Event HD User Reference and Installation Manual Document Number: 602-14886-01, Rev. A Date: OCTOBER, 2007 © 2006 Moseley, Inc. All Rights Reserved. This book and the information contained herein is the proprietary and confidential information of Moseley, Inc. that is provided by Moseley exclusively for evaluating the purchase of Moseley, Inc. technology and is protected by copyright and trade secret laws.
ii No part of this document may be disclosed, reproduced, or transmitted in any form or by any means, electronic or mechanical, for any purpose without the express written permission of Moseley, Inc. For permissions, contact Moseley Marketing Group at 1-805-968-9621 or 1-805-685-9638 (FAX). Notice of Disclaimer: The information and specifications provided in this document are subject to change without notice. Moseley, Inc.
iii Table of Contents 1. SAFETY PRECAUTIONS...................................................................................1 2. SYSTEM DESCRIPTION...................................................................................1 2.1 About This Manual...........................................................................................1 2.2 Introduction....................................................................................................1 2.3 System Features..........................
iv 3.8.3 Grounding the SDIDUTM...........................................................................26 3.8.4 Connecting the SDIDUTM to the PC and Power Source..................................26 3.8.5 SDIDU™ Configuration..............................................................................27 3.8.6 ODU Antenna Alignment............................................................................30 3.8.7 Quick Start Settings .......................................................................
v FIGURE 2-9. 1+1 PROTECTION IN NON-DIVERSITY MODE...............................23 FIGURE 2-10. 1+1 PROTECTION IN DIVERSITY MODE.....................................23 FIGURE 2-11. 1 + 1 MULTI-HOP REPEATER CONFIGURATION..........................25 FIGURE 2-12. CROSSPOINT SWITCH................................................................26 FIGURE 2-13. (A) CROSSPOINT SWITCH USED A PASSTHROUGH IN REPEATER CONFIGURATION. (B) CROSSPOINT SWITCH ALLOWS ACCESS FOR ADD/DROP. 27 FIGURE 2-14.
vi FIGURE 3-24. THREADED HOLE LOCATIONS.....................................................34 FIGURE 3-25. GUIDES......................................................................................35 List of Tables TABLE 2-1. KEY BENEFITS AND ADVANTAGES OF THE EVENT-HD RADIOS.........3 TABLE 2-4. DVB-ASI OUTPUT STATUS LED......................................................11 © 2007 Moseley, Inc. All Rights Reserved. 602-14886-01, Rev.
vii © 2007 Moseley, Inc. All Rights Reserved. 602-14886-01, Rev.
1. Safety Precautions 1 1.Safety Precautions PLEASE READ THESE SAFETY PRECAUTIONS! RF Energy Health Hazard This symbol indicates a risk of personal injury due to radio frequency exposure. The radio equipment described in this guide uses radio frequency transmitters. Do not allow people to come in close proximity to the front of the antenna while the transmitter is operating.
2 1. Safety Precautions Risk of Personal Injury from Fiber Optics DANGER: Invisible laser radiation. Avoid direct eye exposure to the end of a fiber, fiber cord, or fiber pigtail. The infrared light used in fiber optics systems is invisible, but can cause serious injury to the eye. WARNING: Never touch exposed fiber with any part of your body. Fiber fragments can enter the skin and are difficult to detect and remove. Warning – This is a Class A product WARNING: This is a Class A product.
2. System Description 1 2.System Description 2.1About This Manual This manual is written for those who are involved in the “hands-on” installation of the EVENT HD in a microwave point-to-point link, such as installation technicians, site evaluators, project managers, and network engineers. It assumes the reader has a basic understanding of how to install hardware, use Windows based software, and operate test equipment. 2.
2 2. System Description MPEG / HDTV Decoder MPEG / HDTV Encoder ENG VAN Studio Figure 2-1. Typical Broadcast ENG Application Unlicensed high-capacity full-duplex data and broadcast applications for data rates to 100 Mbps, 5.3 GHz band between 5.25 to 5.35 GHz for U-NII in 13, 20, and 30 MHz channels. 5.8 GHz band between 5.725 to 5.850 GHz for ISM in 12.5, 16.7, 25, and 30 MHz channels. Licensed high-capacity full-duplex data and broadcast applications for data rates to 100 Mbps, 2/2.
2. System Description 3 ring-type architecture. This ring or consecutive point radio architecture is self-healing in the event of an outage in the link and automatically re-routes data traffic, thereby ensuring that service to the end user is not interrupted. The Event HD digital radios enable network operators (mobile and private), government and access service provides to offer a portfolio of secure, scalable wireless applications for data, video, and Voice over IP (VoIP).
4 2. System Description Benefits Advantages to Providers/Customers Reference Fast return on investment. 3.1, 3.4, 3.6 Easy to install units Straightforward modular system enables fast deployment and activation. No monthly leased line fees. Carrier-class reliability. Complete support of payload capacity with additional voice orderwire Aggregate capacity beyond basic network payload. Scalable and spectrally efficient system. Separate networks for radio overhead/management and user payload.
2. System Description 5 Benefits Advantages to Providers/Customers Reference A graphical user interface offers security, configuration, fault, and performance management via standard craft interfaces. Simplifies management of radio network and minimizes resources as entire network can be centrally managed out of any location. 2.5, 2.8 Suite of SNMP-compatible network management tools that provide robust local and remote management capabilities.
6 2. System Description Powerful Trellis Coded Modulation concatenated with Reed-Solomon Error Correction Built-in Adaptive Equalizer Support of Voice Orderwire Channels Adaptive Power Control Standard high-power feature at antenna port o 5W (37 dBm) in 2 GHz bands o 1W (30 dBm) in 5.
