User's Manual

ManualsBrandsVecima Networks ManualsElectronicsWireless LAN end-user modem

Table Of Contents

Contents
- Contents v
- Figures ix
- Tables xi
- Preface xv
- Index 261
Figures
Tables
Preface
- About this Manual
- Conventions
- Regulatory Notices
- Warnings and Advisories
- Customer Support
1 Introduction
2 Quick Startup
- 2.1 Equipment
- 2.2 Equipment Setup
- 2.3 CCU Configuration
- 2.4 EUM Configuration
- 2.5 Testing CCU–EUM Communications
- 2.6 Connecting the Quick Startup to the Internet
- 2.7 Adding more EUMs to the Quick Startup
3 Detailed Description
- 3.1 LMS4000 Overview
- 3.2 Communications Access Point
  - 3.2.1 Key Components
  - 3.2.2 Optional Components
- 3.3 Customer-premises Equipment
  - 3.3.1 Key Components
  - 3.3.2 EUM
- 3.4 Basic Operation
- 3.5 CCU–EUM Interface — Detailed Technical Description
  - 3.5.1 Physical Layer (DSSS Radio)
  - 3.5.2 MAC Layer (Polling MAC)
- 3.6 CCU and EUM Feature Description
4 IP Network Planning
- 4.1 LMS4000 IP Addressing
- 4.2 IP Planning Process
- 4.3 Network Address Translation
5 Radio Network Planning
- 5.1 Design Methodology
- 5.2 Basic System Design
- 5.3 Multi-CAP RF Network Design Considerations
6 Installation/Diagnostic Tools
- 6.1 Indicators and Connectors
- 6.2 Command-line Interface
- 6.3 EUM Configuration Utility
- 6.4 RSSI/Tx Quality/Antenna Pointing
- 6.5 Transfer a File to or from a CCU Using FTP
- 6.6 Operating Statistics
- 6.7 SNMP
- 6.8 Field Upgrade Process
- 6.9 FTPing CCU and EUM Configuration Files
7 Configuring the CCU
- 7.1 CCU and EUM Serial Number, MAC Address, and Station ID
- 7.2 Setting the CCU Password
- 7.3 Configuring the CCU RF Parameters
- 7.4 Configuring CCU IP Parameters
- 7.5 Configuring DHCP Relay
- 7.6 Configuring Port Filtering
- 7.7 Configuring the SNTP/UTC Time Clock
- 7.8 Configuring SNMP
- 7.9 Adding EUMs to the Authorization Table
8 Configuring the EUM
- 8.1 Setting the EUM Password
- 8.2 Configuring the EUM RF Parameters
- 8.3 Configuring EUM IP Parameters
- 8.4 Configuring Port Filtering
- 8.5 Configuring SNMP
- 8.6 Configuring the Customer List
9 Installing the EUM
- 9.1 Before you Start the EUM Installation
- 9.2 Other EUM Programming Considerations
- 9.3 Installation Overview
- 9.4 Installation Procedures
10 Maintaining the Network
- Maintaining Temperature and Humidity
- Cleaning the Equipment
- Checking the CCU Shelf Cooling Fans
11 Monitoring the Network
- 11.1 CCU Transmit Statistics
- 11.2 CCU Receive Statistics
- 11.3 EUM Statistics Monitoring
12 Troubleshooting
- 12.1 EUM Troubleshooting
- 12.2 CCU Troubleshooting
- 12.3 If You Have an Interferer
- 12.4 General Troubleshooting Information
- Network Address Translation
- Ethernet Cable Wiring
13 Specialized Applications
- 13.1 EUM Thin Route
- 13.2 EUM Backhaul
Appendix A Specifications
Appendix B Factory Configuration
Appendix C CommandLine Syntax
- Command-line Syntax Conventions and Shortcuts
- CCU Command-line Syntax
- EUM Command-line Syntax
Appendix D Antenna Guidelines
Appendix E CCU/EUM Data Tables
Appendix F Ping Commands
Appendix G SNMP MIB Definitions
- MIB-II Elements Supported from RFC-1213
  - Groups in MIB-II
  - Interfaces Group MIB
- WaveRider CCU Enterprise MIBs
- CCU RFC MIB-II Traps
  - RFC MIB-II Traps
- WaveRider EUM Enterprise MIBs
- EUM RFC MIB-II Traps
  - RFC MIB-II Traps
Appendix H Operating Statistics
- Ethernet Statistics
- Radio Driver Statistics
- MAC Interface Statistics
- Routing/Bridging Protocol Statistics
- Network Interface Statistics
- System Load Statistics (Radio Meter)
Appendix I IP Plan — Example
- NAP IP Addressing Plan
- CCU Ethernet IP Addressing Plan
- CCU Radio IP Addressing Plan
- EUM IP Addressing Plan
- Subscriber IP Addressing Plan
Appendix J Acronyms and Glossary
Index

3 Detailed Description

32 APCD-LM043-4.0

NLOS exists when the path between the CCU and EUM is obstructed, or partially obstructed,

by terrain, buildings, or foliage. NLOS is illustrated in Figure 19. Since radio waves reflect,

refract, and diffract, a non line of sight path does not necessarily mean the EUM-CCU radio

link does not have enough signal margin. It simply means that the path loss is be greater than

the LOS path loss. Within the engineered NLOS coverage range of the CCU, the NLOS path,

using an indoor antenna, is acceptable for most EUM installations.

Figure 19 Typical NLOS Path

It is difficult to accurately predict NLOS path loss; however, a lot of field data has been

collected and factored into commercially available path-prediction software.

LMS4000 900 MHz radio coverage prediction depends on the following:

• CCU radio output power, transmission-line losses, and antenna height and gain

• Length of the path between the CCU and EUM

• Height of terrain, foliage, and buildings along the path between the CCU and EUM,

which determines the percentage of the path that is obstructed.

• EUM antenna height and gain, transmission-line losses, and receiver sensitivity

• If the EUM antenna is installed indoors, location of the EUM antenna within the end-

user premises, and the premises building type and wall construction

The EUM has been designed to work with the WaveRider indoor switched-beam diversity

antenna. Where greater range is required, outdoor EUM antennas are also available.

Generally, the higher the CCU antenna, the better the range, especially for LOS performance.

Ideally, the CCU antenna should be installed well above the average height of trees in the

vicinity of the CCU.