Moseley Associates EVENTHD Users Manual

Event HD

User Reference and Installation Manual

Document Number: 602-14886-01, Rev. A

Date: OCTOBER, 2007

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. reserves the right to make changes in design or components as progress in engineering and manufacturing may warrant.

The Warranty(s) that accompany Moseley products are set forth in the sales agreement/contract between Moseley and its customer. Please consult the sales agreement for the terms and conditions of the Warranty(s) provided by Moseley. To obtain a copy of the Warranty(s), contact you Moseley Sales Representative at 1-805-968-9621 or 1-805-685-9638 (FAX).

The information provided in this document is provided “as is” without warranty of any kind, either expressed or implied, including, but not limited to, the implied warranties of merchantability, fitness for a particular purpose, or non-infringement. Some jurisdictions do not allow the exclusion of implied warranties, so the above exclusion may not apply to you.

In no event shall Moseley, Inc. be liable for any damages whatsoever – including special, indirect, consequential or incidental damages or damages for loss of profits, revenue, use, or data whether brought in contract or tort, arising out of or connected with any Moseley, Inc., document or the use, reliance upon or performance of any material contained in or accessed from this document. Moseley’s license agreement may be provided upon request. Additional Terms and Conditions will be finalized upon negotiation or a purchase.

The above information shall not be constructed to imply any additional warranties for Moseley, Inc. equipment including, but not limited to, warranties of merchantability or fitness for an intended use.

Trademark Information

Software Defined Indoor UnitTM (SDIDUTM) is a product and trademark of Moseley Inc.

JavaTM is a trademark of Sun Microsystems Inc.

Windows® is a registered trademark of Microsoft Corporation

All other brand or product names are trademarks or registered trademarks of their respective companies or organizations.

Part Number: MK-MAN-4001

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 .............................................................................................. 5

2.4 Physical Description ......................................................................................... 6

2.4.1 Model Types 7

2.4.2 Front Panel ............................................................................................... 8

2.4.3 Rear Panel Indicators .................................................................................. 9

2.4.4 Rear Panel Connections ............................................................................. 12

2.4.5 ODU LED Indicators .................................................................................. 15

2.5 System Description ........................................................................................ 16

2.6 Consecutive Point Architecture ......................................................................... 19

2.7 2 + 0 (East-West) Configuration ..................................................................... 21

2.8 Spanning Tree Protocol (STP) .......................................................................... 22

2.9 1+1 Protection ............................................................................................... 22

2.9.1 Protected Non-Diversity (Hot Standby) ........................................................ 22

2.9.2 Protected Diversity ................................................................................... 23

2.10 1 + 1 Multi-hop Repeater Configuration ........................................................... 24

2.11 Data Interfaces ............................................................................................ 25

2.12 Crosspoint Switch ......................................................................................... 26

2.13 Power Management ...................................................................................... 27

2.14 Event-HD Software and Network Management ................................................. 28

2.14.1 IP Address ............................................................................................. 28

2.14.2 Network ................................................................................................. 28

2.14.3 NMS Network Operational Principles .......................................................... 29

2.14.4 Third Party Network Management Software Support .................................... 30

2.15 System Loopbacks ........................................................................................ 30

3. INSTALLATION ............................................................................................... 1

3.1 Unpacking ....................................................................................................... 1

3.2 Notices ........................................................................................................... 2

3.3 PRE-INSTALLATION NOTES ............................................................................... 2

3.4 Back-to-Back Bench Testing .............................................................................. 2

3.5 Overview of Installation and Testing Process ....................................................... 3

3.6 Site Evaluation ................................................................................................ 4

3.6.1 Preparing for a Site Evaluation ..................................................................... 5

3.6.2 Site Evaluation Process ............................................................................... 6

3.6.3 Critical System Calculations ......................................................................... 8

3.6.4 Frequency Plan Determination ................................................................... 10

3.6.5 Antenna Planning ..................................................................................... 13

3.6.6 ODU Transmit Power Setup ........................................................................ 14

3.7 Installation of the Event-HD ............................................................................ 17

3.7.1 Installing the Event-HD SDIDUTM .............................................................. 17

3.7.2 Installing the Event-HD ODU ...................................................................... 18

3.7.3 Routing the ODU/IDU Interconnect Cable .................................................... 22

3.8 Quick Start Guide ........................................................................................... 23

3.8.1 Materials Required .................................................................................... 23

3.8.2 Grounding the ODU ................................................................................... 24

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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 ................................................................................. 31