2. System Description 7 2.4.1Model Types The following model types are available with associated ODU configuration: Product Name Band 1. Event 2200 1990-2110 Primary Data Interfaces ASI 10-100 Mbps Ethernet 2 Mbps 16xE1/T1 2025-2150 2xEthernet 2. Event 2200 FD 16xE1/T1 2200-2300 2xEthernet 3. Event 2500 4. Event 5300 2450-2500 5250-5350 Ethernet 2 Mbps 16xE1/T1 up to 100 Mbps 2xEthernet 6. Event 6500 7. Event 6800 6425-6525 6525-6875 9.
8 2. System Description 2.4.2Front Panel All models of the Event HD are available with an optional front panel to perform primary configuration functions such as change frequency and monitor receiver status and radio health parameters. The panel is shown in Figure 2-2. Figure 2-2. Event-HD front panel (optional) The menu structure is navigated with the arrow keys, using the “check” key to enter, and the X key to escape (go back one level).
2. System Description 9 Configuration ODU Control ODU Channel Administration ODU Control Str Tx Pwr:x.xxxxx Mute :xxxxxx State :xxxxxx ODU Channel Link Loopback Administration xxxx days xxh:xxm FP Network IDU Network Link Freq:x.xxxxxx Link:QPSK-10.5Mbaud dataR=BaudR*mod FP Network IP :xxx.xxx.xxx.xxx Mask:xxx.xxx.xxx.xxx GW :xxx.xxx.xxx.xxx Loopback Type:combo of 3 LIU: combo Duration: combo IDU Network IP :xxx.xxx.xxx.xxx Mask:xxx.xxx.xxx.xxx GW :xxx.xxx.xxx.
10 2. System Description DVB-ASI In Status LED Controller Status LED Power/ Fault LED Ethernet/ E1/T1 Status LED Modem Status LED DVB-ASI Out Status LED Figure 2-2. Software Defined IDU™ LEDs: SDIDUTM Rear Panel Configuration for Software Defined IDU™, 1+0 Configuration The modem status LED indicates the modem status as described in Table 2-2. Table 2-2. Modem status LED.
2. System Description 11 Table 2-3. DVB-ASI Input status LED. LED STATUS GREEN Good ASI input RED No ASI input Alternating YELLOW/GRN ASI exceeds radio bit rate (FIFO overflow) Flashing RED Loss-of-Frame Flashing GRN No ASI data Table 2-4. DVB-ASI Output status LED.
12 2. System Description The standard I/O and modem status LEDs are set to red when certain alarms are posted. A complete list of alarms is provided in Appendix 6.1. H The alarm description is also displayed in the Graphical User Interface (GUI) as described in the User Interface Reference Manual. 2.4.4Rear Panel Connections Refer to the Figure 2-3 for an example of a Software Defined IDU™ rear panel followed by a description of the connections.
2. System Description 13 Power Supply Input DC Input -48 VDC 48v (Isolated Input); 2-pin captive power connector. The Software Defined IDU™ requires an input of 48 volts dc ±10% at the rear panel DC Input connector. The total required power is dependent on the option cards and protection configuration (1+0, 1+1). The SDIDUTM rear panel power connector pin numbering is 1 through 2, from left to right, when facing the unit rear panel.
14 2. System Description Alarm/Serial Interface Alarms/Serial DB-15HD female connector for two Form-C relay alarm outputs (rated load: 1A @ 24 VDC), two TTL alarm outputs, four TTL alarm inputs, and Serial Console. The two Form-C relay alarm outputs can be configured to emulate TTL alarm outputs. USB Interface USB USB connector, reserved. Voice Orderwire Connector Call Button The voice orderwire provides a PTP connection via a PTT handset and buzzer. The call button initiates a ring.
2. System Description 15 DVB/ASI, DS-3, E-3, and STS-1Connection (Optional Mini IO) DVB/ASI Out BNC connector for the DVB/ASI digital video and DS-3, E-3, and STS-1 interface. DVB/ASI In BNC connector for the DVB/ASI digital video and DS-3, E-3, and STS-1 interface. OC-3 Connection (Optional Mini IO) OC-3 Out OC-3 type SC connectors for the OC-3 interface. OC-3 In OC-3 type SC connectors for the OC-3 interface. STM-1 Connection (Optional Mini IO) STM-1Out BNC connector for the STM-1 interface.
16 2. System Description The upper RSL LED meter is calibrated to represent exactly 10 dB for each LED, going from -95 dBm at the far left (red) to -15 dBm at the far right (green). The brightness of each LED is modulated for levels between 0 to 10 dB such that the far left LED will be fully extinguished at -95 dBm and the far right LED will be fully illuminated at -15 dBm. When the RSL is in the red region (<-75 dBm) the signal level is approaching or has reached threshold (depends on modulation type).
2. System Description 17 IDU IDU CONTROLLER CPU RCH Serial SNMP 2x 100Base-Tx Switch 2x 100 Mbps User 2x 100Base-Tx Switch 16x 1.544/2.048 Mbps 16 T1/E1 2x 100 Mbps Modem Control Telemetry Serial East/Primary Modem Quad Mux Digital IF MODEM/ FEC ASIC Multiplexed IF -48Vdc 64 kbps Voice West/Secondary Modem Standard I/O Cards Optional I/O Cards (Small Slot) Up to 150 Mbps DVB-ASI 4x44.736/34.368/ 51.84 Mbps DS-3/ES/ STS-1 2x 155.52 Mbps 2xSTM-1/ OC3 4x44.736/34.368/ 51.
