Clip The USB Retention Clip attaches to the underside of the Aprisa SR+ enclosure adjacent to the USB connector. To attach the USB Retention Clip: 1. Clean the enclosure surface where the retention clip will attach with an alcohol based cleaner e.g. Isopropanol. 2. Peel off the retention clip protective backing. 3. Stick the clip onto the Aprisa SR+ enclosure ensuring that it aligns to the middle of the radio USB connector. Aprisa SR+ User Manual 1.6.
Maintenance | 357 10. Maintenance No User-Serviceable Components There are no user-serviceable components within the radio. All hardware maintenance must be completed by 4RF or an authorized service centre. Do not attempt to carry out repairs to any boards or parts. Return all faulty radios to 4RF or an authorized service centre. For more information on maintenance and training, please contact 4RF Customer Services at support@4rf.com.
358 | Maintenance Software Upgrade A software upgrade can be performed on a single Aprisa SR+ radio or an entire Aprisa SR+ network. Network Software Upgrade This process allows customers to upgrade their Aprisa SR+ network from the central base station location without need for visiting remote sites. The Software Pack is loaded into the base station with the file transfer process (see ‘Software > File Transfer’ on page 238) and distributed via the radio link to all remote stations.
Maintenance | 359 4. Activate the software on the base station radio (see ‘Software > Manager’ on page 242). 5. When the new software has been activated, remote stations will re-register with the base station. The remote stations software version can verified with ‘Network Status > Network Table’ on page 271. 6. When the base station restarts with the new software, rediscover the nodes (see ‘Discover Nodes’ on page 218). 7.
360 | Maintenance Protected Network Upgrade Process This upgrade process is for upgrading the software on an entire Aprisa SR+ network from a protected base station. This software upgrade can be achieved without disruption to traffic. Transferring the new software to the radios The software can be transferred to the radio via an FTP transfer or from a USB flash drive. 1.
Maintenance | 361 Confirm that the new software version is now running on the radios 1. Re-login into the Protection Station and navigate to SuperVisor > Software>Summary. 2. Confirm that the Primary and Secondary radio current software version is now up to date 3. Confirm that the list of remote radios are now running the latest software version with ‘Network Status > Network Table’ on page 271. 4.
362 | Maintenance Single Radio Software Upgrade This upgrade process is for upgrading the software on a single Aprisa SR+ radio. Note: If a radio has been configured for a Protection Type of ‘Redundant’, and that radio is no longer part of a Protected Station, the Protection Type must be changed to ‘None’ before the radio software upgrade can be achieved.
Maintenance | 363 USB Boot Upgrade Method A single Aprisa SR+ radio can also be upgraded simply by plugging a USB flash drive containing the new software into the USB A host port on the Aprisa SR+ front panel and power cycling the radio. To upgrade the Aprisa SR+ radio software: 1. Unzip the software release files in to the root directory of a USB flash drive. 2. Check that the SuperVisor USB Boot Upgrade setting is set to ‘Load and Activate’ (see ‘Software > Setup’ on page 237). 3.
364 | Maintenance Protected Station Software Upgrade This upgrade process is for upgrading the software on a single Aprisa SR+ Protected Station. USB Boot Upgrade Method Assuming the Primary radio is active and the Secondary radio is standby 1. Using the Hardware Manual Lock switch, force the primary radio to active. 2. Insert the USB flash drive with the new software release into the secondary radio host port . 3. Power cycle the secondary radio. The radio will be upgraded with the new software. 4.
Interface Connections | 365 11.
366 | Interface Connections RS-232 Serial Interface Connections RS-232 Pinout The Aprisa RS-232 Serial Interface is always configured as a DCE: RJ45 Pin Number Pin Function Direction TIA-568A Wire Colour TIA-568B Wire Colour 1 RTS Input Green / white Orange/white 2 DTR / Sleep Mode Input Green Orange 3 TXD Input Orange / white Green/white 4 Ground Blue Blue 5 DCD Output Blue / white Blue/white 6 RXD Output Orange Green 7 DSR Output Brown / white Brown/white 8 CTS Ou
Interface Connections | 367 Alarm Interface Connections RJ45 Pin Number Pin Function Direction TIA-568A Wire Colour TIA-568B Wire Colour 1 Alarm 1 Input / sleep control Input Green / white Orange/white 2 Ground Green Orange 3 Alarm 2 Input Orange / white Green/white 4 Ground Blue Blue 5 Alarm 1 Output Blue / white Blue/white 6 Ground Orange Green 7 Alarm 2 Output Brown / white Brown/white 8 Ground Brown Brown Input Output Output Note: The TIA-568B wiring is the most c
368 | Alarm Types and Sources 12. Alarm Types and Sources Alarm Types There are three types of alarm event configuration types: 1. Threshold Type These alarm events have lower and upper limits. An alarm is raised if current reading is outside the limits. Note: the limits for PA Current, TX AGC, TX Reverse Power and Thermal shutdown are not user configurable. 2. Error Ratio Type This is the ratio of bad packets vs total packets in the defined sample duration.