3.9 SDIDU™ Service ............................................................................................ 32

3.9.1 Removing a Module .................................................................................. 33

3.9.2 Installing a Module ................................................................................... 34

4. SUMMARY SPECIFICATION ............................................................................. 1

5. REAR PANEL CONNECTORS ............................................................................. 1

5.1 DC Input (Power) Connector ............................................................................. 1

5.2 Ethernet 100BaseTX Payload Connector 1-2 ........................................................ 1

5.3 SONET Payload Connector ................................................................................. 1

5.4 STM-1 Payload Connector ................................................................................. 2

5.5 DVB/ASI, DS-3, E-3, STS-1 Payload Connector .................................................... 2

5.6 NMS 10/100BaseTX Connector 1-2 ..................................................................... 2

5.7 Alarm/Serial Port Connector .............................................................................. 3

5.8 ODU Connector ................................................................................................ 3

5.9 T1/E1 - Channels 1-2 Connector ........................................................................ 4

5.10 T1/E1 - Channels 3-16 Connector ..................................................................... 4

5.11 USB .............................................................................................................. 6

5.12 Voice Order Wire ............................................................................................ 7

5.13 Data Order Wire ............................................................................................. 7

5.13.1 RS422 ..................................................................................................... 7

5.13.2 RS-232 .................................................................................................... 8

6. APPENDIX ...................................................................................................... 1

6.1 Alarm Descriptions ........................................................................................... 1

Abbreviations & Acronyms ................................................................................... 15

Conversion Chart ................................................................................................ 17

List of Figures

FIGURE 2-1. TYPICAL BROADCAST ENG APPLICATION.......................................2

FIGURE 2-2. MICROWAVE SPLIT MOUNT ARCHITECTURE...................................3

FIGURE 2-2. EVENT-HD FRONT PANEL (OPTIONAL)...........................................8

FIGURE 2-2. SOFTWARE DEFINED IDU™ LEDS: SDIDUTM REAR PANEL

CONFIGURATION FOR SOFTWARE DEFINED IDU™, 1+0 CONFIGURATION.......10

FIGURE 2-3. SOFTWARE DEFINED IDU™-SB, 1+1 PROTECTION: SDIDUTM REAR

PANEL CONNECTIONS......................................................................................12

FIGURE 2-4. ODU 2200 RSSI OUTPUT VS. RECEIVED SIGNAL. .........................15

FIGURE 2-5. EVENT-HD BLOCK DIAGRAM.........................................................17

FIGURE 2-6. RING CONFIGURATION................................................................20

FIGURE 2-7. CONSECUTIVE POINT NETWORK..................................................21

FIGURE 2-8. 2 + 0 (EAST WEST) CONFIGURATION...........................................22

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. PC AND EVENT-HD SDIDUS™ ON SAME SUBNET.........................29

FIGURE 2-15. EVENT-HD SDIDUS™ ON DIFFERENT SUBNETS...........................30

FIGURE 3-1. EVENT HD (1+0) COMPONENTS......................................................1

FIGURE 3-2. EVENT-HD BACK-TO-BACK TESTING CONFIGURATION...................3

FIGURE 3-3. NETWORK DEPLOYMENT LIFECYCLE...............................................4

FIGURE 3-3. 2 GHZ, 12 MHZ BAS FREQUENCY PLAN.........................................10

FIGURE 3-4. 2 GHZ, 17 MHZ LEGACY BAS FREQUENCY PLAN............................11

FIGURE 3-6. 7 GHZ, 25 MHZ BAS FREQUENCY PLAN.........................................11

v

FIGURE 3-7. EVENT-HD 5.3 GHZ FREQUENCY PLAN .........................................12

FIGURE 3-8. EVENT-HD 5.8 GHZ FREQUENCY PLAN .........................................13

FIGURE 3-8. SOFTWARE DEFINED IDU™ DIMENSIONS.....................................18

FIGURE 3-9. ¼-20 THREADED MOUNTING HOLE LOCATIONS ON ODU2200. USE ANY 4.