18 2. System Description The Event-HD ODU RF Up/Down Converter provides the interface to the antenna. The transmit section up converts and amplifies the modulated Intermediate Frequency (IF) of 350 MHz from the IF Processor and provides additional filtering. The receive section down converts the received signal, provides additional filtering, and outputs an IF of 140 MHz to the IF Processor.
2. System Description 19 carrier. The multiplexer function is built into an appliqué that resides in the Modem/IF Module. Two modems can be used for 1+1 protection or ring architectures. • Power Supply – The Event-HD power supply accepts 48 Vdc and supplies the SDIDUTM and ODU with power. A second redundant power supply may be added as an optional module. The Modem Processor and its associated RAM, ROM, and peripherals control the digital and analog operation.
20 2. System Description Figure 2-6. Ring Configuration SONET/SDH rings are inherently self-healing. Each ring has both an active path and a standby path. Network traffic normally uses the active path. If one section of the ring fails, the network will switch to the standby path. Switchover occurs in seconds. There may be a brief delay in service, but no loss of payload, thus maintaining high levels of network availability.
2. System Description 21 Figure 2-7. Consecutive Point Network 2.72 + 0 (East-West) Configuration The Event-HD supports a 2+0, or east-west, configuration that allows a consecutive point architecture to be achieved with only a single 1 RU chassis at each location. In this configuration the SDIDUTM contains two modems and may contain two power supplies. One modem is referred to as the west modem and the other as the east modem.
22 2. System Description Connected to east modem Connected to west modem Connected to west modem Connected to west modem Connected to east modem Connected to east modem Connected to east modem Connected to west modem Figure 2-8. 2 + 0 (East West) Configuration 2.8Spanning Tree Protocol (STP) Spanning Tree Protocol (STP) keeps Ethernet loops from forming in a ring architecture. Without STP, loops would flood a network with packets. STP prevents loops by creating an artificial network break.
2. System Description 23 mode does not require the extra bandwidth or interference protection. It provides hitless receive switching and hot standby. The SDIDUTM automatically switches transmit ODU upon appropriate ODU alarm or ODU interface error, minimizing transmit outage time. Connected to west modem Connected to west modem Connected to east modem Connected to east modem Figure 2-9. 1+1 Protection in Non-Diversity Mode 2.9.
24 2. System Description 2.9.2.2 Spatial Diversity In spatial diversity, two non-interfering paths are used. The proprietary framer chooses the best, or error-free, data stream and forwards it to the Line Interface Units (LIUs). 2.9.2.2.1Single Transmitter Protected Non-Diversity, or Hot Standby, is also referred to as Single Transmitter Spatial Diversity. For more information on this mode, see Section 2.9.1. 2.9.2.2.
2. System Description 25 Protected Link Protected Link Data drop/insert Data drop/insert Data drop/insert Protected Link Protected Link Data drop/insert Figure 2-11. 1 + 1 Multi-Hop Repeater Configuration 2.11Data Interfaces The primary interface for video and broadcast applications is the DVB-ASI interface located in the mini-I/O card slot. Alternatively this interface can be replaced with STM-1 Optical/OC-3 or STM-1 Electrical interfaces. The optical interface is single mode at 1300 nm.
26 2. System Description 2.12Crosspoint Switch The SDIDU™ crosspoint switch provides any-to-any E1/T1 routing between rear panel ports and RF links, as shown in Figure 2-12. Flexible channel mapping allows selection from predefined routings or custom routing. Custom routings are uploaded to the SDIDU™ via FTP. Two examples of the crosspoint capability are to use the crosspoint switch to configure a repeater or an add/drop. These examples are shown in Figure 2-13.
2. System Description 27 Repeater Example Add/Drop Example Up to 32 E1 Up to 32 E1 Modem East Framer IO Up to 16E1 Modem West Crosspoint Switch Up to 32 E1 Up to 32 E1 Modem East Framer Optional IO Up to 16E1 IO Up to 16E1 Modem West Crosspoint Switch Optional IO Up to 16E1 Figure 2-13. (a) Crosspoint Switch used a passthrough in repeater configuration. (b) Crosspoint Switch allows access for add/drop. 2.
28 2. System Description In response to the need for a high-density deployment model the Event-HD uses a unique power control technique called AdTPC. AdTPC enables Event-HD to transmit at the minimum power level necessary to maintain a link regardless of the prevailing weather and interference conditions. The Event-HD is designed and manufactured to not exceed the maximum power allowed. The purpose of power management is to minimize transmit power level when lower power levels are sufficient.
2. System Description 29 HD to be configured in a protected ring configuration where the STP will prevent an Ethernet loop in the ring. This will also allow the ring to re-configure in the event of an outage. The Event-HD acts as a network bridge via the Ethernet switch and STP. The Event-HD does not currently support NMS routing capability. 2.14.3NMS Network Operational Principles The Event-HD does not provide routing capability.
30 2. System Description SWITCH ROUTER IP1: 192.168.1.1 IP2: 192.168.2.1 SDIDUTM IP: 192.168.2.33 GW: 192.168.2.1 PC IP: 192.168.1.10 GW: 192.168.1.1 SUBNET 1 SDIDUTM IP: 192.168.1.21 GW: 192.168.1.1 SUBNET 2 Figure 2-15. Event-HD SDIDUs™ on Different Subnets 2.14.4Third Party Network Management Software Support The Event-HD SDIDU™ supports SNMPv1, SNMPv2, and SNMPv3 protocols for use with third party network management software.
2. System Description 31 available. Loopback points and duration are easily selected through the Graphical User Interface, for more information see the User Interface Guide. © 2007 Moseley, Inc. All Rights Reserved. 602-14886-01, Rev.
