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300 24 Manual Replace Sheet | Users Manual | 414.20 KiB | / April 06 2001 | |||
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I Will 30024 Manual | Users Manual | 867.18 KiB | / April 06 2001 | |||
| 1 | Parts List/Tune Up Info | native | / April 06 2001 | |||||
| 1 | RF Exposure Info | / April 06 2001 | ||||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | Block Diagram | / April 06 2001 | ||||||
| 1 | ID Label/Location Info | / April 06 2001 | ||||||
| 1 | Cover Letter(s) | / April 06 2001 | ||||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | Test Report | / April 06 2001 | ||||||
| 1 | External Photos | native | / April 06 2001 | |||||
| 1 | Test Report | / April 06 2001 | ||||||
| 1 | Attestation Statements | / April 06 2001 | ||||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | External Photos | native | / April 06 2001 | |||||
| 1 | Test Report | / April 06 2001 | ||||||
| 1 | Internal Photos | native | / April 06 2001 | |||||
| 1 | Internal Photos | native | / April 06 2001 |
| 1 | 300 24 Manual Replace Sheet | Users Manual | 414.20 KiB | / April 06 2001 |
Change to I.WiLL 300-24 Access Point Manual May 2001 Please replace pages 1920 of the I.WiLL 300-24 Access Point manual (Version 1.1 - 02/00) with the attached replacement page. Information about EIRP has been claried and corrected on the replacement page. MAY 2001 1 Unlike the Tx output power of the devices, EIRP is subject to both antenna gain and cable losses. Calculating the Link Budget Calculating EIRP (Effective Isotropic Radiated Power) EIRP is the power radiating from an antenna taking into account the output power from the transmitter, the connector and cable losses, and the antenna gain. Because many antennas can provide a directional gain, the effective radiated power can increase. Losses, such as cable losses can subtract from this amount. You calculate the EIRP as follows:
Formula:
Note:
EIRP = Tx Power (dBm) - Cable Losses (dBm) - Connector Losses
(dBm) + Antenna Gain (dB) The FCC regulatory body has set the peak EIRP limit to 400 mW for multipoint and fixed point-to-point applications per FCC 01-158 with a peak power output of 100 mW. Only the antenna with which the equipment is authorized may be used per FCC 47 CFR 15.204(c). Industry Canada RSS-139, Annex B specifies the maximum transmitter output at +30dBm, with a maximum EIRP (Equivalent Isotropically Radiated Power) at +36dBm for multi-point configurations and a maximum EIRP of +53dBm only for licensed point-to-point applications. In accordance with ETS 300-328 for 2.4GHz RLANs, the maximum EIRP shall not exceed +20dBm, with a maximum SPD (Spectral Power Density) not exceeding +10dBm/MHz. Confirmation is required with the relevant European national radio communications local authority for deviations from this specification. Note:
All EIRP work must be completed by a professional installer. In some situations, you may want to use an omni-directional antenna in your Working with Antenna Gain To ensure the best range and interference suppression, the external antenna should be directional, focusing the radio energy in one direction (toward the other end of the link). The direction can be azmuthal or a horizontal radiation angle. A directional antenna focuses the RF energy to the intended station rather than omni-directionally. This reduces interference from other systems that are operating at the same frequency. Note:
system design. For example, you would use an omni-directional antenna for a base station with remote sites situated in a 360 path around it. When you select an antenna, pay particular attention to the gain specification. When you select an antenna for a remote station, select an antenna with a gain that provides at least 13dB Fade Margin. Antenna gain is specified in either dBi or dBd. When an antenna is specified in dBd, add 2.14dB to the value to convert it to dBi. Note:
All antenna gain work must be completed by a professional installer. Version 1.1 - 05/01 19 Determining the RF Link Calculating Propagation Loss The propagation loss is the attenuation (reduction) in RF signal energy as it travels through space. In most wireless systems, losses through space are the major contributor to signal attenuation. When you know the intended installation locations of the base and remote stations, determine the physical line of sight distance and then calculate the RF attenuation as follows:
Formula:
Note:
Attenuation (dB) = 100dB + 20log(d where:
d
= Distance in Kilometers km 100dB = Pathloss Constant
) km The FCC regulatory body has set the peak EIRP limit to 400 mW for multipoint and fixed point-to-point applications per FCC 01-158 with a peak power output of 100 mW. Only the antenna with which the equipment is authorized may be used per FCC 47 CFR 15.204(c). Industry Canada RSS-139, Annex B specifies the maximum transmitter output at +30dBm, with a maximum EIRP (Equivalent Isotropically Radiated Power) at +36dBm for multi-point configurations and a maximum EIRP of +53dBm only for licensed point-to-point applications. Industry Canada RSS-139, Annex B specifies the maximum transmitter output at +30dBm, with a maximum EIRP (Equivalent Isotropically Radiated Power) at +36dBm for multi-point configurations and a maximum EIRP of +53dBm only for licensed point-to-point applications. In accordance with ETS 300-328 for 2.4GHz RLANs, the maximum EIRP shall not exceed +20dBm, with a maximum SPD (Spectral Power Density) not exceeding +10dBm/MHz. Confirmation is required with the relevant European national radiocommunications local authority for deviations from this specification. Note:
All propagation loss work must be completed by a professional installer. Working with the Fresnel Zone It is essential to locate your antennas at maximum above-ground height to ensure the most effective and reliable link. Achieving maximum above-ground antenna height means that:
all ground-based obstructions are cleared from the line-of-sight path the Fresnel Zone is clear of obstructions 20 Version 1.1 - 05/01
| 1 | I Will 30024 Manual | Users Manual | 867.18 KiB | / April 06 2001 |
Contents Welcome ..................................................................... 1 Overview of the I.WiLL 300-24 Access Point .........................................1 About this Guide ........................................................................................1 Whats in this Guide ...................................................................................1 Conventions Used in this Guide .................................................................2 Customer Support ......................................................................................3 Contacting Customer Support ..............................................................3 Get Started .................................................................. 5 Overview ....................................................................................................5 Understanding the Front and Back Panels ................................................5 The Front Panel ....................................................................................5 The Back Panel ....................................................................................7 Completing Pre-Installation ...................................... 9 Overview ....................................................................................................9 Installation Requirements ..........................................................................9 Planning the Physical Layout ...................................................................10 Determining the Physical Distance Between Sites .............................10 Working with Antennas .......................................................................10 Determining Cable Requirements ......................................................11 Working with Fade Margins ................................................................11 Assessing the Weatherproofing Requirements ..................................11 Pre-configuring the Stations .....................................................................11 Pre-configuring Stations .....................................................................11 Pre-configuring the Polling List ...........................................................14 Bench Testing the 300-24 ........................................................................16 Determining the RF Link ......................................... 17 Overview ..................................................................................................17 Calculating the Link Budget .....................................................................17 Link Budget Variables .........................................................................18 Working with System Gain .................................................................18 Version 1.1 - 01/04/00 i Contents Calculating ERP (Effective Radiated Power) ..................................... 19 Working with Antenna Gain ............................................................... 19 Calculating Propagation Loss ............................................................ 20 Calculating Cable Loss ...................................................................... 21 Calculating Path Loss ........................................................................ 22 Link Budget Example .............................................................................. 23 Verifying a Link Budget ........................................................................... 24 Reviewing the Link Statistics ............................................................. 24 Installing Base and Remote Stations ..................... 27 Overview ................................................................................................. 27 Installing the Antenna .............................................................................. 27 Powering Up the Units ............................................................................. 27 Verifying the RF Port .......................................................................... 28 Fine-tuning Antennas ......................................................................... 29 Completing the Installation Connections ............................................ 29 Installing the Units on a Rack .................................................................. 30 Configuring Using the Menus ................................. 31 Overview ................................................................................................. 31 Navigating the Configuration Menus ....................................................... 31 Accessing the Menus ......................................................................... 31 Using the Console .............................................................................. 32 Using Telnet ....................................................................................... 33 Exiting the Configuration Menus ........................................................ 34 Viewing System Information .................................................................... 35 Viewing System Revision Information ................................................ 35 Viewing System Software ROM Images ............................................ 36 Viewing Current System Status ......................................................... 37 Viewing the MAC Layer Statistics ...................................................... 39 Setting the System Security .................................................................... 42 Setting Access Types ........................................................................ 42 Setting Community Names ................................................................ 43 Setting Passwords ............................................................................. 44 Setting Automatic Timeouts ............................................................... 45 Working with System Images .................................................................. 46 Setting the Default Image .................................................................. 46 Rebooting Images .............................................................................. 47 Restoring Configurations ......................................................................... 48 Working with Modes ................................................................................ 49 Resetting the Statistics ............................................................................ 50 Configuring the Internet IP Settings ........................................................ 52 Setting the Internet IP Address .......................................................... 52 Setting the Ethernet MAC Address .................................................... 53 Setting the IP Routing Options ........................................................... 54 ii Version 1.1 - 01/04/00 Contents Setting the Default Gateway IP Address ............................................55 Setting the SNMP NMS Trap IP Address ...........................................55 Configuring the Radio ..............................................................................57 Setting the OFDM Station Type ..........................................................57 Setting the RF IDs and Center Frequency .........................................58 Configuring the IP Filter for a Remote Station ....................................59 Configuring the Polling List .................................................................61 Using the 300-24 Command Line ............................................................63 Using the Basic Commands ...............................................................63 Using SNMP .............................................................. 65 Using the Wi-LAN SNMP MIB ..................................................................65 Using the Wi-LAN MIB Object Identifier Nodes .......................................66 Wi-LAN MIB Object Identifier Nodes ..................................................67 Appendix A: Product Specification ........................ 73 Overview ..................................................................................................73 Specification .............................................................................................73 Appendix B: Monitor and Test Links ...................... 75 Overview ..................................................................................................75 Monitoring RSSI .......................................................................................75 Monitoring Null Depth ..............................................................................76 Monitoring Fade Margin ...........................................................................76 Performing a Link Test .............................................................................76 Appendix C: Upgrading Software ........................... 79 Overview ..................................................................................................79 Upgrading Software via FTP ....................................................................79 Using the Upgraded Software ............................................................81 Glossary .................................................................... 83 Index .......................................................................... 89 Version 1.1 - 01/04/00 iii Contents iv Version 1.1 - 01/04/00 Notices Copyright Notice This guide and the application and hardware described herein are furnished under license and are subject to a confidentiality agreement. The software and hardware can be used only in accordance with the terms and conditions of this agreement. No part of this guide may be reproduced or transmitted in any form or by any means electronic, mechanical, or otherwise, including photocopying and recordingwithout the express written permission of Wi-LAN, Inc. While every effort has been made to ensure that the information contained in this guide is correct, Wi-LAN, Inc. does not warrant the information is free of errors or omissions. Information contained in this guide is subject to change without notice. Copyright November 1999 Wi-LAN, Inc. All rights reserved. Published and printed in Canada. Wi-LAN, Inc. Suite 300, 801 Manning Road S.E. Calgary, Alberta CANADA Tel: +1-403.273.9133 Users Notice The device presented in this guide complies with:
RSS-139 of Industry Canada Note: The user must apply for a site license in Canada for outdoor operation. The operational frequency range of 2450-2483.5MHz is recommended for approval. Use Industry Canada license application form: IC-2365, and consult Radio Standard Procedure: RSP-101, issued by Industry Canada.