19

FIGURE 3-10. POLE MOUNTING BRACKETS ON ODU2200

19

FIGURE 3-11. COMPLETED POLE MOUNTING OF ODU2200

20

FIGURE 3-12. EVENT ODU5800 REAR VIEW .....................................................20

FIGURE 3-13. TILT BRACKET FOR EVENT ODU5800..........................................21

FIGURE 3-14. EVENT ODU5800 WITH MOUNTED TILT BRACKET ......................21

FIGURE 3-15. COMPLETED MOUNTING FOR THE EVENT ODU5800....................22

FIGURE 3-16. GROUND CONNECTIONS TO ODU................................................25

FIGURE 3-17. SDIDU DC POWER CABLE CONNECTOR.......................................26

FIGURE 3-18. SOFTWARE DEFINED IDU™-SB, 1+1 PROTECTION, REAR PANEL

CONNECTIONS.................................................................................................27

FIGURE 3-19. ODU 2200 RSSI OUTPUT VS. RECEIVED SIGNAL. .......................30

FIGURE 3-20. ODU RSSI OUTPUT VS. RECEIVED SIGNAL. ................................31

FIGURE 3-21. IDU IP ADDRESS LABEL LOCATION............................................32

FIGURE 3-22. SDIDU™ MODULES.....................................................................33

FIGURE 3-23. THUMBSCREW AND CORNER SCREW LOCATIONS.......................33

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

vii

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. The antenna will be professional installed on fixed-mounted outdoor permanent structures to provide separation from any other antenna and all persons.

WARNING: RF Energy Exposure Limits and Applicable Rules for 6-38 GHz. It is recommended that the radio equipment operator refer to the RF exposure rules and precaution for each frequency band and other applicable rules and precautions with respect to transmitters, facilities, and operations that may affect the environment due to RF emissions for each radio equipment deployment site.

Appropriate warning signs must be properly placed and posted at the equipment site and access entries.

Protection from Lightning

Article 810 of the US National Electric Department of Energy Handbook 1996 specifies that radio and television lead-in cables must have adequate surge protection at or near the point of entry to the building. The code specifies that any shielded cable from an external antenna must have the shield directly connected to a 10 AWG wire that connects to the building ground electrode.

Do not turn on power before reading Moseley’s product documentation. This device has a 48 VDC direct current input.

Protection from RF Burns

It is hazardous to look into or stand in front of an active antenna aperture. Do not stand in front of or look into an antenna without first ensuring the associated transmitter or transmitters are switched off. Do not look into the waveguide port of an ODU (if applicable) when the radio is active.

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. In a domestic environment this product may cause

radio interference in which case the user may be required to take adequate measures.

Warning – Turn off all power before servicing

WARNING: Turn off all power before servicing.

Safety Requirements

Safety requirements require a switch be employed between the SDIDU™ external power supply and the SDIDU™ power supplies.

Proper Disposal

The manufacture of the equipment described herein has required the extraction and use of natural resources. Improper disposal may contaminate the environment and present a health risk due to the release of hazardous substances contained within. To avoid dissemination of these substances into our environment, and to lessen the demand on natural resources, we encourage you to use the appropriate recycling systems for disposal. These systems will reuse or recycle most of the materials found in this equipment in a sound way. Please contact Moseley or your supplier for more information on the proper disposal of this equipment.

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.

2.2Introduction

The Moseley family of digital radios provides high capacity transmission, flexibility, features, and convenience for wireless digital communications networks. The Moseley digital point-to-point radios represent a new microwave architecture that is designed to address universal applications for video, audio, data, PDH and SDH platforms. This advanced technology platform is designed to provide the flexibility to customers for their current and future network needs.

The Moseley EVENT HD is a digital microwave radio terminal composed of a Software Defined Indoor Unit™ (SDIDU™) and Outdoor Unit (ODU). The SDIDU is common to all product lines whereas the ODU, the radio transceiver unit which establishes the frequency of operation, is selected by application and model. The ODU is fully interchangeable covering the licensed 2, 7, 13, 18, and 23 GHz bands as well as the unlicensed 5.3 and 5.8 GHz ISM bands. Some applications are:

Broadcast STL (Studio-to-Transmitter Link) and BAS (Broadcast Auxiliary Service) for for licensed half-duplex applications, FCC part 74.602, for data rates to 150 Mbps,

 2 GHz band between 1990 to 2110 MHz in 12 MHz and 17 MHz channels.

 6.5 GHz band between 6425 to 6525 MHz in 25 MHz channels.

 7 GHz band between 6825 to 7125 MHz in 25 MHz channels.

 13 GHz band between 12.7 to 13.25 GHz in 25 MHz channels.

2 2. System Description

ENG VAN Studio

MPEG / HDTV

Encoder

MPEG / HDTV

Decoder

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 GHz band, Canada and Australia.

 6.8 GHz band, FCC part 101.147, in 10 MHz channels.

 6 GHz lower and upper, and 7 GHz ETSI.

 18 and 23 GHz, US part 101.