3. Installation 1 3.Installation 3.1Unpacking The following is a list of possible included items. Description Quantity Event-HD SDIDUTM (1RU chassis) 1 ODU (with hardware) 1 Manual (or Soft copy on a CD) 1 SDIDUTM ODUs Figure 3-1. Event HD (1+0) Components Be sure to retain the original boxes and packing material in case of return shipping. Inspect all items for damage and/or loose parts. Contact the shipping company immediately if anything appears damaged.
2 3. Installation 3.2Notices CAUTION: DO NOT OPERATE UNITS WITHOUT AN ANTENNA, ATTENUATOR, OR LOAD CONNECTED TO THE ANTENNA PORT. DAMAGE MAY OCCUR TO THE TRANSMITTER DUE TO EXCESSIVE REFLECTED RF ENERGY. ALWAYS ATTENUATE THE SIGNAL INTO THE RECEIVER ANTENNA PORT TO LESS THAN -20 dBm. THIS WILL PREVENT OVERLOAD AND POSSIBLE DAMAGE TO THE RECEIVER MODULE. WARNING HIGH VOLTAGE IS PRESENT INSIDE THE ODU and SDIDUTM WHEN THE UNIT IS PLUGGED IN.
3. Installation 3 Ant. Port 30dB 20dB 30dB 10W 2W 10W ODU 1 Ant. Port ODU 2 TNC IF Cable (supplied) SDIDU 1 TNC IF Cable (supplied) SDIDU 2 Figure 3-2. Event-HD Back-to-Back Testing Configuration 3.5Overview of Installation and Testing Process The installation and testing process is accomplished by performing a series of separate, yet interrelated, procedures, each of which is required for the successful implementation of a production Event-HD network.
4 3. Installation Network Life Cycle Customer Requirements RF Planning & Network Design Site Selection & Acquisition Network Operation & Maintenance Installation & Commissioning Network Upgrade & Expansion Perform Site Evaluation Mount and Align ODUs Install Cables Configure Digital Software Defined IDUTM PDH Type of Network? SDH Perform SDH Network Test Perform Fast PDH Network Test Installation & Commissioning Complete 03-01-013b Figure 3-3. Network Deployment Lifecycle 3.
3. Installation • • 5 Confirm • Line of sight for each link • Event-HD ODU mounting locations • Site equipment locations • Cable routes • Any other potential RF sources Prepare site drawings and record site information 3.6.
6 3. Installation 3.6.2Site Evaluation Process The following steps must be completed to perform a successful site evaluation. Each step in the process is detailed in the following subparagraphs: • Ensure RF Safety compliance: Ensure that appropriate warning signs are properly placed and posted at the equipment site or access entry. For a complete list of warnings, refer the Safety Precautions listed at the beginning of this manual.
3. Installation 7 As shown in the picture above, when a hard object protrudes into the signal path within the Fresnel zone, knife-edge diffraction can deflect part of the signal and cause it to reach the receiving antenna slightly later than the direct signal. Since these deflected signals are out of phase with the direct signal, they can reduce its power or cancel it out altogether.
8 3. Installation • - Grounding all Event-HD ODUs to antenna tower. - Grounding all SDIDUTM to the rack. Determine the Length of Interconnect Cable from Event-HD ODU to SDIDUTM: The primary consideration for the outdoor interconnect cable from the Event-HD ODU to SDIDUTM is the distance and route between the Event-HD ODU and SDIDUTM. This cable should not exceed 330 feet using Times Microwave LMR-200 cable. Guidelines are provided in Table 3-1.
3. Installation 9 LP (dB) = 36.6 + 20log10 (F*D) Where: F is the Frequency in MHz, D is the Distance of path in miles This link budget is very important in determining any potential problems during installation. The expected RSL and measured RSL should be close (+/- 5 to 10 dB) 3.6.3.2 Fade Margin Calculation The fade margin is the difference between the actual received signal and the Event-HD digital radio’s threshold for the modulation mode selected.
10 3. Installation Humid/Over Water: C = 4 (worst case channel) Average Conditions: C = 1 Dry/Mountains: C = 0.25 (best case channel) Example: Assume 21 dB fade margin, over 5 miles with average climate/terrain. The availability comes out to be 99.9986. This corresponds to the link being unavailable for 7.6 minutes per year. 3.6.
3. Installation 11 2 GHz 17 MHz (BAS Band A) A1 A2 A3 A4 A5 A6 A7 18 MHz 17 MHz 17 MHz 17 MHz 17 MHz 17 MHz 17 MHz 1999.0 2016.5 2033.5 2050,5 2067.5 2084.5 2101.5 1990 2110 Frequency (MHz) Figure 3-4. 2 GHz, 17 MHz Legacy BAS Frequency Plan 2.4 GHz 17 MHz (BAS Band A) A8 A9 17 MHz 17 MHz 2458.5 2475 2450 Frequency (MHz) 2483.5 Figure 3-5. 2.
12 3. Installation 5.3 GHz 1-Channel Plan, 30 MHz 20 MHz T/R Guard Band A1 B1 30MHz 5250 30MHz 5270 5290 5310 5330 5350 60MHz T/R 5.3 GHz 2-Channel Plan, 20 MHz 20 MHz T/R Guard Band A1 A2 20MHz 20MHz 5260 5280 5250 5290 B1 B2 20MHz 20MHz 5320 5340 5310 5350 60MHz T/R 60MHz T/R 5.