(Part III of RSP-101 is not required as equipment is RSS-139 certified). FCC part 15
CEPT/ERC Recommendations, ETS 300-328, ETS 300-826, and EN 60950 The specifications and parameters of the device described in this document are subject to change without notice. Operation is subject to the following two conditions:
this device may not cause interference this device must accept any interference, including interference that may cause undesired operation of the device. Version 1.1 - 01/04/00 v
Notices This equipment generates, uses, and radiates radio frequency and, if not installed and used in accordance with this guide, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following methods:
reorient or relocate the receiving antenna increase the separation between the equipment and receiver connect equipment to an outlet on a circuit different from that to which the receiver is connected consult the dealer or an experienced radio/TV technician for help As the 300-24 is used on a license-exempt, non-frequency coordinated, unprotected spectrum allocation, and thus can be subject to random unidentified interference, applications must not be those of a primary control where a lack of intercommunication could cause danger to property, process, or person. An alternative fail-safe should be designed into any system to ensure safe operation or shut down, should communication be lost for any reason. Important Notices
Changes or modifications to the equipment not expressly approved by Wi-LAN, Inc., could void the users authority to operate the equipment.
Appropriately shielded remote I/O serial cable with the metal connector shell and cable shield properly connected to chassis ground shall be used to reduce the radio frequency interference. FCC radio frequency exposure limits may be exceeded at distances closer than 23 centimeters from the antenna of this device.
All antenna installation work shall be carried out by a knowledgeable and professional installer. vi Version 1.1 - 01/04/00
Welcome Overview of the I.WiLL 300-24 Access Point The I.WiLL 300-24 Access Point (300-24) is the first Wi-LAN product based on the Wide-band Orthogonal Frequency Division Multiplexing (W-OFDM) technology. With a peak data rate of 30 Mbps in 25 MHz of bandwidth, the 300-24 demonstrates the industrys most efficient use of bandwidth. The Dynamic Time Allocation technique allocates variable time slots to busy stations when needed. Valuable bandwidth is not wasted allocating time to idle stations. The 300-24 operates in the 2.4-2.4835 GHz license-exempt ISM band allowing you to provide wireless networking connectivity at a fraction of the wire, cable, or fibre networking costs. You can manage, configure, and monitor the entire wireless network through the RS-232 management port, SNMP, or telnet. About this Guide This guide provides instruction on how to install and configure your 300-24. The guide is intended for individuals with basic experience installing and configuring telecommunications and networking equipment. For assistance installing and configuring the 300-24 contact Wi-LAN support. See Customer Support on page 3 for information about contacting Wi-LAN. Whats in this Guide The following table shows the information in each section of this guide:
This section... Welcome Get Started Completing Pre-Installation Contains this information... An overview of the 300-24, identifying who should use this guide, how to obtain customer support, and introducing the terms used in this guide. An introduction to the 300-24 front and back panels, and a description of the LEDs and connectors on the panels. A list of the installation requirements, instruction on how to complete preliminary layout of your 300-24 system, including working with antennas and fade margins, and pre-configuring the unit. Version 1.1 - 01/04/00 1 Welcome This section... Contains this information... Determining the RF Link Installing Base and Remote Stations Configuring Using the Menus Using SNMP Instruction on how to plan your RF link, calculate the link budget, and an example of a link budget calculation. Instruction on how to install the base and remote stations, including antenna installation, rack installation, and working with the fade margin. Step-by-step instruction on configuring the 300-24 using the configuration menus. A detailed description of the Wi-LAN SNMP MIB object identifier nodes specific to the 300-24. Appendix A: Product Specifications Specific technical details of the 300-24. Appendix B: Monitor Link Mode Appendix C: Upgrading Software Glossary Index Details about how to monitor the link mode including monitoring the RSSI, null depth, and fade margin. Instruction on how to upgrade the board software using FTP. An alphabetical list of the terms used in this guide. A detailed alphabetical index of this guide. Conventions Used in this Guide This guide uses specific typographic conventions to help you work with the guide when you install and configure the 300-24. The following conventions are used:
This... italic text bold arial bold serif Select Press Indicates... For example... A configuration menu screen. Main System menu A menu item you select or a key you press on the keyboard. Text that you type into a configuration menu. To move the arrow cursor (->) beside the menu item in the configuration menu. To press a key on your keyboard. Select System Commands or Press the Enter key On the command line, type telnet <IP address>
Select System Commands Press the Enter key 2 Version 1.1 - 01/04/00 Customer Support This... Indicates... For example... Entry field Scroll menu window A field beside a menu item into which you can type or select a configuration option. The OFDM Station Type entry field To press the up and down arrow keys to move through items in an active entry field. In the OFDM Station Type entry field, scroll to select Base Unit A configuration screen where you can select and apply a configuration setting. A configuration screen where you can only view information. You cannot select any configuration settings from the menu. The Main System menu The System Software ROM Images window Customer Support You can contact Wi-LANs applications engineers to help you troubleshoot your Wi-LAN products and your wireless network applications. Our applications engineers are also available to help you identify the most cost-effective solutions or configurations for your applications. Contacting Customer Support You can contact Wi-LAN customer support by:
For this location... Contact support by... Canada and USA Outside North America Calling toll free: +1-800 258 6876 Available from: 6:00 a.m. to 5:00 p.m. (GMT-7:00) Calling:
Available from: 6:00 a.m. to 5:00 p.m. (GMT-7:00)
+1-403 273 9133 All locations Sending an e-mail message to:
techsupport@wi-lan.com You can also contact the Wi-LAN dealer or representative in your region. Call Wi-LAN at the support numbers indicated above for the dealer in your area, or send an e-mail message to techsupport@wi-lan.com. Version 1.1 - 01/04/00 3 Welcome 4 Version 1.1 - 01/04/00 Get Started Overview The I.WiLL 300-24 Access Point (300-24) is a multi-point product that allows wireless connection of remote computers or LAN segments at signaling rates up to 30 Mbps. The unit is self-contained and easy to use. You do not need installation disks or software drivers to get started. You simply connect the 300-24 to each LAN segment. This section introduces you to the front and back panels of the 300-24 and describes the connectors and LEDs on the panels. Understanding the Front and Back Panels The 300-24 has connectors on the back and front panels that you need to be familiar with before you install and configure the unit. You should also understand the color states of the LEDs on the front panel. The Front Panel Following is an illustration of the front panel:
LED Indicators Serial Port Connector Front Panel Description Following is a description of the connector on the panel:
Connector Type Description RJ11 Serial Port Connector Enables you to configure the 300-24 using the RS-232 Serial Port Interface. Only Data Transmit, Data Receive, and Ground are used (pins 2, 3, and 5 respectively). Note: You may have to use a male DB9 adaptor to connect to the PC. Version 1.1 - 01/04/00 5 Get Started During normal operation, the Tx and Rx LEDs blink. Front Panel LEDs The front panel has seven LEDs (Light Emitting Diodes) that indicate the normal operational status of the transceiver. Following are the LED color states and their associated status:
LED Type Link - 10BT Link - 100BT LAN - Tx LAN - Rx RF - Tx RF - Rx Power Color Green Off Green Off Green Off Green Off Green Off Green Off Green Orange Off Status Active 10BaseT ethernet connection Inactive 10BaseT ethernet connection Active 100BaseT ethernet connection Inactive 100BaseT ethernet connection Transmitting to the wire (ethernet) Inactive LAN Tx Receiving from the wire (ethernet) Inactive LAN Rx Transmitting to the air Inactive RF Tx Receiving from the air Inactive RF Rx Power is connected to the transceiver Power on self test No power is connected to the transceiver 6 Version 1.1 - 01/04/00 Understanding the Front and Back Panels The Back Panel Following is an illustration of the back panel:
AC Power Level Switch Attaching Screw Ground Screw DB9 Serial Port
(configuration management) 10/100 BaseT Ethernet Connector Antenna Connector
(requires N-Type connector) AC Power Connector Back Panel Description Following are descriptions of the items on the back panel:
Item Description 10/100 BaseT Ethernet Connector (RJ45 connector) DB9 Serial Port
(configuration management) Antenna Connector Ground Screw The RJ45 connector uses a standard 10/100BaseT pin out. The connector auto-negotiates the level requirements; it automatically sets the network media support level. Note: Cabling between 10/100baseT nodes is usually through a network hub. To make a direct 10/100baseT connection between a 300-24 and a PC, use a standard ethernet crossover cable. Enables you to configure the 300-24 using the RS-232 Serial Port Interface. Only Data Transmit, Data Receive, and Ground are used (pins 2, 3, and 5 respectively) - straight-through cable. Enables you to connect an antenna to the 300-24. You must use an N-Type connector for all antennas. Note: All antenna installation work shall be carried out by a knowledgeable and professional installer. Enables you to attach a bared 18 gauge or better ground wire to ground the unit. You would use this grounding when the ground provided by the power cable is not adequate or does not meet the users installation requirements. Version 1.1 - 01/04/00 7 Get Started Grounding the 300-24 If the power cable used in your installation does not have adequate grounding, or if the grounding does not meet your installation requirements, you will need to ground the unit using the ground screw located on the back of the unit. This might occur if you you are installing the unit on a rack, where solid chassis grounds are mandated by the installation specialists. The ground wire should be 18 gauge or better and the other end of the wire should be connected to the rack in the case of a rack mounted installation, or to the customers facility grounding system. Following is an enlarged view of the ground screw identified in The Back Panel on page 7:
Rear View ground screw ground screw Side View hole for ground wire When you ground the unit, you need to insert the ground wire into the hole for the ground wire and then tighten the ground screw to secure the wire. With a separate ground installed, the 300-24 may have a better earth ground than the local AC power outlets; an isolation transformer or laptop PC may be required if ground loop noise becomes troublesome. Proper electrostatic precautions must be followed. 8 Version 1.1 - 01/04/00 Completing Pre-Installation Overview Before you install the I.WiLL 300-24 Access Point (300-24) you must perform certain preliminary steps to ensure an effective and reliable wireless link. These steps include:
gathering your required installation tools, accessories, and power supplies determining the physical layout of your planned link planning your antenna and fade margin requirements pre-configuring the stations bench testing the units in a controlled environment Each of these steps is described in this section. Installation Requirements Before you install the 300-24, you should have the following tools and accessories available:
10-32 x 3/4 Phillips oval head screws with plastic cup washers
(Hammond P/N 1421 A for rack mount) 50 ohm coaxial cable (outdoor installation site)
Allen Hex Driver/Allen Key 5/64"
Robertson No. 0 screwdriver EPROM extractor for PLCC package EPROM extractor for DIP package
Nut driver 3/16"
Ensure that the 300-24 shipping package contains the following items:
rubber duck antenna
N-Type male to TNC female adaptor (for installing the rubber duck antenna)
DB9 adaptor (F) to 6 cond (RJ11) power supply cord straight-through ethernet cable (RJ45) crossover ethernet cable (RJ45)
DB9 (M) to DB25 (F) adaptor
RJ11 serial port cable (14 modular plug)
RS-232 DB9 serial cable Version 1.1 - 01/04/00 9
Completing Pre-Installation I.WiLL 300-24 Access Point Installation and Configuration Guide
Wi-LAN Documentation CD
Warranty Card If any of the above items are not included in the 300-24 shipping package, please contact Wi-LAN customer support. See Customer Support on page 3 for information on how to contact Wi-LAN. Planning the Physical Layout Before you install the units, you must determine the physical locations for each component of your 300-24 system. When you plan the physical layout, you will need to:
use a GPS, map, or other distance measurement method to determine the physical distance between each unit You must have a professional installer assess and calculate the following:
the antenna mast height requirements and fade margins the cable requirements including routing, between antenna and unit the fade margin to determine the reliability of your wireless link the weatherproofing requirements Determining the Physical Distance Between Sites Before you install the units, use a mapping method to determine the distance between your sites. When you determine the distance, you must check the radio path to identify any obstructions in the site path between radio locations. You can contact a Wi-LAN applications engineer to confirm that you have planned an effective radio layout. See Customer Support on page 3 for more information about contacting Wi-LAN. Working with Antennas If you are installing the unit in an indoor setting, the antenna packaged with the unit will be sufficient for indoor wireless communications. If you are installing the unit in an outdoor location, a professional installer must calculate the required mast height to ensure effective communication between your radio links. When installing an outdoor antenna, the professional installer should consider:
the required height of the antenna to ensure a clear line-of-site between the RF links regulatory restrictions, such as height, on antenna mast usage in the identified location obtaining permission from building owners if you intend to install your antenna on a rooftop potential wind load and ice loading impact on the antenna grounding requirements. The antenna must be properly grounded for lightening in accordance with the relevant electrical code for the installation location. See Working with Antenna Gain on page 19 or see the 300-24 Product Specification for more information about installing and selecting antennas in outdoor locations. Due to the high frequency and low output powers permitted in the ISM band, no obstructions can be tolerated between two antennas. You should use lightening arrestors to ground your outdoor antenna, cables, and support structures. 10 Version 1.1 - 01/04/00
Pre-configuring the Stations Determining Cable Requirements If you are installing the antenna in an outdoor location, you will require 50 ohm coaxial cable to connect the unit to the antenna. You must minimize the length of the cable between the unit and antenna; the longer the cable length the greater the dB loss. You must calculate the required cable lengths before you install the 300-24. Notes:
You should use surge suppressors at the point of cable entry into the building.