The Event HD digital radios support diversity, 1+0, and 1+1 protection and ring architectures in a single 1 RU chassis. The modem and power supply functions are supported using easily replaceable plug-in modules. An additional feature of the SDIDU

TM

is provision for a second plug-in modem/IF module to provide diversity, repeater or east/west network configurations.

The Event HD includes integrated Operations, Administration, Maintenance, and Provisioning (OAM&P) functionality and design features enabling simple commissioning when the radio network is initially set up in the field at the customer’s premises. Furthermore, a highlight of the Event HD is scalability and the capability to support a

2. System Description 3

Core Access

Network

Indoor Unit

Outdoor

Unit

Outdoor

Unit

Outdoor

Unit

Outdoor Unit

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). The overall split mount architecture consists of a single 1RU rack mount Software Defined Indoor Unit (SDIDUTM) with a cable connecting to an Outdoor Unit (ODU) with an external antenna.

Figure 2-2. Microwave Split Mount Architecture

Table 2-2 shows key features that Moseley technology offers to those involved in the design, deployment and support of broadband fixed wireless networks.

Table 2-1. Key Benefits and Advantages of the Event-HD Radios

Benefits Advantages to Providers/Customers Reference

Software Defined Indoor Unit (SDIDUTM)

Universal signal processing platform

Advanced Single Chip Modem ASIC

Integrated Forward Error Correction (FEC)

Powerful adaptive equalizer

Enables easy network interface options and network capacity growth in the future.

Cost effective solution; simplifying product logistics and overall product life cycle costs. The flexibility reduces capital and operating expenditures commonly associated with field installation, maintenance, training and spares.

Frequency independent and Scalable.

Software defined flexibility enables selective modulation for spectral efficiency and adherence to worldwide regulatory emissions guidelines.

2.2 – 2.5

4 2. System Description

Benefits Advantages to Providers/Customers Reference

Easy to install units

Straightforward modular system enables fast deployment and activation.

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.

Ring Architecture

Supports a ring (consecutive point) configuration, thus creating a self-healing redundancy that is more reliable than traditional point-to-point networks.

In the event of an outage, traffic is automatically rerouted via another part of the ring without service interruption.

Ring/consecutive point networks can overcome line-of-sight issues and reach more buildings than other traditional wireless networks.

Networks can be expanded by adding more Software Defined IDU™ or more rings, without interruption of service.

Fast return on investment.

No monthly leased line fees.

Increases available bandwidth of network.

Allows customer full use of revenue-generating payload channel.

Lowers total cost of ownership.

Enables network scalability.

Increases deployment scenarios for initial deployment as well as network expansion with reduced line-of-sight issues.

Increases network reliability due to selfhealing redundancy of the network.

Minimizes total cost of ownership and maintenance of the network.

Allows for mass deployment.

3.1, 3.4, 3.6

2.2 – 2.5

2.6

A separate management channel allows for a dedicated maintenance ring with connections to each Software Defined IDU™ on the ring.

Adaptive Power Control

Automatically adjusts transmit power in discrete increments in response to RF interference.

Comprehensive Link/Network Management Software

Enables dense deployment.

Simplifies deployment and network management.

2.7

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.

Suite of SNMP-compatible network management tools that provide robust local and remote management capabilities.

2.3System Features

 Selectable Rates and Interfaces

o DVB-ASI interface application scalable from 10 to 100 Mbps.

o PDH Options

 Up to 16 x E1/T1

 100BaseTX/Ethernet: Scalable 1-100 Mbps

Simplifies management of radio network and minimizes resources as entire network can be centrally managed out of any location.

Simplifies troubleshooting of single radios, links, or entire networks.

Simplifies network upgrades with remote software upgrades.

Allows for mass deployment.

2.5, 2.8

 DS-3/E-3/STS-1

o Super PDH Options

 Up to 32 x E1/T1

 100 BaseTX/Ethernet: Scalable 1-100 Mbps

o SDH Options

 1-2 x SDH STM-1/OC-3 SONET

 Support for multiple configurations for both PDH and SDH

o 1+0, 1+1 protection/diversity

o Hot Standby

o East/West Repeater (2 + 0)

 Selectable Spectral Efficiency of 0.8 to 6.25 bits/Hz (including FEC and spectral

shaping effects)

 QPSK, 16 –256 QAM Modulation

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 5.8, 7, and 13 GHz bands

 Built-in Network Management System (NMS)

 Consecutive Point ring architecture

 Built-in Bit Error Rate (BER) performance monitoring

 Integrated Crosspoint switch: allows a total of 160 E1s (200 T1s) to be mapped

any-to-any between front-panel ports and RF link(s).