3. Installation 13 5.8 GHz 1-Channel Plan, 30 MHz 25 MHz T/R Guard Band A1 B1 30MHz 5725 30MHz 5750 5775 5800 5825 5850 75MHz T/R 5.8 GHz 2-Channel Plan, 25 MHz 25 MHz T/R Guard Band A1 A2 25MHz 25MHz 5737 5762 5725 5775 B1 B2 25MHz 25MHz 5812 5837 5800 5850 75MHz T/R 75MHz T/R 5.8 GHz 3-Channel Plan, 16.7 MHz 25 MHz T/R Guard Band A1 A2 A3 B1 B2 B3 16.7MHz 16.7MHz 16.7MHz 16.7MHz 16.7MHz 16.
14 3. Installation 3.6.6ODU Transmit Power Setup Setting the ODU transmit power is conditional on the band and application. The installer of this equipment is responsible for proper selection of allowable power settings. If there are any questions on power settings refer to your professional installer in order to maintain the FCC legal ERP limits. This warning is particularly true for the 5.3 GHz and 5.8 GHz bands and special instructions are provided below for these bands.
3. Installation 15 3.6.6.2 5.3 GHz Band In the 5.3 GHz U-NII band the peak EIRP (Effective Isotropic Radiated Power) is limited to +30 dBm at the antenna for bandwidths above 20 MHz and is reduced for narrower bandwidths in accordance with FCC part 15.407a(3). The installer is responsible during set up of transmit power to not exceed FCC limits on transmission power.
16 3. Installation For link budget, EIRP(Avg) dBm = 37 dBi + Tx Power Setting (dBm). Table 3-3. Maximum Power Settings for 5.3GHz U-NII Band Operation (US). Antenna Diameter Antenna Gain, dBi* (example) Maximum Tx Power Setting, dBm Maximum Tx Power Setting, dBm Maximum Tx Power Setting, dBm 1 Channel Mode (30MHz BW) 2 Channel Mode (20MHz BW) 3 Channel Mode (13.3MHz BW) 6 foot dish 37.6 -10 -11 -12 4 foot dish 34.6 -7 -8 -9 3 foot dish 31.2 -3 -4 -5 2 foot dish 28.0 0 -1 -2 1.
3. Installation 17 3.7Installation of the Event-HD The following sections provide installation guides for: • SDIDUTM Installation • ODU Installation 3.7.1Installing the Event-HD SDIDUTM The Event-HD SDIDUTM can be installed in the following three options: 1. Table top or cabinet 2. Wall mount 3. Rack mount The Event-HD SDIDUTM should be: • Located where you can easily connect to a power supply and any other equipment used in your network, such as a router or PC.
18 3. Installation 3.7.1.3 Installing in a Rack To maintain good airflow and cooling, it is preferred that the Event-HD Software Defined IDU™ is installed in a slot that has blank spaces above and below the unit. To rack-mount the SDIDUTM, use the supplied mounting brackets (Moseley part number 2734001-0001) to secure the chassis to the rack cabinet.
3. Installation 19 3.7.2.1 Installing ODU2200, ODU6500, ODU7200 11. The ODUxx00 chassis family has mounting holes located on the underside of the unit. There are total of 10 threaded ¼-20 holes available for mounting directly to a plate or to a pole with optional pole mounting hardware. The threaded screw locations are shown below in red in Figure 3-9. It is recommended to use at least 4 ¾” screws with lock washers. 2 Figure 3-9. ¼-20 threaded mounting hole locations on ODU2200. Use any 4. 32.
20 3. Installation 6 Figure 3-11. Completed Pole Mounting of ODU2200 3.7.2.2 Installing ODU5300, ODU5800 71. Remove the pole mount portion of the tilt bracket from the ODU5800 by loosening the middle bolts and removing the top and bottom bolts on each side. Figure 3-12. Event ODU5800 Rear View 82. Mount the tilt bracket to the mounting pole using the U-Bolts and nuts. Insert the U-bolts around the pole and through the holes in the tilt bracket.
3. Installation 21 Figure 3-13. Tilt Bracket for Event ODU5800 93. Place the Event-HD ODU5800 on the mating half of the tilt bracket connected by the two center bolts. 104. Add the remaining four bolts to the tilt bracket but do not tighten until the antenna alignment is complete (only applies for internal antenna ODUs). Figure 3-14. Event ODU5800 with Mounted Tilt Bracket 11 125. Manually point the ODU in the direction of the link partner ODU. © 2007 Moseley, Inc. All Rights Reserved.
22 3. Installation Figure 3-15. Completed Mounting for the Event ODU5800 3.7.3Routing the ODU/IDU Interconnect Cable 1. Select where the cable will enter the truck or building from outside. 2. Determine the length of cable required. Allow three extra feet on each end to allow for strain relief, as well as any bends and turns. 3. Route the cable. The SDIDUTM is equipped with TNC female connector on the rear of the chassis.
3. Installation 23 vertical runs to reduce stress on the cable. Outside the building, support and restrain the cable as required by routing and environmental conditions (wind, ice). The Event-HD ODU/SDIDUTM and interconnection must be properly grounded in order to protect it and the structure it is installed on from lightning damage. This requires that the ODU, any mounting pole or mast and any exposed interconnect cable be grounded on the outside of the structure.
24 3. Installation 2. Digital voltmeter with test leads 3. SDIDUTM Serial Cable (optional) 4. Computer with networking capability, consisting of either: - Laptop computer with Windows 98/2000/XP/Vista operating system, an Ethernet card with any necessary adapters and a Cat-5 Ethernet regular or crossover cable or - Networked computer with Windows 98/2000/XP/Vista operating system and an additional Ethernet cable providing access to the network. 5. Web Browser program, Internet Explorer 5.