All cabling work must be carried out by a professional installer. Working with Fade Margins Once youve identified the physical locations of your antennas, the height of the antennas, and the cable length required, you can calculate the fade margin for your wireless link. The fade margin enables you to predict the reliability of your wireless link. See Calculating Path Loss on page 22 for more information about fade margins. Note: The fade margin work must be carried out by a professional installer. Assessing the Weatherproofing Requirements All 300-24 units must be located in a weatherproof environment with an ambient temperature between 0 and 30 Celsius. You must consider the building, heating, and air conditioning requirements to ensure that the unit operates within these conditions. Use surge suppressors at the point of cable entry into your building. Pre-configuring the Stations Typically, the physical layout of a 300-24 system involves significant distances between units. To ensure the efficiency of your wireless links you must pre-configure the following:
a base station remote stations the polling list You must assign each 300-24 unit a unique RF Station ID and configure the polling list before the unit will function properly. These steps must be completed and verified before you install any units. Pre-configuring Stations You must designate each 300-24 unit as a base or remote station and assign each 300-24 unit with a unique RF Station ID. See Configuring Using the Menus on page 31 for instruction on using all of the configuration menus. Version 1.1 - 01/04/00 11
Completing Pre-Installation Differences Between the Remote and Base Station Menus The options that appear in the Main System menu vary depending whether you configured the 300-24 unit as a base station or as a remote station. Following are the differences in the Main System menu:
For this station type... This option appears... Remote Station IP Filter Configuration Base Station Remote Station Configuration This option does not appear... Remote Station Configuration IP Filter Configuration To configure a 300-24 unit as a base or remote station 1. Connect a computer to the 300-24 unit via the RS-232 serial port. Note: The computer should be powered down when you connect it to the 300-24. 2. Power up the computer. The Login menu appears. 3. At the Enter Password prompt, type your User Password. Note: When you start the 300-24 unit for the first time, the following user names and passwords apply:
User Name Password Access Level user user Read-only access supervisor supervisor Read/write access 4. Press the Enter key. The Main System menu appears:
Main System Menu
-> System Revision Information System Software ROM Images System Current Status System Security System Commands Network Configuration Radio Configuration IP Filter Configuration MAC Layer Statistics IP Filter Configuration only appears in the Main System menu for units configured as remote stations. 12 Version 1.1 - 01/04/00 Pre-configuring the Stations Use the up and down arrow keys on the keyboard to select a menu item. 5. Select Radio Configuration. 6. Press the Enter key. The Radio Configuration menu appears:
Radio Configuration OFDM Station Type -> Remote Unit RF Station Id [0..1023] 2 RF Network Id [0..1023] 0 RF Center Frequency 2.440 GHz 7. Select OFDM Station Type. 8. Press the Enter key. The OFDM Station Type entry field is highlighted. 9. Complete the following steps depending on the type of station you are configuring:
To configure a... Do this... Base Station Remote Station In the OFDM Station Type entry field, scroll to select Base Unit. In the OFDM Station Type entry field, scroll to select Remote Unit. 10. Press the Enter key. The unit is configured to the selected unit type. 11. Leave the Radio Configuration menu open. To assign the base station or remote station an RF Station ID In the Radio Configuration menu, select RF Station ID [0..1023]. 1. Radio Configuration OFDM Station Type Remote Unit RF Station Id [0..1023] -> 2 RF Network Id [0..1023] 0 RF Center Frequency 2.440 GHz 2. Press the Enter key. The RF Station ID entry field is highlighted. 3. Type a unique number for the RF Station ID. 4. Press the Enter key. The unit is assigned the RF Station ID. 5. Make a note of the RF Station ID you assigned to the unit. Every unit you configure must have a unique RF Station ID. No two units can have the same ID. Version 1.1 - 01/04/00 13 Completing Pre-Installation 6. Press the Esc key until you exit the Configuration menu. 7. Power down the computer. You have completed the pre-configuration for the unit. 8. Repeat the steps in To configure a 300-24 unit as a base or remote station and To assign the base station or remote station an RF Station ID for each unit you need to pre-configure. Pre-configuring the Polling List 1. Connect a computer to the 300-24 unit you configured as a base station via the RS-232 serial port. Note: The computer should be off when you connect it to the 300-24. 2. Power up the computer. The Login menu appears. 3. At the Enter Password prompt, type your User Password. Note: When you start the 300-24 unit for the first time, the following user names and passwords apply:
You pre-configure the polling list for only the base station. User Name Password Access Level user user Read-only access supervisor supervisor Read/write access 4. Press the Enter key. The Main System menu appears:
Main System Menu
-> System Revision Information System Software ROM Images System Current Status System Security System Commands Network Configuration Radio Configuration Remote Station Configuration MAC Layer Statistics Remote Station Configuration only appears in the Main System menu for units configured as the base station. 14 Version 1.1 - 01/04/00 The Remote Station Configuration menu is two pages. The polling list can contain up to 100 stations. Pre-configuring the Stations 5. Select Remote Station Configuration. The Remote Station Configuration menu appears:
Remote Station Configuration - Page 1 Remote Radio Id Distance Remote Radio Id Distance Remote Radio Id Distance Number 0..1023 0..9999 Number 0..1023 0..9999 Number 0..1023 0..9999 1 ->1 1900 2 2 1900 3 0 0 4 0 0 5 0 0 6 0 0 7 0 0 8 0 0 9 0 0 10 0 0 11 0 0 12 0 0 13 0 0 14 0 0 15 0 0 16 0 0 17 0 0 18 0 0 19 0 0 20 0 0 21 0 0 22 0 0 23 0 0 24 0 0 25 0 0 26 0 0 27 0 0 28 0 0 29 0 0 30 0 0 31 0 0 32 0 0 33 0 0 34 0 0 35 0 0 36 0 0 37 0 0 38 0 0 39 0 0 40 0 0 41 0 0 42 0 0 43 0 0 44 0 0 45 0 0 46 0 0 47 0 0 48 0 0 49 0 0 50 0 0 51 0 0 52 0 0 53 0 0 54 0 0 55 0 0 56 0 0 57 0 0 6. 7. In the Radio Id field, type the Radio Station ID for the station (you must identify a unique Radio Id for all remotes and the base station). Note: The order in which you enter the IDs determines the polling sequence of the units. In the Distance field, type the distance, in meters, from the Radio ID to the base station. Following is an example of a completed polling list entry:
Remote Radio Id Distance Number 0..1023 0..9999 1 ->1 1900 The RF Station ID 1 is 1900 meters from the base station. The RF Station ID is 1. The station is the first item in the polling list. 8. Once you have entered the ID and distance for each remote station and the base station, press the Esc key until you exit the Configuration menu. 9. Power down the computer. You have pre-configured the polling list. Version 1.1 - 01/04/00 15 Completing Pre-Installation Bench Testing the 300-24 Before you deploy the 300-24 unit into a network configuration, you should familiarize yourself with the equipment by bench testing the unit in a controlled environment. The receiver portion of the 300-24 unit is extremely sensitive, and the high sensitivity of the radio receiver can make testing in small environments difficult. Close proximity of the transmitter will overwhelm the radios receiver. When you conduct your bench test, ensure that there is five feet between the two units. You will need the following equipment to bench test the unit:
2 x portable or laptop computers with functioning 10/100 Ethernet adaptors 1 x 5 feet RG58 cables (terminated N Male x SMA Female) 1 x 5 feet RG58 cables (terminated N Male x SMA Male) 1 x 60 dB attenuation @ 2.44 Ghz (can be accommodated by 2 x 30 attenuators) 1 x straight-through RS232 cable DB9 x DB9 2 x Ethernet crossover cable To bench test the 300-24 1. Use one of the Ethernet crossover cables to set up a peer-to-peer network between the two PCs. 2. Verify network operation by transferring a file between the two PCs. 3. Pre-configure each of the 300-24 units. Refer to Pre-configuring the Stations on page 11 for instructions on pre-configuring the units. Insert the attenuation between the two RG58 cables. 4. 5. Connect the opposite ends of the cables to each 300-24 unit. This creates a controlled path between the units of a known path loss. 6. Perform the link test between the two units. Refer to Viewing the MAC Layer Statistics on page 39 and Appendix B: Monitor and Test Links on page 75 for information about link tests. Using the required cables and attenuation for this bench test, the fade margin should be 32 dB ( 3 dB). 7. Finally, connect each PC to the 300-24 devices via the Ethernet cables. 8. Transfer a file using the same file transfer protocol used in step 2. The systems are now tested and configured for deployment into the network system. 16 Version 1.1 - 01/04/00
Determining the RF Link Overview This section provides details about how to obtain the maximum range from your RF link. The effectiveness and reliability of your RF link depends on the following:
antenna gain distance between antennas and obstructions in the RF path above-ground height of the antennas length and type of coaxial cable connecting the 300-24 and the antenna The above factors are used to calculate your link budget. The link budget calculation indicates if your radio link is feasible over a given distance and path and if your RF link meets regulatory requirements. Link budgets are typically expressed in decibel (dB) format. Calculating the Link Budget Specific calculations must be completed to determine your link budget. This section describes the calculations and includes definitions of the terms and variables used in the calculations. The following dB terms are used in this section:
Term dB dBd dBi dBm Description Decibel. A relative measure of power used to specify power gains and losses. The difference in power P1 and P2 expressed in dB is:
dB
10 log P1
P2 The gain or loss of an antenna reference to a standard dipole. Gain of a Standard Dipole = 2.14 dBi. The gain or loss of an antenna referenced to an isotropic
(theoretical point source) radiator. This measure is used with only antennas, as it quantifies gain or loss of a physical radiator with respect to a theoretical one. A power measurement referenced to one milli-Watt. This is an absolute measure of power rather than a relative measure such as a gain or a loss. Version 1.1 - 01/04/00 17
Determining the RF Link Link Budget Variables You will use the following variables when you calculate the link budget:
Variable System Gain ERP (Effective Radiated Power) Sensitivity Antenna Gain Propagation Loss Cable Loss Path Loss Description The maximum path loss that the system can support for usable data transmission. The power radiating from an antenna taking into account the output power from the transmitter, connector losses, cable losses, and the antenna gain. The minimum signal strength required for usable performance. Expressed in dBm. Gain of the antenna over a dipole (dBd) or theoretical (dBi). The signal loss experienced as it travels through the air. Expressed in dB. The signal loss experienced as it passes through the coax cable. Expressed in dB. The total loss from one end of the path to the other. This includes propagation losses, cable losses, and any other losses that impact the system performance. Working with System Gain Proper path planning ensures that each end of the RF link receives sufficient signal power to maintain a desired Bit Error Rate (BER). The system gain of a radio system is the difference between the transmitted power and the receivers sensitivity threshold. See Link Budget Variables on page 18 for definitions of these terms. Using this relationship, the system gain of the 300-24 is:
Formula:
Variables:
System Gain = Tx Power - Rx Sensitivity Tx Power Receiver Sensitivity =