2.4Physical Description

The following section details the physical features of the Event HD™ digital radios.

• Model Types

• Front and rear panel configurations

• LED and I/O descriptions

2. System Description 7

2.4.1Model Types

The following model types are available with associated ODU configuration:

Primary

Product Name Band

Data Interfaces

Primary Throughput ODU

1. Event 2200 1990-2110

2025-2150

2. Event 2200 FD

2200-2300

3. Event 2500 2450-2500

4. Event 5300 5250-5350

5. Event 5800 5725-5850

6. Event 6500 6425-6525

7. Event 6800 6525-6875

ASI 10-100 Mbps

Ethernet 2 Mbps

16xE1/T1

up to 100

2xEthernet

16xE1/T1

Mbps

up to 100

Mbps

2xEthernet

ASI 10-100 Mbps

Ethernet 2 Mbps

16xE1/T1

up to 100

Mbps

2xEthernet

16xE1/T1

up to 100

Mbps

2xEthernet

ASI 10-150 Mbps

Ethernet 2 Mbps

16xE1/T1

up to 100

Mbps

2xEthernet

ODU2200

ODU2200FD

ODU2500

ODU5300

ODU5800

ODU6500

ODU6800

8. Event 7200 6875-7125

9. Event 13G

12700-132

50

ASI 10-150 Mbps

Ethernet 2 Mbps

ASI 10-150 Mbps

Ethernet 2 Mbps

ODU7200

ODU13G/18G/23G

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). The menu structure gives access to three primary functions: Status, Configuration, and Alarms. The menus are navigated as follows:

Event Status Configuration Alarms

Status Transmit Receive Versions

Transmit Output Pwr: xx.xxxxx Freq : x.xxxxxx

Receive Freq: x.xxxxxx Modem Errors

Modem RSL :-xx.xxxx SNR :x.xxxxxx Lock:xxxxxxxx

Errors Last Err sec:xxxxxx Err sec 24h:xxxxxx

Versions FP:xxxxxxxxxx IDU/ODU

IDU/ODU Software/FPGA Configuration Firmware

Software/FPGA Kernel:xxxxxxxxxxxx Appl :xxxxxxxxxxxx FPGA :xxxxxxxxxxxx

Configuration ODU :xxxxxxxxxxxxx Modes:xxxxxxxxxxxxx Chan :xxxxxxxxxxxxx

Firmware ODU :xxxxxxxxx Boot :xxxxxxxxx Modm :xxxxxxxxx

2. System Description 9

Configuration ODU Control ODU Channel Administration

ODU Control Str Tx Pwr:x.xxxxx Mute :xxxxxx State :xxxxxx

Alarms Active Clear

1) mm-dd-yy hh:mm:ss xxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxx

2) mm-dd-yy hh:mm:ss xxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxx

ODU Channel Link Loopback

Link Freq:x.xxxxxx Link:QPSK-10.5Mbaud dataR=BaudR*mod

Loopback Type:combo of 3 LIU: combo Duration: combo

Are you sure?

Alarms Cleared

Administration xxxx days xxh:xxm FP Network IDU Network

FP Network IP :xxx.xxx.xxx.xxx Mask:xxx.xxx.xxx.xxx GW :xxx.xxx.xxx.xxx

IDU Network IP :xxx.xxx.xxx.xxx Mask:xxx.xxx.xxx.xxx GW :xxx.xxx.xxx.xxx

The front panel provides immediate and convenient access to these functions however much more extensive configuration and status information (status, alarm, graphical history, constellations, etc.) are provided via the NMS Ethernet interface and web GUI.

2.4.3Rear Panel Indicators

All models of the Event HD support a variety of rear panel configurations that are dependent on the network interface and capacity configurations.

Figure 2-2 provides an example of the Event HD 1+0 configuration and the associated LEDs displayed on the SDIDUTM rear panel. The controller, standard I/O, and each modem card have a status LED.

10 2. System Description

Controller

Status LED

Power/

Fault LED

Ethernet/

E1/T1

Status LED

DVB-ASI

Out Status

LED

DVB-ASI In Status LED

Modem

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.

LED STATUS

GREEN

ORANGE

Flashing GREEN

Flashing ORANGE

Active Locked Link

Standby Locked Link (1+1 Non-Diversity

Only)

Low SNR

Unlocked

2. System Description 11

Table 2-3. DVB-ASI Input status LED.

LED STATUS

GREEN

RED

Alternating

YELLOW/GRN

Flashing RED

Flashing GRN

Table 2-4. DVB-ASI Output status LED.