3. Installation 25 Figure 3-16. Ground Connections to ODU. © 2007 Moseley, Inc. All Rights Reserved. 602-14886-01, Rev.
26 3. Installation 3.8.3Grounding the SDIDUTM 1. The SDIDU™ should be able to be connected to a system or building electrical ground point (rack ground or power third-wire ground) with a cable of 36” or less. 2. Connect the grounding wire to either grounding point on the rear panel. Use 6-32x5/16 maximum length screws (not provided) to fasten the lug of the grounding cable. 3. Connect the other end of the ground to the local source of ground in an appropriate manner. 3.8.
3. Installation 27 per step 2 above. Refer to Figure 3-17. Note that the Software Defined IDU™ SDIDUTM does not have a power on/off switch. When DC power is connected, the digital radio powers up and is operational. There can be up to 5 W of RF power present at the antenna port. The antenna should be directed safely when power is applied. 6. Turn on the 48 V dc power supply, and verify that the reading on the digital voltmeter is as specified in step 3 above. 7.
28 3. Installation 3.8.5.1 Setting the IDU IP Address 1. The PC’s network configuration must be set with the parameters provided at the end of this guide. 2. The IDU should be accessible from your PC at the default IP address provided at the end of this guide. A network ‘ping’ can be done to verify connectivity to the IDU. 3. Start web browser and use the SDIDUTM default IP address as the url. 4. Log in at the login prompt. The username and password are provided at the end of this guide. 5.
3. Installation 29 3.8.5.3 Configuring the Site Attributes Use the GUI to enter device information as follows: 1. In the navigation menu, select Administration, then Device Information, and then Device Names. 2. Enter the Owner, Contact, Description, and Location. These values are not required for operation, but will help keep a system organized. 3.8.5.4 Power on Reset to Factory Defaults The SDIDU™ may be reset to factory defaults during power up.
30 3. Installation Table 3-4: Serial Port Parameters Parameter Speed Bits Stop-Bits Parity Flow-Control Value 38400 8 1 None None After powering-on the SDIDUTM, the CLI may be accessed by connecting the serial cable between the PC and the SDIDUTM, launching and configuring a terminal program (e.g. Hyperterm) and pressing the enter key. You will be prompted for a username and password, which are supplied at the end of this guide. 3.8.
3. Installation 31 For simplex applications such as broadcast STL or ENG where the ODU is a receiver or a transmitter only then both LED bars represent either RSL for receiver ODU or transmit power for transmitter ODU. For RSL each LED represents 5 dB, with brightness modulated from off for 0 dB to fully on for 5 dB increments. 3.8.6.
32 3. Installation Event-HD IP Address The Event-HD system will be configured and tested as link prior to delivery to the customer. The IP address will be set at the factory to these default values: Parameter Value IP Address Netmask 192.168.1.1xx 255.255.255.0 Gateway 192.168.1.1 Where xx is in the range from 01 to 99. The IP address is indicated on the rear panel as shown in Figure 3-21. Figure 3-21.
3. Installation 33 Power Supply Module Power Supply Module Controller Module Standard IO Module Expansion Module Mini IO Module Modem Module Modem Module Figure 3-22. SDIDU™ Modules 3.9.1Removing a Module 9. Modules are static sensitive and should only be handled in an ESD-safe environment. When packaging modules for shipment or storage, place in an ESD bag. 10. Remove rear panel connections to the module. 11. Remove the two thumbscrews on either side of the module.
34 3. Installation powered on and the ground lug is being used to ground the unit, first move the ground connection to the ground lug located on the Controller Module. The SDIDU™ retains its current configuration when a module is removed, unless that module is the Controller Module. In which case, the IP addresses will need to be reprogrammed. Figure 3-24. Threaded Hole Locations 3.9.2Installing a Module 1. Modules are static sensitive and should only be handled in an ESD-safe environment.
3. Installation 35 Guide Figure 3-25. Guides 3. Install thumbscrews on either side of the module as shown in Figure 3-24. a. The Mini IO card has a corner screw, which should be installed. This corner screw is shown in Figure 3-23. 4. Make rear panel connections to the module and power on the SDIDU™ if necessary. 5. Verify proper operation of the unit. a. If the Controller Module has been changed, reprogram the IP addresses. © 2007 Moseley, Inc. All Rights Reserved. 602-14886-01, Rev.
36 © 2007 Moseley, Inc. All Rights Reserved. 3. Installation 602-14886-01, Rev.
4. Summary Specification 1 4.Summary Specification Parameter Event 2200, 2200FD, 2400 Event 6500, 6800, 7200, 7400 2GHz 6-7 GHz Frequency Bands 1.990-2.110 6.425-6.525 (others available on request) 2.200-2.300 6.525-6.875 2.450-2.500 6.875-7.125 Event 5800 Event 5300 5.8 GHz 5.3 GHz 5.725-5.850 5.250-5.350 System 7.125-7.425 Output Power 4 Watts 1 Watt 200 mW +5 dBm 12, 17 MHz 20, 25, 28, 30 MHz 12.5, 16.7, 25, 30 MHz 13.3, 20, 30 MHz (avg. max.
2 4. Summary Specification Parameter Event 2200, 2200FD, 2400 Event 6500, 6800, 7200, 7400 2GHz 6-7 GHz Event 5800 Event 5300 5.8 GHz 5.
5. Rear Panel Connectors 1 5.Rear Panel Connectors 5.1DC Input (Power) Connector MSTB 2,5/ 2-GF 1 2 PIN TYPE SIGNAL 1 POWER Power supply return 2 POWER 48 Vdc, nominal Mating Connector: MSTB 2,5/ 2-STF Ordering Information: Phoenix Contact Part Number 1786831 5.