Alarm Types and Sources | 369 Alarm Events Transmitter Alarm Events Event ID Event Display Text Default Severity Configuration Type Function Recommended Actions 1 PA Current critical(1) Threshold Type Alarm to indicate that the current drawn by the transmitter power amplifier is outside defined limits. Check antenna is not open or shorted, check duplexer correctly connected and tuned, if OK replace radio.
370 | Alarm Types and Sources Radio Interface Path Alarm Events Event ID Event Display Text Default Severity Configuration Type Function Recommended Actions 34 RF No Receive Data warning(4) Sample Duration Type Alarm to indicate that there is no data received on the RF path in the defined duration period. Check master is operational. If new deployment check setup, frequencies, and duplexer (if used). Check antenna is not open or shorted. If the antenna is directional check for offpointing.
Alarm Types and Sources | 371 Event ID Event Display Text Default Severity Configuration Type Function Recommended Actions 45 Port 3 Eth Data Receive Errors warning(4) Error Ratio Type Alarm to indicate that Ethernet port 3 received input signal contains errors at a higher rate than the defined error rate threshold. Check Ethernet cable and connector. Check switch port or RTU is active. Check IP and VLAN configuration.
372 | Alarm Types and Sources Hardware Alarm Events Event ID Event Display Text Default Severity Configuration Type Function Recommended Actions 56 VDC Power Supply warning(4) Not Configurable Alarm to indicate that the input power source is outside the operating limits of 10 to 30 VDC Check DC connection to radio. Replace power supply. 57 3.3 Volts Power Supply warning(4) Not Configurable Alarm to indicate that the 3.3 volt power rail is outside defined limits.
Alarm Types and Sources | 373 Protected Station Alarm Events Event ID Event Display Text Default Severity Configuration Type Function Recommended Actions 17 Protection Sw Manual Lock warning(4) Not Configurable Alarm to indicate that the Protection Switch Software Manual Lock has been activated. Information only. 18 Protection Hw Manual Lock warning(4) Not Configurable Alarm to indicate that the Protection Switch Hardware Manual Lock has been activated.
374 | Alarm Types and Sources Informational Events Event ID Event Display Text Default Severity Function Recommended Actions 26 User authentication succeeded information (5) Event to indicate that a user is successfully authenticated on the radio during login. The information on the user that was successfully authenticated is provided in the eventHistoryInfo object of the Event History Log.
Specifications | 375 13. 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 Range Synthesizer Step Size VHF 135 MHz 135-175 MHz 0.625 kHz UHF 220 MHz 215-240 MHz 0.625 kHz UHF 320 MHz 320-400 MHz 6.
376 | Specifications 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.
Specifications | 377 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 84.0 kbit/s 56.0 kbit/s 28.0 kbit/s 9.6 kbit/s 25 kHz 120.0 kbit/s 80.0 kbit/s 40.0 kbit/s 19.2 kbit/s 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.
378 | Specifications 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 216.0 kbit/s 144.0 kbit/s 72.0 kbit/s 38.4 kbit/s 50 kHz (1) 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.
Specifications | 379 FCC Compliant FCC: 135 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 15 kHz 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 30 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 15 kHz 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 30 kHz 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.
380 | Specifications 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 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 25 kHz 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 50 kHz 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.
Specifications | 381 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 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 50 kHz (1) 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.
382 | Specifications 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.
Specifications | 383 FCC: 700 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 16 QAM QPSK 25 kHz 120.0 kbit/s 80.0 kbit/s 40.0 kbit/s 19.2 kbit/s 50 kHz 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 75 kHz (1) 4-CPFSK (2) 64 QAM Minimum Coded Forward Error Correction Channel Size Gross Radio Capacity less FEC 16 QAM QPSK 25 kHz 103.9 kbit/s 46.2 kbit/s 23.1 kbit/s 16.7 kbit/s 50 kHz 207.