LED STATUS

GREEN

Alternating

RED/GREEN

GREEN,

occasionally

flashing YELLOW

Good ASI input

No ASI input

ASI exceeds radio bit rate

(FIFO overflow)

Loss-of-Frame

No ASI data

Active Locked ASI Link

No ASI, loss-of-frame

Locked ASI link with errors

(yellow flashes)

The controller status LED is the primary rear panel indicator of alarms. An alarm is generated when a specific condition is identified and is cleared when the specified condition is no longer detected. When an alarm is posted,

1. The controller status LED turns orange for 5 seconds

2. The controller status LED turns off for 5 seconds

3. The controller status LED flashes orange the number of times specified by the first digit of the alarm code

4. The controller status LED turns off for 3 seconds

5. The controller status LED flashes orange the number of times specified by the second digit of the alarm code

Steps 2-5 are repeated for each alarm posted. The entire process is repeated as long as the alarms are still posted.

12 2. System Description

NMS

Controller

Ethernet

-48V Power Input

100Base-T

Ethernet

Data

Channels

ASI

Output

ASI

Input

ODU IF

Connection

Redundant

Power-Supply

(optional for

1+1, 2+0)

ALARM/Serial

Interface

Redundant

MODEM

(optional for

1+1, 2+0)

USB

Ground

lug

Call

Button

Voice

Orderwire

Data

Orderwire

2xT1/E1

14xT1/E1

Ground

lug

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 H6.1.

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.

Figure 2-3. Software Defined IDU™-SB, 1+1 Protection: SDIDUTM Rear Panel

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. Pin 1 is the power supply return and is connected to unit chassis ground internally. Pin 2 should be supplied with a nominal 48 V dc, with respect to the unit chassis (ground). A ground-isolated supply may be used, provided it will tolerate grounding of its most positive output.

The recommended power input is 44 to 52 V dc at 2 Amps minimum. It is recommended that any power supply used be able to supply a minimum of 100 W to the SDIDUTM.

A mating power cable connector is supplied with the Software Defined IDU™. It is a 2-pin plug, 5 mm pitch, manufactured by Phoenix Contact, P/N 17 86 83 1 (connector type MSTB 2,5/2-STF). This connector has screw clamp terminals that accommodate 24 AWG to 12 AWG wire. The power cable wire should be selected to provide the appropriate current with minimal voltage drop, based on the power supply voltage and length of cable required. The recommended wire size for power cables under 10 feet in length supplying 48 Vdc is 18 AWG.

The SDIDUTM supplies the ODU with all required power via the ODU/SDIDUTM Interconnect cable. The Software Defined IDU™ does not have a power on/off switch. When DC power is connected to the SDIDUTM, the digital radio powers up and is operational. There can be up to 320 mW of RF power present at the antenna port (external antenna version). The antenna should be directed safely when power is applied.

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. Only the SDIDU’s™ link partner will receive the ring. VOW does not ring all nodes or support “party line” calls.

Voice Orderwire

RJ-45 modular port connector for voice orderwire interface.

Data Orderwire Connector

Data Orderwire

RJ-45 modular port connector for RS422/RS-232 data at 64 kbps.

NMS 10/100 Network Management System Connections

NMS 10/100 1

10/100Base-TX RJ-45 modular local port connector for access to the Network Management System (SNMP) and GUI.

NMS 10/100 2

10/100BaseTX RJ-45 modular remote port connector for access to the Network Management System (SNMP). This port to be used for consecutive point networks.

100/Ethernet Models: Ethernet 100BaseT Connections

USER 10/100 1

100Base-TX RJ-45 modular port connector for the local Fast Ethernet interface.

USER 10/100 2

100Base-TX RJ-45 modular port connector. This port to be used for consecutive point networks.

T1 Channels

T1 1-2

T1 3-8/16

Two T1/E1 (RJ-48C) interface connections.

Single Molex 60-pin connector containing 14 T1/E1 connections.

2. System Description 15

Unit ON

(Heartbeat)

-95

dBm

-15

dBm

Tx

Min

Tx

Max

Transmit

Power Level

(Bottom Row)

Receive Signal

Level

(Top Row)

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 In

OC-3 type SC connectors for the OC-3 interface.

STM-1 Connection (Optional Mini IO)

STM-1Out

STM-1 In

BNC connector for the STM-1 interface.

ODU/SDIDUTM Interconnect

To ODU

TNC female connector. Used to connect the ODU to the SDIDUTM. Provides –48VDC and 350 MHz Transmit IF to the ODU and receives 140 MHz Receive IF from the ODU.