2 5. Rear Panel Connectors 5.4STM-1 Payload Connector BNC Female TX RX PIN TYPE SIGNAL TX OUTPUT SDH STM-1 payload output (electrical) RX INPUT SDH STM-1 payload input (electrical) Mating Connector: BNC Male Ordering Information: Tyco Electronics/Amp Part Number 225395-2 or equivalent 5.5DVB/ASI, DS-3, E-3, STS-1 Payload Connector Consult factory for availability.
5. Rear Panel Connectors 3 3 5.
4 5. Rear Panel Connectors Cable Type Ordering Information Belden 7808 Tyco Electronics/Amp Part Number 1-225550-3 or equivalent 5.9T1/E1 - Channels 1-2 Connector RJ-48C Female 100 Ω /120 Ω Balanced PIN TYPE SIGNAL 1 INPUT RX+ 2 INPUT RX- 3 N/A GND 4 OUTPUT TX+ 5 OUTPUT TX- 6 N/A GND 7 N/A N/A 8 N/A N/A Mating Connector: Standard RJ-45 Plug Ordering Information: Tyco Electronics/Amp Part Number 5-554169-3 or equivalent 5.
5. Rear Panel Connectors 5 5 Molex LFH Matrix 50 Receptacle © 2007 Moseley, Inc. All Rights Reserved.
6 5.
5. Rear Panel Connectors 7 7 5.12Voice Order Wire RJ-45 Female PIN TYPE SIGNAL 1 N/A NC 2 INPUT PTT 3 N/A GND 4 OUTPUT PO- 5 OUTPUT PO+ 6 INPUT TI- 7 N/A GND 8 N/A NC Mating Connector: Standard RJ-6 Plug or Standard RJ-45 Plug Ordering Information: Tyco Electronics/Amp Part Number 5-554710-3 or equivalent for RJ-6. Tyco Electronics/Amp Part Number 5-554169-3 or equivalent for RJ-45. 5.13Data Order Wire 5.13.
8 5. Rear Panel Connectors 5.13.2RS-232 RJ-45 Female PIN TYPE SIGNAL 1 N/A NC 2 N/A NC 3 N/A Signal GND 4 N/A NC 5 INPUT RX Data + 6 OUTPUT TX Data + 7 N/A NC 8 N/A NC Mating Connector: Standard RJ-45 Plug Ordering Information: Tyco Electronics/Amp Part Number 5-554169-3 or equivalent © 2007 Moseley, Inc. All Rights Reserved. 602-14886-01, Rev.
6. Appendix 1 6.Appendix 6.1Alarm Descriptions Alarm Affected Component Description LED to RED Alarm Severity Code Modem Fault Lower Modem The specified Modem card has indicated a fault. Fault detection is via reading Modem Hardware Status from MODEM during start-up and polling GPIO for MODEM fault indication. Polling interval 5 sec. N/A 11 Critical Modem Comm Failure Lower Modem The Controller Card is unable to communicate with the specified Modem card.
2 6. Appendix Alarm Synthesizer Unlock Lower Affected Component Modem Description LED to RED Alarm Severity Code Modem synthesizer has unlocked. Fault detection via modem status polling. Polling is done in conjunction with Modem Unlock polling. N/A N/A Critical SNR Low Lower Modem The signal-to-noise ratio is below the minimum operational level of the link as set during configuration. Fault detection via modem status polling, comparing Eb/N0 value to threshold value in configuration table.
6. Appendix 3 3 Alarm RSL Low Upper Affected Component Modem Description LED to RED Alarm Severity Code RSSI is approaching the minimum operational level of the link as set during configuration. Fault detection via modem status polling, comparing RSSI value to threshold value in configuration table. Polling interval 5 sec. N/A N/A Major SNR Low Upper Modem The signal-to-noise ratio is below the minimum operational level of the link as set during configuration.
4 6. Appendix Alarm Affected Component Description LED to RED Alarm Severity Code Power Supply Card Removed Lower Power Supply The specified Power Supply card has been removed from the IDU. Fault detection via card-detect logic. N/A 32 Major Power Supply Fault Upper Power Supply The Power Supply card has indicated a fault. Fault detection via polling GPIO. Polling interval 5 sec.
6. Appendix 5 5 Alarm Affected Component Description LED to RED Optional I/O Card Removed OptIO The Optional I/O card has been removed from the IDU (only if the Optional I/O card has been enabled for use). Fault detection via card-detect logic. N/A Optional I/O Card Installed OptIO The Optional I/O card has Optional been installed into the IDU I/O (only if the Optional I/O card is not enabled for use). Fault detection via card-detect logic. Alarm is raised then lowered.
6 6. Appendix Alarm Affected Component Description LED to RED Alarm Severity Code ODU Fault Lower ODU The ODU has indicated a fault condition. Fault detection via polling of ODU or unsolicited message, if supported. Polling interval 5 sec. Polling done via API functional call. Report of this alarm in the GUI/Syslog/Alarm history indicates the fault code from the ODU. N/A 71 Critical ODU Comm Failure Lower ODU The IDU is unable to communicate with the ODU.
6. Appendix 7 7 Alarm Affected Component Description LED to RED Alarm Severity Code East ATPC Tx at ODU Max Power The IDU is unable to increase the Tx Power as requested by link partner due to maximum power being reached. Maximum power is specified in the configuration table. N/A 76 Info West ATPC Tx at ODU Max Power The IDU is unable to increase the Tx Power as requested by link partner due to maximum power being reached. Maximum power is specified in the configuration table.