= 15dBm
-78dBm nominal for quasi-error free
(BER 10-9) operation Calculation:
93dB = 15dBm - -78dBm More info:
To ensure reliable communications, the system gain plus all antenna gains must be greater than the sum of all losses. For a reliable link it is recommended that the system gain plus all antenna gains be greater than the sum of all losses by a factor of 13dB. This factor is known as the Fade Margin. 18 Version 1.1 - 01/04/00 Calculating the Link Budget Unlike the Tx output power of the devices, ERP is subject to both antenna gain and cable losses. Calculating ERP (Effective Radiated Power) ERP is the power radiating from an antenna taking into account the output power from the transmitter, the connector and cable losses, and the antenna gain. Because many antennas can provide a directional gain, the effective radiated power can increase. Losses, such as cable losses can subtract from this amount. You calculate the ERP as follows:
Formula:
Note:
ERP = Tx Power (dBm) - Cable Losses (dBm) - Connector Losses
(dBm) + Antenna Gain (dB) The FCC regulatory body has set the ERP limit to +36dBm for fixed point-to-point applications per FCC 15.247(b)(3)(i). Industry Canada RSS-139, Annex B specifies the maximum transmitter output at +30dBm, with a maximum EIRP (Equivalent Isotropically Radiated Power) at +36dBm for multi-point configurations and a maximum EIRP of +53dBm only for licensed point-to-point applications. In accordance with ETS 300-328 for 2.4GHz RLANs, the maximum EIRP shall not exceed +20dBm, with a maximum SPD (Spectral Power Density) not exceeding +10dBm/MHz. Confirmation is required with the relevant European national radio communications local authority for deviations from this specification. Note: All ERP work must be completed by a professional installer. Working with Antenna Gain To ensure the best range and interference suppression, the external antenna should be directional, focusing the radio energy in one direction (toward the other end of the link). The direction can be azmuthal or a horizontal radiation angle. A directional antenna focuses the RF energy to the intended station rather than omni-directionally. This reduces interference from other systems that are operating at the same frequency. Note: In some situations, you may want to use an omni-directional antenna in your system design. For example, you would use an omni-directional antenna for a base station with remote sites situated in a 360 path around it. When you select an antenna, pay particular attention to the gain specification. When you select an antenna for a remote station, select an antenna with a gain that provides at least 13dB Fade Margin. Antenna gain is specified in either dBi or dBd. When an antenna is specified in dBd, add 2.14dB to the value to convert it to dBi. Note: All antenna gain work must be completed by a professional installer. Version 1.1 - 01/04/00 19 Determining the RF Link Calculating Propagation Loss The propagation loss is the attenuation (reduction) in RF signal energy as it travels through space. In most wireless systems, losses through space are the major contributor to signal attenuation. When you know the intended installation locations of the base and remote stations, determine the physical line of sight distance and then calculate the RF attenuation as follows:
Formula:
Attenuation (dB) = 100dB + 20log(dkm) where:
dkm = Distance in Kilometers 100dB = Pathloss Constant Note:
The FCC regulatory body has set the ERP limit to +36dBm for fixed point-to-point applications per FCC 15.247(b)(3)(i). Industry Canada RSS-139, Annex B specifies the maximum transmitter output at +30dBm, with a maximum EIRP (Equivalent Isotropically Radiated Power) at +36dBm for multi-point configurations and a maximum EIRP of +53dBm only for licensed point-to-point applications. In accordance with ETS 300-328 for 2.4GHz RLANs, the maximum EIRP shall not exceed +20dBm, with a maximum SPD (Spectral Power Density) not exceeding +10dBm/MHz. Confirmation is required with the relevant European national radiocommunications local authority for deviations from this specification. Note: All propagation loss work must be completed by a professional installer. Working with the Fresnel Zone It is essential to locate your antennas at maximum above-ground height to ensure the most effective and reliable link. Achieving maximum above-ground antenna height means that:
all ground-based obstructions are cleared from the line-of-sight path the Fresnel Zone is clear of obstructions 20 Version 1.1 - 01/04/00
The Fresnel Zone is the expansion of the RF signal radio angles in the vertical plane near the middle of the RF path. Following is a basic illustration of the Fresnel Zone concept:
Calculating the Link Budget First Fresnel Zone Line of Sight Fresnel R adius The maximum Fresnel Radius indicates that this path must be kept clear of obstructions. G round The Fresnel radius is calculated as follows:
Formula:
Fresnel Zone Radius =
3.4 dkm
d
8.12 2 metres Installations involving cable runs longer than a few feet must use high-
quality, low loss shielded coax. Calculating Cable Loss The wireless link is subject to implementation losses such as cable and connector losses. The two primary coaxial cable specifications for the 300-24 are:
cable must be 50 ohms nominal impedance cable must be of a low loss type Generally, cable losses are specified in dB/foot or dB/meter. Following is an example of cable loss ratings:
Cable Type LMR400 LMR600 dB/foot 0.0684 0.0441 dB/meter 0.220 0.142 Notes:
When you calculate path loss, you should add 1dB at each end of the link to compensate for connector losses in addition to the cable loss value.
All cable loss work must be completed by a professional installer. Version 1.1 - 01/04/00 21
Determining the RF Link Calculating Path Loss Path loss describes the total RF attenuation throughout the system from Tx antenna to Rx antenna. This includes the losses as the RF signal travels through space plus Tx and Rx cable loss, and Tx and Rx connector loss. Use the following formula to calculate path loss:
Formula:
Path Loss = Tx and Rx Cable Loss + Tx and Rx Connector Loss +
Propagation Loss Once you know the path loss, you can compare the value to the system gain value. If the system gain value is greater than the path loss, the link is feasible. See Working with System Gain on page 18 for more information about system gain. Note: All path loss work must be completed by a professional installer. Working with the Fade Margin The amount that the system gain plus the total antenna gain exceeds the path loss is called the Fade Margin. The Fade Margin is calculated as the number of dB that the received signal strength exceeds the minimum receiver sensitivity. You require some level of Fade Margin for any wireless system. The Fade Margin compensates for RF path fading due to weather conditions or nearby objects that induce multi-path signaling. The Fade Margin for the 300-24 is a minimum of 13dB. The sum of the cable losses, connector losses, propagation losses, and the 13dB required Fade Margin should be less than the system gain value of 93dB. Note: All fade margin work must be completed by a professional installer. Total antenna gain is:
Tx Antenna Gain +
Rx Antenna Gain 22 Version 1.1 - 01/04/00 Link Budget Example Link Budget Example The values for cable and connector losses in this example are only for illustration. You will need to work these out for your specific installations. Putting everything together, you must satisfy the following equation to have a successful link:
Formulas:
System Gain + Antenna Gain Propagation Loss + Fade Margin
+ Cable Losses + Connector Losses or Fade Margin System Gain + Antenna Gain - Propagation Loss -
Cable Losses - Connector Losses where:
System Gain = Tx Power - Rx Sensitivity Antenna Gains = Tx Antenna Gain + Rx Antenna Gain Cable Losses = Base Cable Losses + Remote Cable Losses Connector Losses = Base System Connector Losses + Remote System Connector Losses Variables:
Desired Fade Margin Tx Power Rx Sensitivity Tx Antenna Gain Rx Antenna Gain Propagation Loss for
13dB 15dBm
-78dBm 9dB 15 dB desired range of 1km =
100 20
log 1
100dB Tx Cable Losses
(2m LMR400) Rx Cable Losses
(2m LMR 400) Tx Connector Losses Rx Connector Losses
.44dB
.44dB
.5dB
.5dB System Gain = 15dBm - -78dBm = 93dBm Antenna Gains = 9dB + 15dB = 24dB Cable Losses = .44dB + .44dB = .88dB Connector Losses = .5dB + .5dB = 1dB Fade Margin = 93dB + 24dB - 100dB - .88dB - 1dB = 15.12dB We have achieved the goal of a Fade Margin 13dB. Variable Calculations:
Fade Margin Calculation:
Analysis:
Version 1.1 - 01/04/00 23 Determining the RF Link Verifying a Link Budget You need to verify the link budget in both directions: base station to remote station and remote station to base station. To verify the link budget calculations, from the 300-24 user interface, measure the Received Signal Strength Indicator (RSSI), Null Depth, and the Fade Margin. Note: The effects of multi-path are not the same in both directions of a link and you need to verify the link budget in both directions. Following are descriptions of the link statistics you need to measure:
See Viewing the MAC Layer Statistics on page 39 for more information about the MAC Layer Statistics window. Term Null Depth Description The difference in strength between the strongest and weakest OFDM carriers. A Null Depth of more than a few dB indicates the receiver is experiencing multi-path effects which are partially canceling the signal. If the Null Depth is more than 3dB, it should be compensated by moving the receiving antenna or increasing the antenna gain. RSSI A numeric indication of the received signal strength in dBm. Reviewing the Link Statistics Once you set up the link and select the Mac Layer Statistics window in the user interface, you can measure the RSSI, Null Depth, and Fade Margin to ensure that the link is functioning properly. See Appendix B: Monitor and Test Links on page 75 for more information about monitoring link statistics after the system installation is complete. You need to measure:
Null Depth
Bit Error Rate (BER) Interpreting the Null Depth When you interpret the link statistics, you need to subtract the Null Depth from your budgeted Fade Margin. For example, if you budgeted a 13dB Fade Margin, and you have an indicated Null Depth of 3dB and an indicated Fade Margin of 10dB, then your calculations were correct. Budgeted Fade Margin = Indicated Null Depth + Indicated Fade Margin where:
13dB = 3dB + 10dB For small Null Depths, you will typically proceed with a reduced Fade Margin as long as the number of uncorrected errors is zero, or is incrementing very slowly during peak traffic periods. 24 Version 1.1 - 01/04/00 Verifying a Link Budget Interpreting Bit Error Rate (BER) The BER after Reed-Solomon Forward Error Correction (RS FEC) can be computed from the number of uncorrected byte errors and the total number of frames received. The following constants are used in the calculation:
1536 bytes per frame 8 bits per byte 1.25 bit errors per uncorrected byte error (on average) From these values, the following formula is structured:
BER = 1.25 x Uncorrected Bytes / (Number of Frames x 1536 x 8) You need to accumulate approximately 80 byte errors, or 100 bit errors, to receive statistically significant results. The final test of a good link, is when the BER on the monitoring computer is 10-9 or better. Version 1.1 - 01/04/00 25
Determining the RF Link 26 Version 1.1 - 01/04/00 Installing Base and Remote Stations Overview Once you have determined the RF link and configured the units, you can install the 300-24 units at the site locations. Installing the Antenna If you are using rubber duck or rubber dipole antennas, they should be pointed vertically (up). If your antennas will be located on a support structure, or on top of a tower, you should have a professional tower worker complete the antenna installation. When you install the antenna, ensure that:
the antennas for the system have the same polarity (vertical or horizontal). all connectors attaching the coaxial cable to the antenna are properly weatherproofed. a drip loop is formed at the building entrance, to prevent water flowing down the coaxial cable from entering the installation building. the coaxial cable is secured to the supporting structure at one meter intervals. This will prevent wind damage and frost loading problems. the antenna is firmly attached to the mast to prevent it from falling, yet has some flexibility so that you can move the antenna to fine-tune antenna position. the coaxial cable is connected to the antenna and to the antenna port on both sides of the link (base and remote stations). Note: All antenna installation work must be completed by a professional installer. Powering Up the Units Before you power up the units, ensure that the AC Power Level Switch on the back panel of the unit is set correctly. An incorrect power level setting can cause serious damage to the unit when it is powered up. When you successfully power up the unit, the Power LED on the front panel will initially be orange, and then change to green. See Front Panel LEDs on page 6 for more information about the LED display. You need to verify that your hardware and software revision numbers match those on the data list shipped with the unit. If the numbers do not match, contact Wi-LAN customer support. See Contacting Customer Support on page 3 for more information about contacting Wi-LAN. Version 1.1 - 01/04/00 27
Installing Base and Remote Stations To verify the revision numbers 1. Access the Configuration menus using Telnet or RS-232. See Accessing the Menus on page 31 for more information about accessing the Configuration menus and logging into the system. 2. Access the System Revision Information window and verify that the hardware and software revision numbers shown in the window match those on the data list shipped with the unit. See Viewing System Revision Information on page 35 for more information about viewing the System Revision Information window. Verifying the RF Port You can connect two units together back to back via an RF cable to verify the RF port. You need to ensure that:
you have at least 70dB of RF attention between the RF ports of the two units. the units are at least 10 meters apart. you connect a 30dB attenuator directly to each RF port to minimize cross-talk between units. the attenuators have at least a 20dBm power rating. you add another 10dB of attenuation between the units, either at one end or in between the units. To verify the RF port 1. Access the Configuration menus and verify the following:
Verify that... For more information see... The IP addresses are unique for each unit. The IP Masks are the same for both units. To set the Internet IP address on page 52. To set the Internet IP mask on page 52. The MAC addresses are unique for both units. To set the ethernet MAC address on page 53. One unit is a base station and all others are remotes. All units are included in the Base Stations Remote Poll Configuration. To set the OFDM station type on page 57. To configure the polling list on page 61. There is both ethernet and wireless access to the units TCP/IP stack. To set ethernet and wireless access on page 42. The host computers connected to the unit are on the same subnet. Setting the Internet IP Address on page 52. 28 Version 1.1 - 01/04/00
Powering Up the Units Verify that... For more information see... The host computers connected to the units have unique IP addresses with respect to themselves and the units. Setting the Internet IP Address on page 52. 2. From each end of your two unit connection, ping the unit from the wire and wireless sides. 3. From each end of your two unit connection, telnet to the unit from the wire and wireless sides. If you can successfully communicate to all units through ping and telnet, your RF port is verified. Fine-tuning Antennas You can fine-tune the antennas by generating consistent steady traffic through the 10/100BaseT port at one end and then, at the receiving end, connecting a PC via the RS-232 to monitor the link statistics. You can ping the computer to create steady traffic. Ensure that the link statistics show an adequate Fade Margin and that the Null Depth is less than 4dB. See Appendix B: Monitor and Test Links on page 75 for information about monitoring the link statistics. Reposition the antennas until the required link statistics values are achieved. Once the antennas have been adjusted to maximize performance, you can secure them properly to the support structures. Note: All antenna fine-tuning must be completed by a professional installer. Completing the Installation Connections Once the antennas are properly positioned, you need to connect the 300-24 to its LAN segment. You complete this connection as you would connect a PC to a LAN segment. Note: Cabling between 10/100baseT nodes is usually through a network hub. To make a direct 10/100baseT connection between a 300-24 and a PC, use a standard crossover cable. You must swap pins 1 & 3 and 2 & 6. Once the connection is complete, the 300-24 unit is ready for network traffic. The link statistics display in real time. Any changes to the antenna position are immediately represented in the link monitoring screen. Version 1.1 - 01/04/00 29 Installing Base and Remote Stations Installing the Units on a Rack You can mount the 300-24 unit in a rack. The face plate and hardware for rack installations is included in the 300-24 shipping package. Following is an illustration of how to attach the face plate to the 300-24:
The unit is designed for installation in a 19 inch rack that is 3U high. 30 Version 1.1 - 01/04/00 Configuring Using the Menus Overview This section includes some general information about:
accessing and modifying the configuration settings
working with the configuration menus to define your 300-24 system settings You can use the following methods to access and configure the 300-24 units:
Telnet
RS-232 Management Port SNMP See Using SNMP on page 65 for information about using SNMP. You can configure any unit as a base or a remote station. Each system configuration includes only one base station, however it can include multiple remote stations. If you need a true wide area network where all sites pass all data packets, the base and remote stations need to communicate directly with each other. Every station will receive and decode all packets and a true LAN/WAN network is created from individual segments. Navigating the Configuration Menus You use the keyboard keys to highlight and apply configuration options in the configuration menus. See Conventions Used in this Guide on page 2 for descriptions of the menu selection conventions used in this guide. Accessing the Menus As discussed earlier in this section, you can access the configuration menus using the following two methods:
RS-232 Management Port Telnet Version 1.1 - 01/04/00 31
Configuring Using the Menus Using the Console You can access the configuration menus by connecting a PC to the unit through the RS-232 Serial Port Interface. Typically, you will use this access method to complete pre-installation configuration and to initially set up your 300-24 system. To access the configuration menus through the console 1. Disconnect the power from the 300-24. 2. Connect a serial cable from a DB9 serial port on the PC to the RS-232 serial port on the 300-24. Note: You can access the RS-232 serial port through the RJ11 connection on the front of the unit, or through the DB9 connection on the back panel. Adaptors to complete these connections are shipped with the 300-24. 3. Start a terminal emulation program on the PC. 4. Set the terminal emulation program to emulate a VT100 terminal at:
9600 baud 8 data bits no parity 1 stop bit 5. Set the terminal program to use the PC serial port that is connected to the 300-24 unit. 6. Power up the unit. 7. Press the spacebar on the keyboard. The Login menu appears. 8. At the Enter Password prompt, type your User Password. The Main System menu appears:
Main System Menu
-> System Revision Information System Software ROM Images System Current Status System Security System Commands Network Configuration Radio Configuration Remote Station Configuration MAC Layer Statistics Remote Station Configuration only appears in the Main System menu for units configured as the base station. You can now start configuring the unit. 32 Version 1.1 - 01/04/00
Navigating the Configuration Menus Using Telnet Typically, you will use telnet to access the configuration menus once you have already completed the initial unit configuration. Because you telnet to the units IP address, you must have already defined the address before you can telnet to it. This configuration method is effective when you need to configure a unit from a remote location. To use the keyboard up and down arrow keys to navigate the configuration menus, ensure that the VT100 Arrows feature in your telnet session is enabled. To access the units through telnet 1. From a VT100 terminal, or emulation, type telnet <IP address>. Where <IP address> is the address of the unit that you want to configure. Note: If you are using Microsoft Telnet 1.0 as your terminal emulation application, see To set the VT100 arrows in Microsoft Telnet below for instruction on setting the VT100 arrows. 2. Press the Enter key. The Login menu appears. 3. At the Enter Password prompt, type your User Password. The Main System menu appears:
Main System Menu
-> System Revision Information System Software ROM Images System Current Status System Security System Commands Network Configuration Radio Configuration IP Filter Configuration MAC Layer Statistics IP Filter Configuration only appears in the Main System menu for units configured as remote stations. You can now start configuring the unit. Version 1.1 - 01/04/00 33 Configuring Using the Menus To set the VT100 arrows in Microsoft Telnet 1. In the active Microsoft Telnet 1.0 session, select Terminal, Preferences from the menu bar. The Terminal Preferences window appears:
2. Click to select the VT100 Arrows checkbox. 3. Click OK. The VT100 arrows are enables in the telnet session, and you can use the keyboard arrow keys to navigate the configuration menus. Exiting the Configuration Menus Once you have configured the unit, you must exit the menus before disconnecting the unit from the PC. To exit the configuration menus 1. Press the Esc key on the keyboard until you exit the configuration menus. 2. Power down the computer. 34 Version 1.1 - 01/04/00 Viewing System Information You can use the Main System menu to view the following system information:
Viewing System Information You can only view information in this window. You cannot select or apply any configuration settings. system revision information system software ROM images current system status
MAC (Media Access Control) layer statistics Viewing System Revision Information The system revision information shows details about the system including the:
version of the 300-24 hardware
RAM and ROM size version number of the system image file on the unit version date of the system image file on the unit name of the image file running on the 300-24 To view system revision information 1. From the Main System menu, select System Revision Information. The System Revision Information window appears:
System Revision Information Hardware Rev 0.0.0 (4MB RAM, 512K AMD Flash) ROM Size 0x80000 RAM Size 0x400000 Software Rev 0.0.0 (Wi-LAN Ethernet/OFDM) File Date Oct 8 1999 18:28:33 File Name FACTORY-IMAGE 2. Following is a description of the fields in the window:
This field... Hardware ROM Size RAM Size Software File Date Shows this... The revision number of the 300-24 unit, and the RAM and AMD Flash installed in the unit. The amount of read-only memory in the unit. The amount of random-access memory in the unit. This value also appears in the Hardware field. The revision number of the system image running on the unit. The revision date and time of the system image running on the unit. File Name The file name of the system image running on the unit. Version 1.1 - 01/04/00 35
Configuring Using the Menus Viewing System Software ROM Images The System Software ROM Images window shows a list of all images that are available on the unit. Initially, only the Factory-Image is available, however as new images are developed, Wi-LAN will place them on their web site where you can download the system image files. To view system software ROM images 1. From the Main System menu, select System Software ROM Images. The System Software ROM Images window appears:
System Software ROM Images File Name Revision Date Time Size Default Current