Ground Connection

Ground Lug

Two ground lugs are provided on the rear panel. Either may be used to connect the SDIDU™ to ground.

2.4.5ODU LED Indicators

The ODU 2200, 6500, and 7200 has an externally visible LED meter that provides both RSL (Receive Signal Level) and transmit power. For full-duplex operation the ODU meter displays RSL on the top bar and transmit level on the bottom bar as shown in Figure 2-4.

Figure 2-4. ODU 2200 RSSI Output vs. Received Signal.

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).

The transmit LED indicates full power will all 8 LEDs illuminated to minimum power with 1 LED illuminated. For simplex applications the both rows indicate either RSL or transmit power.

2.5System Description

The overall Event-HD digital radio architecture consists of a single 1RU rack mount Software Defined Indoor UnitTM (SDIDUTM) with a cable connecting to an Outdoor Unit (ODU). The IF signal between the SDIDU and ODU operates at a relatively low frequency compared with the RF signal allowing for extensive cable runs in excess of 250 m with inexpensive coaxial cable with no degradation in radio performance.

The Event-HD ODU is mounted to a fixed or telescoping antenna mast near the desired antenna location providing a short cable run between ODU and antenna at the RF frequency. This SDIDU /ODU architecture is advantageous when compared to a single IDU (no ODU) with external mount antenna as operating at these RF frequencies from the IDU rack to the antenna will result in significant signal degradation and require expensive low-loss coaxial cable or waveguide.

FRAMER

DVB-ASI

DS-3/ES/

STS-1

2xSTM-1/

OC3

4xDS3/ES/

STS1

STM-1/OC3

64 kbps

Voice

16 T1/E1

User 2x

100Base-Tx

Switch

MODEM/

FEC ASIC

MODEM/

FEC ASIC

4x44.736/34.368/

51.84 Mbps

2x 155.52 Mbps

4x44.736/34.368/

51.84 Mbps

Up to 150 Mbps

2x 100 Mbps

16x 1.544/2.048

Mbps

Digital

IF

Quad

Mux

SNMP 2x

100Base-Tx

Switch

CPU

East/Primary Modem

West/Secondary Modem

Digital

IF

Quad

Mux

2x 100 Mbps

IDU

CONTROLLER

Optional I/O Cards

(Small Slot)

Standard I/O Cards

Optional I/O Cards

(Large Slot)

Primary Power

Supply

Secondary Power

Supply

Serial

RCH Serial

Modem Control

Telemetry

IDU

-48Vdc

Multiplexed

IF

Multiplexed

IF

155.52 Mbps

External Antenna

N-type

Internal/

Horizontal

Antenna

Transfer

Switch

Duplexer

Diversity

Switch

Vertical

Antenna

Unlicensed 5.3/5.8 GHz

Internal Duplexer Configuration

Tx

Rx

Duplexer

Short-Haul 6-38 GHz

Internal Duplexer Config

External Antenna

(Waveguide

Flange)

Tx

Rx

Transmitter

Up-Converter

Receiver

Down-Converter

350

MHz

140

MHz

DC/DC

Converters

-48Vdc

+10Vdc

+5Vdc +3Vdc

-5Vdc

Commlink

& Processor

5/10 MHz

ODU

RSL

(Received Signal Level)

Voltage

TNC

BNC

Quad

Mux

Tx Out

Tx Ext

Antenna

N-Type

Rx In

Rx Ext

Antenna

N-Type

2. System Description 17

Figure 2-5. Event-HD Block Diagram

Figure 2-5 shows the Event-HD digital radio and interfaces from a functional point of view. The functional partitions for the I/O, Modem/IF, power supply modules, up/down converters, and internal RF duplexing partition are shown. The SDIDUTM comes with the standard I/O capability which can be upgraded. The Modem/IF function is modular allowing the addition of a second Modem to support protection or ring architectures. The power supply is similarly modular. In addition, the ODUs are interchangeable allowing use of a single IDU in licensed, unlicensed, and short-haul applications by swapping the RF component.

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.

The Event-HD digital radio modem performs QPSK, 16-QAM, 32-QAM, 64-QAM, and 128QAM modulation and demodulation of the payload and forward error correction using advanced modulation and coding techniques. Using all-digital processing, the IF Modem uses robust modulation and forward error correction coding to minimize the number of bit errors and optimize the radio and network performance. The IF Modem also scrambles, descrambles and interleaves/deinterleaves the data stream in accordance with Intelsat standards to ensure modulation efficiency and resilience to sustained burst errors. The modulation will vary by application, data rate, and frequency spectrum. The highest order modulation mode supported is 128 Quadrature Amplitude Modulation (QAM). Table 2-5 summarizes the TCM/convolutional code rates for each modulation type supported by the Event-HD.