8 6. Appendix Alarm Affected Component Description LED to RED Alarm Severity Code External Alarm 3 External The external Alarm 3 input has been activated. Fault detection via polling GPIO. Polling interval 1 sec. N/A 93 Info External Alarm 4 External The external Alarm 4 input has been activated. Fault detection via polling GPIO. Polling interval 1 sec. N/A 94 Info Remote IDU Alarm Link Partner IDU The link partner IDU has indicated an alarm condition via ROH.
6. Appendix 9 9 Alarm Affected Component Description LED to RED Alarm Severity Code STM RS_LOF IDU The SDH/SONET Mux/Demux has a Loss of Frame Defect. Fault detection via polling of RS_LOF_T bit in STM-1 Core. Alternate detection via Interrupt enabled in STM-1 core. N/A Solid Critical STM RS_OOF IDU The SDH/SONET Mux/Demux has an Out of Frame Defect. Fault detection via polling of RS_OOF_T bit in STM-1 Core. Alternate detection via Interrupt enabled in STM-1 core.
10 6. Appendix Alarm Affected Component Description LED to RED Alarm Severity Code STM MS_B2 IDU The SDH/SONET Mux/Demux has a B2 Defect at the Multiplex level. Fault detection via polling of MS_B2_T bit in STM-1 Core. Alternate detection via Interrupt enabled in STM-1 core. N/A Solid Major STM AU-AIS x IDU The SDH/SONET Mux/Demux has detected an AIS at the AU Level. Fault detection via polling of AU_AIS_T bit in STM-1 Core. Where ‘x’ is the HP index.
6. Appendix 11 11 Alarm Affected Component Description LED to RED Alarm Severity Code STM HP-REI x IDU The SDH/SONET Mux/Demux HP number ‘x’ has a Remote Error Indication. Fault detection via polling of HP_REI_T bit in STM-1 Core. Where ‘x’ is the HP index. Alternate detection via Interrupt enabled in STM-1 core. N/A Solid Major STM HP-RDI x IDU The SDH/SONET Mux/Demux HP number ‘x’ has a Remote Defect Indication. Fault detection via polling of HP_RDI_T bit in STM-1 Core.
12 6. Appendix Alarm Affected Component Description LED to RED Alarm Severity Code STM TU-AIS lkm IDU The SDH/SONET Mux/Demux TU number ‘x’ has an AIS. Fault detection via polling of TU_AIS_T bit in STM-1 Core. Where ‘lkm’ is the TU index as LKM numbering. Alternate detection via Interrupt enabled in STM-1 core. N/A Solid Critical STM TU-LOP lkm IDU The SDH/SONET Mux/Demux TU number ‘x’ has a Loss of Pointer Defect. Fault detection via polling of TU_LOP_T bit in STM-1 Core.
6. Appendix 13 13 Alarm Affected Component Description LED to RED Alarm Severity Code STM LP-RDI lkm IDU The SDH/SONET Mux/Demux LP number ‘x’ has a Remote Defect Indication. Fault detection via polling of LP_RDI_T bit in STM-1 Core. Where ‘lkm’ is the LP index as LKM numbering. Alternate detection via Interrupt enabled in STM-1 core. N/A Solid Major STM LP-PLM lkm IDU The SDH/SONET Mux/Demux LP number ‘x’ has a Path Identifier Mismatch.
14 6. Appendix Alarm NTP Update Affected Component IDU Description LED to RED Alarm Severity Code When the system time is updated via NTP raise then lower this alarm. The previous system time and new system time should be noted in the alarm log, SNMP trap, and syslog messages. N/A Solid Info Remote IDU Reconfiguration Failure When a remote reconfiguration fails and the original configuration is restored after timeout, raise then lower this alarm.
6.
16 6. Appendix RX Receiver SDH Synchronous Digital Hierarchy SNMP Simple Network Management Protocol SNR Signal-to-Noise Ratio SDIDUTM Software Defined Indoor Unit (Moseley trademark) SONET Synchronous Optical Network STM-1 Synchronous Transport Module 1 TCP/IP Transmission Control Protocol/Internet Protocol TTL Transistor-transistor logic TX Transmitter © 2007 Moseley, Inc. All Rights Reserved. 602-14886-01, Rev.
6. Appendix 17 17 Conversion Chart microvolts to dBm (impedance = 50 ohms) microvolts dBm microvolts dBm 0.10 -127.0 180 -61.9 0.25 -119.0 200 -61.0 0.50 -113.0 250 -59.0 0.70 -110.1 300 -57.4 1.0 -107.0 350 -56.1 1.4 -104.1 400 -54.9 2.0 -101.0 450 -53.9 2.5 -99.0 500 -53.0 3.0 -97.4 600 -51.4 3.5 -96.1 700 -50.1 4.0 -94.9 800 -48.9 4.5 -93.9 900 -47.9 5.0 -93.0 1,000 -47.0 6.0 -91.4 1,200 -45.4 7.0 -90.1 1,400 -44.1 8.0 -88.9 1,600 -42.
18 6. Appendix microvolts dBm microvolts 70 -70.1 223.6 mV 0 (1 mW) 80 -68.9 707.1 mV +10 (10mW) 90 -67.9 2.23 V +20 (100 mW) 100 -67.0 7.07 V +30 (1 W) 120 -65.4 15.83 V +37 (5 W) 140 -64.1 22.36 V +40 (10 W) 160 -62.9 © 2007 Moseley, Inc. All Rights Reserved. dBm 602-14886-01, Rev.
IN CASE OF DIFFICULTY... Moseley products are designed for long life and trouble-free operation. However, this equipment, as with all electronic equipment, may have an occasional component failure. The following information will assist you in the event that servicing becomes necessary. TECHNICAL ASSISTANCE Technical assistance for Moseley products is available from our Technical Support Department by phone or email.