384 | Specifications 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 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 50 kHz 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 83.
Specifications | 385 IC Compliant IC: 135 MHz Band No Forward Error Correction Channel Size Gross Radio Capacity 64 QAM 16 QAM QPSK 4-CPFSK 15 kHz 54.0 kbit/s 36.0 kbit/s 18.0 kbit/s 9.6 kbit/s 30 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 15 kHz 46.8 kbit/s 20.8 kbit/s 10.4 kbit/s 8.4 kbit/s 30 kHz 83.1 kbit/s 37.0 kbit/s 18.5 kbit/s 16.
386 | Specifications 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 60.0 kbit/s 40.0 kbit/s 20.0 kbit/s 9.6 kbit/s 25 kHz 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 50 kHz 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.
Specifications | 387 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 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 50 kHz (1) 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.
388 | Specifications 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 96.0 kbit/s 64.0 kbit/s 32.0 kbit/s 19.2 kbit/s 50 kHz 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 83.
Specifications | 389 Receiver Receiver Sensitivity 12.
390 | Specifications Adjacent Channel Selectivity Adjacent channel selectivity 12.5 kHz 25 kHz 50 kHz 75 kHz > -47 dBm > -37 dBm > -37 dBm > -37 dBm BER < 10 -2 64 QAM > 43 dB > 53 dB > 53 dB > 53 dB BER < 10 -2 16 QAM > 43 dB > 53 dB > 53 dB > 53 dB QPSK > 48 dB > 58 dB > 58 dB > 58 dB 4-CPFSK > 55 dB > 65 dB > 65 dB > 65 dB 12.
Specifications | 391 Spurious Response Rejection Spurious response rejection 12.5 kHz 25 kHz 50 kHz 75 kHz > -32 dBm > -32 dBm > -32 dBm > -32 dBm BER < 10 -2 64 QAM > 58 dB > 58 dB > 58 dB > 58 dB BER < 10 -2 16 QAM > 58 dB > 58 dB > 58 dB > 58 dB QPSK > 63 dB > 63 dB > 63 dB > 63 dB 4-CPFSK > 70 dB > 70 dB > 70 dB > 70 dB 12.
392 | Specifications Transmitter Max peak envelope power (PEP) Average Power output 12.5 W (+41 dBm) 64 QAM 0.01 to 2.5 W (+10 to +34 dBm, in 1 dB steps) 16 QAM 0.01 to 3.2 W (+10 to +35 dBm, in 1 dB steps) QPSK 0.01 to 5.0 W (+10 to +37 dBm, in 1 dB steps) 4-CPFSK (Note 1) 0.01 to 10.
Specifications | 393 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 Counter Mode Encryption (CTR) using Advanced Encryption Standard (AES) 128, 192 or 256 Data authentication Cipher Block Chaining Message Authentication Code (CBC-MAC) using Advanced Encryption Standard (AES) 128, 192 or 256 Apris
394 | 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.
Specifications | 395 RS-232 Asynchronous Interface The Aprisa SR+ radio’s 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.
396 | 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.
Specifications | 397 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 Nominal voltage Absolute input voltage range 13.8 VDC 48 VDC +13.
398 | 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 Transmit / Receive < 35 W for 10 W transmit peak power < 25.0 W for 1 W transmit power Receive only Standard Power Optimized <7W < 3 W in active receive state < 2 W in idle receive state < 0.
Specifications | 399 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 Dimensions Width 210 mm (8.27”) Depth 130 mm (5.12”) and 146 mm (5.748”) with TNC connectors Height 41.5 mm (1.63”) Weight 1.25 kg (2.
400 | Specifications Compliance ETSI Radio EN 300 113-2 EMI / EMC EN 301 489-1 and 5 Safety EN 60950-1:2006 Class 1 division 2 for hazardous locations Environmental ETS 300 019 Class 3.4 Ingress Protection IP51 Radio 47CFR part 24, part 27, part 90 and part 101 Private Land Mobile Radio Services EMC 47CFR part 15 Radio Frequency Devices, EN 301 489-1 and 5 Safety EN 60950-1:2006 Class 1 division 2 for hazardous locations Environmental ETS 300 019 Class 3.
Product End Of Life | 401 14. Product End Of Life 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.
402 | Copyrights 15. Copyrights Mirrored Bits® is a registered trademark of Schweitzer Engineering Laboratories, Inc Aprisa SR+ User Manual 1.6.
Abbreviations | 403 16.