Table 2-5. Event-HD TCM/Convolutional Code Rates

Modulation Type Available Code Rates

QPSK 1/2, 3/4, 7/8

16-QAM 3/4, 7/8,

32-QAM 4/5, 9/10

64-QAM 5/6, 11/12

128-QAM 11/12

The major functions of the SDIDUTM can be summarized as follows:

• I/O Processing – Event-HD digital radio comes with a standard I/O capability that

includes support for up to 16xT1/E1 and 2x100Base-TX user payloads, 2x100Base-TX for SNMP, and voice orderwire. In addition, option cards for DVB-ASI, DS-3/E3/STS-1, 1-2 x STM-1/OC-3, and 4xDS-3/E3/STS-1 may be added. The EventHD architecture is flexible and allows for the addition of other I/O types in the future.

• Switch/Framing – The Event-HD digital radio includes an Ethernet Switch and a

proprietary Framer that are designed to support 1+1 protection switching, ring architecture routing, and overall network control functions.

• Network Processor – The Event-HD digital radio includes a Network Processor which

performs SNMP and Network Management functions.

• Modem/IF – The Event-HD digital radio modem performs forward-error-correction

(FEC) encoding, PSK/QAM modulation and demodulation, equalization, and FEC decoding functions. The IF chain provides a 350 MHz carrier and receives a 140 MHz

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 SDIDU

TM

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. It also provides configuration and control for both the IF and I/O cards. The SDIDU interfaces with the ODU to receive and provide modulated transmit and receive waveforms.

The Event-HD digital radio also provides the physical interface for the user payload and network management. In transmit mode, the Framer merges user payload (OC-3 or Fast Ethernet) with radio overhead-encapsulated network management data. This combined data stream is transmitted without any loss of user bandwidth. In the receive mode, the Framer separates the combined data stream received from the 256-QAM Modem. The SDIDUTM supports Scalable Ethernet data rates, such as 25 or 50 Mbps via the 100BaseT data interface port. The SDIDUTM provides network management data on 10 Mbps ports accessible via the 10/100BaseTX port. The Central Processor Unit (CPU) provides the embedded control and network element functionality of the OAM&P. The CPU also communicates with other functions within the SDIDUTM for configuration, control, and status monitoring. The CPU passes appropriate status information to the SDIDUTM rear panel display.

The power supply converts -48 Vdc to the DC voltage levels required by each component in the system.

2.6Consecutive Point Architecture

The consecutive point network architecture is based upon the proven SONET/SDH ring. Telecommunications service providers traditionally use the SONET/SDH ring architecture to implement their access networks. A typical SONET/SDH network consists of the service provider’s Point of Presence (POP) site and several customer sites with fiber optic cables connecting these sites in a ring configuration (see Figure 2-6). This architecture lets providers deliver high bandwidth with high availability to their customers.

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.

The consecutive point architecture implemented in the Moseley Digital Radio family is based on a point-to-point-to-point topology that mimics fiber rings, with broadband wireless links replacing in-ground fiber cable. A typical consecutive point network consists of a POP and several customer sites connected using Software Defined IDU™. These units are typically in a building in an east/west configuration. Using east/west configurations, each unit installed at a customer site is logically connected to two other units via an over-the-air radio frequency (RF) link to a unit at an adjacent site.

Each consecutive point network typically starts and ends at a POP. A pattern of wireless links and in-building connections is repeated at each site until all buildings in the network are connected in a ring as shown for an ethernet network in Figure 2-7. For 2 x 1+0 and 2 x 1+1 nodes payload and NMS connections need to be jumpered between two SDIDUTM. For 1 x 2+0 nodes, there is no need for jumpers as there is a single SDIDUTM. For SDH or SONET payloads, the configuration is similar but an external add/drop mux is required.

Moseley Associates EVENTHD Users Manual

Specifications and Main Features

Frequently Asked Questions

User Manual

1.Safety Precautions

2.System Description

2.1About This Manual

2.2Introduction

2.3System Features

2.4Physical Description

2.4.1Model Types

2.4.2Front Panel

2.4.3Rear Panel Indicators

2.4.4Rear Panel Connections

2.4.5ODU LED Indicators

2.5System Description

2.6Consecutive Point Architecture