FACTORY-IMAGE 0.0.0 Oct 8 1999 18:28:33 124792 Yes Yes You can only view information in this window. You cannot select or apply any configuration settings. 2. Following is a description of the fields in the window:
This field... File Name Revision Date Time Size Default Current Shows this... The names of all system image files stored in the unit. The revision number of the system image file. Each time the system image is modified, the revision number increases by 1 unit. For example, the first revision to the file would make the revision number 0.0.1. The date the image file was last revised. The time the image file was last revised. The size of the image file in bytes. Indicates if the image file starts when the 300-24 is powered up. Indicates if the image file is currently operating on the unit. 36 Version 1.1 - 01/04/00 You can only view information in this window. You cannot select or apply any configuration settings. Viewing System Information Viewing Current System Status The Current System Status window shows historical and current information about the unit. This information enables you to view the current state of the system and, if you are troubleshooting system problems, provides historical information that can help you monitor and troubleshoot your system. To view current system status 1. From the Main System menu, select System Current Status. The System Current Status window appears:
System Current Status Cumulative Run-Time 0 Days 3 Hours Current Run-Time 0 Days 00:45:08 Power Cycles 5 Shows Thermal Shutdowns 0 historical Successful Logins 6 information. Unsuccessful Logins 1 Local User Logged In User Telnet User Logged In None FTP User Logged In None System Operational Status N/A Shows LAN Connection Status N/A current Thermal Status N/A information. Correctable Error Rate N/A Uncorrectable Error Rate N/A Bit Error Rate N/A Received Signal Strength RSSI N/A You can reset these statistics to 0. See Resetting the Statistics on page 50 for more information. 2. Following is a description of the fields in the window:
This field... Shows this... Cumulative Run-Time Current Run-Time Power Cycles Thermal Shutdowns Successful Logins Unsuccessful Logins The number of hours the system has been running since purchase. This information is required for maintenance purposes. The time duration that has passed since the unit was last reset. The number of times that the unit has been powered down and repowered up. The number of times that the unit has automatically powered down due to overheating. The number of times that the configuration menus have been successfully accessed. The number of times that access to the configuration menus has failed. Version 1.1 - 01/04/00 37 Configuring Using the Menus This field... Shows this... Local User Logged In Telnet User Logged In FTP User Logged In The access level of the user currently logged into the configuration menus via the RS-232. The access level of the user currently logged into the configuration menus via a telnet session. The access level of the user currently logged into the configuration menu via an FTP session. System Operational Status Not implemented in this release. LAN Connection Status Not implemented in this release. Thermal Status Not implemented in this release. Correctable Error Rate Not implemented in this release. Uncorrectable Error Rate Not implemented in this release. Bit Error Rate Not implemented in this release. Received Signal Strength RSSI Not implemented in this release. 38 Version 1.1 - 01/04/00 You can only view information in this window. You cannot select or apply any configuration settings. Viewing System Information Viewing the MAC Layer Statistics The MAC layer statistics show the performance of the unit in the 300-24 system. Information such as ethernet transmit and receive statistics, and OFDM encoder, decoder and unpacking statistics enable you to view how the system is performing and where there are errors that need to be addressed. To view the MAC layer statistics 1. From the Main System menu, select MAC Layer Statistics. The MAC Layer Statistics window appears:
MAC Layer Statistics Ethernet Receive Statistics Ethernet Transmit Statistics Total Frames Received 4 Total Frames Transmitted 0 Frames For Local Host 4 Frames From Local Host 0 Receive Errors 0 Frames Dropped 0 Frames Dropped 0 OFDM Decoder Statistics OFDM Encoder Statistics Total Frames Decoded 0 Total Frames Encoded 4 Decoder IDMA Transfers 0 Encoder IDMA Transfers 4 Frames For Local Host 0 Frames From Local Host 0 Uncorrected Frames 0 Uncorrected Bytes 0 OFDM Unpacking Statistics Corrected Frames 0 Corrected Bytes 0 Start Sequence Errors 0 Start Seq Extra Bytes 0 Header Errors 0 OFDM Channel Statistics RSSI (dBm) -87 Average Throughput 640 Null Depth (dB) 0 Maximum Throughput 2016 Fade Margin (dB) 0 FEC BER 0 BER 0 2. Following is a description of the fields in the window:
This field... Shows this... Total Frames Received The number of ethernet frames received from the 100Base-T connection. Total Frames Transmitted The number of ethernet frames transmitted onto the 100Base-T connection. Frames For Local Host
(Ethernet Receive) The number of ethernet frames received from the 100Base-T connection which were destined for the 300-24 units TCP/IP stack. Version 1.1 - 01/04/00 39 Configuring Using the Menus This field... Shows this... Frames From Local Host
(Ethernet Transmit) Receive Errors Frames Dropped
(Ethernet Transmit) Frames Dropped
(Ethernet Receive) Total Frames Decoded Total Frames Encoded The number of ethernet frames transmitted onto the 100Base-T connection which originated from the 300-24 units TCP/IP stack. The number of ethernet frames received with errors, for example, runt (smaller than 64 bytes), jabber
(larger than 1518 bytes), or overflow error. The number of ethernet frames not transmitted due to some error, for example, unable to transmit within 15 retries, or underflow error. The number of ethernet frames dropped because the wireless link is at capacity and all of the queues are full. The number of ethernet frames that went through the rs-decoder without uncorrectable errors. The number of ethernet frames that went through the rs-encoder. Decoder IDMA Transfers The number of RF superframes received by the rs-decoder Encoder IDMA Transfers The number of RF superframes produced by the rs-encoder Frames For Local Host
(OFDM Decoder) Frames From Local Host
(OFDM Encoder) Uncorrected Frames Uncorrected Bytes Corrected Frames Corrected Bytes The number of ethernet frames that went through the rs-decoder without uncorrectable errors which were destined for the 300-24 units TCP/IP stack. The number of ethernet frames that went through the rs-encoder which originated from the 300-24 units TCP/IP stack. The number of RF superframes received by the rs-decoder that have uncorrectable errors. The total number of bytes through the rs-decoder which have uncorrectable errors. For Wi-LAN use only. The number of RF superframes received by the rs-decoder that have correctable errors. For Wi-LAN use only. The total number of bytes through the rs-decoder which have correctable errors. Start Sequence Errors For Wi-LAN use only. Start Seq Extra Bytes For Wi-LAN use only. Header Errors For Wi-LAN use only. 40 Version 1.1 - 01/04/00 Viewing System Information This field... RSSI (dBm) Null Depth (dB) Shows this... Received signal strength indicator (in dB relative to 1 milliWatt). The difference between the strongest and weakest carriers. Fade Margin (dB) Fade Margin. FEC BER BER Average Throughput Maximum Throughput Bit Error Rate after forward error correction. Bit Error Rate before forward error correction. The total throughput (per second) averaged over 10 seconds. The highest throughput over 1 second since the last stats reset. Version 1.1 - 01/04/00 41 Configuring Using the Menus Setting the System Security You can set the security levels and access settings for the system through the Main System menu. These settings enable you to:
set the ethernet and wireless access set community names which the SNMP Manager uses to access the unit define the user and supervisor passwords define the auto logout timeout Setting Access Types Setting the access types involves enabling or disabling access to the unit via the ethernet and/or via the air. The default setting for access is set to on, for both the ethernet and wireless. Depending on your security requirements, you may want to modify these settings. To set ethernet and wireless access 1. From the Main System menu, select System Security. The System Security window appears:
System Security access type settings System Ethernet Access -> on System Wireless Access on SNMP Public Community Name public SNMP Private Community Name netman Change User Password Press Enter to change password Confirm User Password Press Enter to confirm password Change Supervisor Password Press Enter to change password Confirm Supervisor Password Press Enter to confirm password Auto Logout Timeout (Minutes) 10 2. Select System Ethernet Access. An arrow appears to the left of the System Ethernet Access entry field. In the System Ethernet Access entry field, select an option as follows:
3. Select... To... On Off Enable access to the unit via the ethernet Disable access to the unit via the ethernet. 42 Version 1.1 - 01/04/00
Setting the System Security 4. Press the Enter key. 5. Select System Wireless Access. An arrow appears to the left of the System Wireless Access entry field. In the System Wireless Access entry field, select an option as follows:
6. Select... To... On Off Enable access to the unit via the air Disable access to the unit via the air. 7. Press the Enter key. Setting Community Names Setting a community name enables you to manage your system using an SNMP Manager. The public and private community names identify the unit to the SNMP Manager and, depending on the name SNMP uses to identify the unit, indicates if you can execute commands on the unit. To set a community name 1. From the Main System menu, select System Security. The System Security window appears:
System Security System Ethernet Access on System Wireless Access on community name settings SNMP Public Community Name -> public SNMP Private Community Name netman Change User Password Press Enter to change password Confirm User Password Press Enter to confirm password Change Supervisor Password Press Enter to change password Confirm Supervisor Password Press Enter to confirm password Auto Logout Timeout (Minutes) 10 2. Select SNMP Public Community Name. An arrow appears to the left of the SNMP Community Name entry field. 3. Press the Enter key. The entry field changes to edit mode. 4. Type a name for the Community Name. 5. Press the Enter key. The name appears in the entry field. 6. Select SNMP Private Community Name and then repeat steps 3 to 5. A field in edit mode appears in reverse colors. The text appears as white, and the field is highlighted in black. Version 1.1 - 01/04/00 43 Configuring Using the Menus Setting Passwords You can control access to the configuration menus by setting passwords for users and supervisors. Typically, users will have read-only access to all menus, while supervisors can modify configuration settings. To set passwords 1. From the Main System menu, select System Security. The System Security window appears:
System Security System Ethernet Access on System Wireless Access on SNMP Public Community Name public SNMP Private Community Name netman password settings Change User Password -> Press Enter to change password Confirm User Password Press Enter to confirm password Change Supervisor Password Press Enter to change password Confirm Supervisor Password Press Enter to confirm password A field in edit mode appears in reverse colors. The text appears as white, and the field is highlighted in black. Auto Logout Timeout (Minutes) 10 2. Select Change User Password. An arrow appears to the left of the entry field. 3. Press the Enter key. The entry field changes to edit mode. 4. Type the new password. 5. Press the Enter key. An arrow moves to the left of the Confirm Password entry field. 6. Press the Enter key. The entry field changes to edit mode. 7. Re-type the password you typed in step 4. 8. Press the Enter key. The change is saved. 9. Select Change Supervisor Password and then repeat steps 3 to 8. 44 Version 1.1 - 01/04/00 If the menus automatically time out, the system appears frozen. Press the Enter key to view the Login window where you can log in to the menus. Setting the System Security Setting Automatic Timeouts You can specify the maximum idle time period that can pass before the configuration menus close and the Login menu reappears. This ensures that the system closes if a user forgets to exit out of the configuration menus. To set the automatic timeout period 1. From the Main System menu, select System Security. The System Security window appears:
System Security System Ethernet Access on System Wireless Access on SNMP Public Community Name public SNMP Private Community Name netman Change User Password Press Enter to change password Confirm User Password Press Enter to confirm password Change Supervisor Password Press Enter to change password Confirm Supervisor Password Press Enter to confirm password timeout settings Auto Logout Timeout (Minutes) -> 10 2. Select Auto Logout Timeout (Minutes). An arrow appears to the left of the entry field. 3. Press the Enter key. The entry field changes to edit mode. 4. Type the maximum idle time period, in minutes, that can pass before the configuration menus close. 5. Press the Enter key. The new value appears in the entry field. Version 1.1 - 01/04/00 45 Configuring Using the Menus Working with System Images When you first power up the 300-24 unit, it starts with the factory-image. As new images are developed, Wi-LAN will place them on their web site where you can download the image files to the 300-24. Currently, only the factory-image is available. See Upgrading Software via FTP on page 79 for more information about downloading new image files. Setting the Default Image As discussed above, as new images are developed and released, you will have the option to select from a list of images to use on the 300-24. Once you have more than one image saved on the unit, you can define which image file you want to use as the default each time you power up the 300-24. To set the default image 1. From the Main System menu, select System Commands. The System Commands window appears:
System Commands Set Default System Image -> FACTORY-IMAGE Reboot Current Image Press Enter to Execute Reboot a System Image FACTORY-IMAGE Restore Factory Configuration Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode Press Enter to Execute Return to Normal Mode Press Enter to Execute Reset Radio Statistics Press Enter to Execute Reset MAC Layer Statistics Press Enter to Execute Use the arrow keys on the keyboard to scroll through the field selections. 2. Select Set Default System Image. 3. An arrow appears to the left of the entry field. In the Set Default System Image entry field, scroll to select the image to use as the default. 4. Press the Enter key. The new image file appears in the field and will be used each time the 300-24 is powered up. 46 Version 1.1 - 01/04/00 Working with System Images Rebooting Images You can reboot an image to reapply its settings to the unit. You can also choose to reboot the 300-24 using a different image from that which you were originally using. If you make changes to the network configuration, such as changing IP and MAC addresses, you must reboot the current image for the changes to take effect. When you reboot the image, the 300-24 recopies the image from flash memory and runs it. See Configuring the Internet IP Settings on page 52 for more information about changing the network configuration. To reboot the current image 1. From the Main System menu, select System Commands. The System Commands window appears:
System Commands Set Default System Image FACTORY-IMAGE Reboot Current Image -> Press Enter to Execute Reboot a System Image FACTORY-IMAGE Restore Factory Configuration Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode Press Enter to Execute Return to Normal Mode Press Enter to Execute Reset Radio Statistics Press Enter to Execute Reset MAC Layer Statistics Press Enter to Execute 2. Select Reboot Current Image. An arrow appears to the left of the entry field. 3. Press the Enter key. The 300-24 reboots using the current image. To reboot a system image 1. From the Main System menu, select System Commands. The System Commands window appears:
If you try to enter loopback mode when you are already in the mode, failure appears in the Enter Loopback Mode field. System Commands Set Default System Image FACTORY-IMAGE Reboot Current Image Press Enter to Execute Reboot a System Image -> FACTORY-IMAGE Restore Factory Configuration Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode Press Enter to Execute Return to Normal Mode Press Enter to Execute Reset Radio Statistics Press Enter to Execute Reset MAC Layer Statistics Press Enter to Execute 2. Select Reboot a System Image. An arrow appears to the left of the entry field. In the Reboot a System Image entry field, scroll to select the image you want to use. 3. 4. Press the Enter key. The 300-24 reboots using the selected system image. Version 1.1 - 01/04/00 47 Configuring Using the Menus Restoring Configurations When you make changes to the configuration settings, you can easily restore the default configuration settings without having to reboot the 300-24. You have the option of restoring the factory configuration settings, or you can restore the configuration settings from the image you used when you last powered up the unit. To restore the factory configuration 1. From the Main System menu, select System Commands. The System Commands window appears:
System Commands Set Default System Image FACTORY-IMAGE Reboot Current Image Press Enter to Execute Reboot a System Image FACTORY-IMAGE Restore Factory Configuration -> Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode Press Enter to Execute Return to Normal Mode Press Enter to Execute Reset Radio Statistics Press Enter to Execute Reset MAC Layer Statistics Press Enter to Execute 2. Select Restore Factory Configuration. An arrow appears to the left of the entry field. 3. Press the Enter key. The factory configuration settings are restored. To restore the poweron configuration 1. From the Main System menu, select System Commands. The System Commands window appears:
System Commands Set Default System Image FACTORY-IMAGE Reboot Current Image Press Enter to Execute Reboot a System Image FACTORY-IMAGE Restore Factory Configuration -> Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode Press Enter to Execute Return to Normal Mode Press Enter to Execute Reset Radio Statistics Press Enter to Execute Reset MAC Layer Statistics Press Enter to Execute 2. Select Restore Poweron Configuration. An arrow appears to the left of the entry field. 3. Press the Enter key. The configuration settings that were applied when the unit was powered up are restored. 48 Version 1.1 - 01/04/00 Working with Modes Working with Modes You can change the mode settings on the 300-24 to loopback mode or normal mode. In loopback mode, the 300-24 communicates with the baseband board. This mode enables you to verify that the 300-24 is transmitting properly; you cannot receive or transmit in this mode. In normal mode, the unit communicates with the RF Interface board and data is transmitted and received to and from the air and wire. To enter loopback mode 1. From the Main System menu, select System Commands. The System Commands window appears:
System Commands Set Default System Image FACTORY-IMAGE Reboot Current Image Press Enter to Execute Reboot a System Image FACTORY-IMAGE Restore Factory Configuration Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode -> Press Enter to Execute Return to Normal Mode Press Enter to Execute Reset Radio Statistics Press Enter to Execute Reset MAC Layer Statistics Press Enter to Execute 2. Select Enter Loopback Mode. An arrow appears to the left of the entry field. 3. Press the Enter key. The 300-24 is now in loopback mode. To enter normal mode 1. From the Main System menu, select System Commands. The System Commands window appears:
System Commands Set Default System Image FACTORY-IMAGE Reboot Current Image Press Enter to Execute Reboot a System Image FACTORY-IMAGE Restore Factory Configuration Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode Press Enter to Execute Return to Normal Mode -> Press Enter to Execute Reset Radio Statistics Press Enter to Execute Reset MAC Layer Statistics Press Enter to Execute 2. Select Return to Normal Mode. An arrow appears to the left of the entry field. 3. Press the Enter key. The 300-24 is operating in normal mode. Version 1.1 - 01/04/00 49 Configuring Using the Menus Resetting the Statistics The statistics that appear in the MAC Layer Statistics window and the System Current Status window are cumulative that is, the values increase over time, until you reset the numbers back to 0. Typically, you would reset the values when you want to track a specific occurrence of an event. For example, a unit has had a thermal shutdown, and you have corrected the cause of the shutdown (a heating/cooling problem). Once the problem is corrected, you might want to reset the statistics. If the unit shuts down again, a 1 appears in the statistic window and you can easily determine that a thermal shutdown has reoccurred. To reset the radio statistics 1. From the Main System menu, select System Commands. The System Commands window appears:
System Commands Set Default System Image FACTORY-IMAGE Reboot Current Image Press Enter to Execute Reboot a System Image FACTORY-IMAGE Restore Factory Configuration Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode Press Enter to Execute Return to Normal Mode Press Enter to Execute Reset Radio Statistics -> Press Enter to Execute Reset MAC Layer Statistics Press Enter to Execute 2. Select Reset Radio Statistics. An arrow appears to the left of the entry field. 3. Press the Enter key. The values in the System Current Status window are reset to 0. See Viewing Current System Status on page 37 to view the System Current Status window. To reset the MAC Layer statistics 1. From the Main System menu, select System Commands. The System Commands window appears:
System Commands Set Default System Image FACTORY-IMAGE Reboot Current Image Press Enter to Execute Reboot a System Image FACTORY-IMAGE Restore Factory Configuration Press Enter to Execute Restore Poweron Configuration Press Enter to Execute Enter Loopback Mode Press Enter to Execute Return to Normal Mode Press Enter to Execute Reset Radio Statistics Press Enter to Execute Reset MAC Layer Statistics -> Press Enter to Execute 2. Select Reset MAC Layer Statistics. An arrow appears to the left of the entry field. 50 Version 1.1 - 01/04/00 3. Press the Enter key. The values in the MAC Layer Statistics window are reset to 0. See Viewing the MAC Layer Statistics on page 39 to view the MAC Layer Statistics window. Resetting the Statistics Version 1.1 - 01/04/00 51 Configuring Using the Menus Configuring the Internet IP Settings When you change the IP or MAC addresses, you must reboot the current image for the changes to take effect. See Rebooting Images on page 47 for more information. To enable the 300-24 unit to communicate with other units, you need to define the Internet IP settings. You can also configure IP masks that you can use to create subnets for your system. These subnets enable you to perform basic multicasting tasks. Setting the Internet IP Address You need to indicate the IP address for each 300-24 unit. This address enables communication via TCP/IP. To set the Internet IP address 1. From the Main System menu, select Network Configuration. The Network Configuration window appears:
Network Configuration Internet IP Address -> 192.168.3.85 Internet IP Mask 255.255.255.0 Ethernet MAC Address 000203040506 IP Routing Option Transparent Default Gateway IP Address 192.168.3.52 SNMP NMS Trap IP Address 192.168.3.52 2. Select Internet IP Address. An arrow appears to the left of the entry field. 3. Press the Enter key. The entry field changes to edit mode. 4. Type the unique Internet IP address for the unit. 5. Press the Enter key. The Internet IP address appears in the field and is assigned to the unit. To set the Internet IP mask 1. From the Main System menu, select Network Configuration. The Network Configuration window appears:
Network Configuration Internet IP Address 192.168.3.85 Internet IP Mask -> 255.255.255.0 Ethernet MAC Address 000203040506 IP Routing Option Transparent Default Gateway IP Address 192.168.3.52 SNMP NMS Trap IP Address 192.168.3.52 2. Select Internet IP Mask. An arrow appears to the left of the entry field. 52 Version 1.1 - 01/04/00 Configuring the Internet IP Settings 3. Press the Enter key. The entry field changes to edit mode. 4. Type the Internet IP Mask for the unit. 5. Press the Enter key. The Internet IP Mask appears in the field and is assigned to the unit. Setting the Ethernet MAC Address Typically, you will never modify the ethernet MAC address. This address uniquely identifies the 300-24 unit in the system. When you're connected to the internet from your computer, a correspondence table relates your IP address to your computer's physical
(MAC) address on the LAN. If you need to modify the address, you should contact Wi-LAN technical support to discuss the required modifications. See Customer Support on page 3 for more information. To set the ethernet MAC address 1. From the Main System menu, select Network Configuration. The Network Configuration window appears:
Network Configuration Internet IP Address 192.168.3.85 Internet IP Mask 255.255.255.0 Ethernet MAC Address -> 000203040506 IP Routing Option Transparent Default Gateway IP Address 192.168.3.52 SNMP NMS Trap IP Address 192.168.3.52 2. Select Ethernet MAC Address. An arrow appears to the left of the entry field. 3. Press the Enter key. The entry field changes to edit mode. 4. Type the ethernet MAC address for the unit. 5. Press the Enter key. The ethernet MAC address appears in the field and is assigned to the unit. Version 1.1 - 01/04/00 53 Configuring Using the Menus Setting the IP Routing Options You can set your IP routing to enable all data to route through the unit, or you can set the routing to IP Filtering, which will filter out certain IP ranges that you define in the IP Filter Configuration window. Note: For this release, only transparent mode is available. To set the IP routing options 1. From the Main System menu, select Network Configuration. The Network Configuration window appears:
Network Configuration Internet IP Address 192.168.3.85 Internet IP Mask 255.255.255.0 Ethernet MAC Address 000203040506 IP Routing Option -> Transparent Default Gateway IP Address 192.168.3.52 SNMP NMS Trap IP Address 192.168.3.52 2. Select IP Routing Option. An arrow appears to the left of the entry field. In the IP Routing Option entry field, scroll to select the option you want to apply:
3. Select... Transparent IP Filtering To... Enable all received data to route through the system. Prevent data received from a specified range of IP addresses from being routed through the system. 4. Press the Enter key. The selected option is applied. 54 Version 1.1 - 01/04/00 Configuring the Internet IP Settings Setting the Default Gateway IP Address You need to define the IP address of the system gateway. This address designates the main entry point into your network. To set the default gateway IP address 1. From the Main System menu, select Network Configuration. The Network Configuration window appears:
Network Configuration Internet IP Address 192.168.3.85 Internet IP Mask 255.255.255.0 Ethernet MAC Address 000203040506 IP Routing Option Transparent Default Gateway IP Address -> 192.168.3.52 SNMP NMS Trap IP Address 192.168.3.52 2. Select Default Gateway IP Address. An arrow appears to the left of the entry field. 3. Press the Enter key. The entry field changes to edit mode. 4. Type the default gateway IP address for the unit. 5. Press the Enter key. The default gateway IP address is applied. Setting the SNMP NMS Trap IP Address The SNMP NMS Trap IP address identifies the IP address of the network manager. This address basically communicates all alarms or events to the network manager. The network manager can define the types of traps, or alarms, that will be forwarded to the IP address. To set the SNMP NMS Trap IP address 1. From the Main System menu, select Network Configuration. The Network Configuration window appears:
Network Configuration Internet IP Address 192.168.3.85 Internet IP Mask 255.255.255.0 Ethernet MAC Address 000203040506 IP Routing Option Transparent Default Gateway IP Address 192.168.3.52 SNMP NMS Trap IP Address -> 192.168.3.52 2. Select SNMP NMS Trap IP Address. An arrow appears to the left of the entry field. Version 1.1 - 01/04/00 55 Configuring Using the Menus 3. Press the Enter key. The entry field changes to edit mode. 4. Type the SNMP NMS Trap IP address for the unit. 5. Press the Enter key. The SNMP NMS Trap IP address appears in the entry field and is applied to the unit. 56 Version 1.1 - 01/04/00 Configuring the Radio Configuring the Radio You can configure the settings for the radio station type and the RF IDs and frequencies using the Radio Configuration window. These settings can be defined for both remote and base stations. You can also configure settings that are specific to remote stations or to base stations. These settings include:
IP Filtering, which applies to only remote stations Polling Frequencies, which is configured and managed through the base station Setting the OFDM Station Type Before you install and start using the 300-24 in a system, you need to define the unit as a base or a remote station. To set the OFDM station type 1. From the Main System menu, select Radio Configuration. 2. Press the Enter key. The Radio Configuration window appears:
Radio Configuration OFDM Station Type -> Remote Unit RF Station Id [0..1023] 2 RF Network Id [0..1023] 0 RF Center Frequency 2.440 GHz 3. Select OFDM Station Type. An arrow appears to the left of the entry field. 4. Press the Enter key. 5. In the OFDM Station Type entry field, select a station type as follows:
To configure a... Do this... Base Station Remote Station In the OFDM Station Type entry field, scroll to select Base Unit. In the OFDM Station Type entry field, scroll to select Remote Unit. 6. Press the Enter key. The unit is configured to the selected unit type. Version 1.1 - 01/04/00 57
Configuring Using the Menus Setting the RF IDs and Center Frequency You need to identify the RF station and network IDs for the unit, and also set the RF center frequency. All units in a given network should use the same frequency so they can communicate with each other. Every unit you configure must have a unique RF Station ID. No two units can have the same ID. To set the RF Station ID 1. From the Main System menu, select Radio Configuration. 2. Press the Enter key. The Radio Configuration window appears:
Radio Configuration OFDM Station Type Remote Unit RF Station Id [0..1023] -> 2 RF Network Id [0..1023] 0 RF Center Frequency 2.440 GHz 3. Select RF Station Id [0..1023]. 4. Press the Enter key. The entry field changes to edit mode. 5. Type a unique number for the RF Station ID. 6. Press the Enter key. The unit is assigned the RF Station ID. To set the RF Network ID 1. From the Main System menu, select Radio Configuration. 2. Press the Enter key. The Radio Configuration window appears:
Radio Configuration OFDM Station Type Remote Unit RF Station Id [0..1023] 2 RF Network Id [0..1023] -> 0 RF Center Frequency 2.440 GHz 3. Select RF Network Id [0..1023]. 4. Press the Enter key. The entry field changes to edit mode. 5. Type a unique number for the RF Network ID. 6. Press the Enter key. The unit is assigned the RF Network ID. 58 Version 1.1 - 01/04/00 Configuring the Radio To ensure communication between units, all units in the network must have the same center frequency. To set the RF center frequency 1. From the Main System menu, select Radio Configuration. 2. Press the Enter key. The Radio Configuration menu appears:
Radio Configuration OFDM Station Type Remote Unit RF Station Id [0..1023] 2 RF Network Id [0..1023] 0 RF Center Frequency -> 2.440 GHz 3. Select RF Center Frequency. 4. Press the Enter key. The entry field is highlighted. 5. Scroll to select the RF center frequency you will apply to all units in the network. 6. Press the Enter key. The center frequency is applied to the unit. Configuring the IP Filter for a Remote Station You can create IP filters to filter the data that is transmitted and received through the 300-24 unit. The remote unit can filter packets received from the wire or air, or both. When you define a filter, you indicate the host and mask IP addresses of the packets that will be received and transmitted to the unit. You can configure IP filters for only remote stations. To configure the IP filter for a remote station 1. From the Main System menu, select IP Filter Configuration. 2. Press the Enter key. The IP Filter Configuration window appears:
IP Filter Configuration - Page 1 Filter Type Host/Net Address Host/Net Mask 1 ->Undefined 0.0.0.0 0.0.0.0 2 Undefined 0.0.0.0 0.0.0.0 3 Undefined 0.0.0.0 0.0.0.0 4 Undefined 0.0.0.0 0.0.0.0 5 Undefined 0.0.0.0 0.0.0.0 6 Undefined 0.0.0.0 0.0.0.0 7 Undefined 0.0.0.0 0.0.0.0 8 Undefined 0.0.0.0 0.0.0.0 9 Undefined 0.0.0.0 0.0.0.0 10 Undefined 0.0.0.0 0.0.0.0 3. Select the Undefined field in the Filter row you are defining. An arrow appears to the left of the field. Version 1.1 - 01/04/00 59 Configuring Using the Menus 4. Press the Enter key. The entry field changes to edit mode. 5. Scroll to select the IP Filter type you are configuring. You can select from:
Select this filter... To... ENET - Wireless (RF) Filter the packets received from the wireline. Wireless (RF) - ENET Filter the packets received from the air. Undefined Not filter the packets. 6. Press the Enter key. The IP Filter Type is defined. 7. Press the right arrow key on the keyboard to move to the Host/Net Address field. 8. Press the Enter key. The entry field changes to edit mode. 9. Type the IP Address of the Host/Net. 10. Press the Enter key. The address is defined. 11. Press the right arrow key on the keyboard to move to the Host/Net Mask field. 12. Press the Enter key. The entry field changes to edit mode. 13. Type the IP Address of the Host/Net Mask. 14. Press the Enter key. You have configured the IP filter. 15. Repeat steps 3 to 14 to define additional IP filters. 60 Version 1.1 - 01/04/00 Configuring the Radio Configuring the Polling List You can configure the polling list for the base station. When you configure the list, you must include the base station and all remote stations in the list. To configure the polling list 1. From the Main System menu, select Remote Station Configuration. The Remote Station Configuration menu appears:
Remote Station Configuration - Page 1 Remote Radio Id Distance Remote Radio Id Distance Remote Radio Id Distance Number 0..1023 0..9999 Number 0..1023 0..9999 Number 0..1023 0..9999 Remote Station Configuration only appears in the Main System menu for units configured as the base station. 1 ->1 1900 2 2 1900 3 0 0 4 0 0 5 0 0 6 0 0 7 0 0 8 0 0 9 0 0 10 0 0 11 0 0 12 0 0 13 0 0 14 0 0 15 0 0 16 0 0 17 0 0 18 0 0 19 0 0 20 0 0 21 0 0 22 0 0 23 0 0 24 0 0 25 0 0 26 0 0 27 0 0 28 0 0 29 0 0 30 0 0 31 0 0 32 0 0 33 0 0 34 0 0 35 0 0 36 0 0 37 0 0 38 0 0 39 0 0 40 0 0 41 0 0 42 0 0 43 0 0 44 0 0 45 0 0 46 0 0 47 0 0 48 0 0 49 0 0 50 0 0 51 0 0 52 0 0 53 0 0 54 0 0 55 0 0 56 0 0 57 0 0 2. 3. In the Radio Id field, type the Radio Station ID for the station (you must identify a unique Radio Id for all remotes and the base station). Note: The order in which you enter the IDs determines the polling sequence of the units. In the Distance field, type the distance, in meters, from the Radio ID to the base station. Following is an example of a completed polling list entry:
Remote Radio Id Distance Number 0..1023 0..9999 1 ->1 1900 The RF Station ID 1 is 1900 meters from the base station. The RF Station ID is 1. The station is the first item in the polling list. Version 1.1 - 01/04/00 61 Configuring Using the Menus 4. Once you have entered the ID and distance for each remote station and the base station, press the Esc key until you exit the Configuration menu. 5. Power down the computer. You have configured the polling list. 62 Version 1.1 - 01/04/00 Using the 300-24 Command Line Using the 300-24 Command Line The 300-24 has a command line interface that you can use to perform basic commands. The commands are a quick way to perform basic tasks while you remain logged into the configuration menus. Using the Basic Commands While you are logged into the configuration menus, you can press the Esc key until you exit out of the menus to the command line prompt. The command line prompt appears as:
wilan>
You can execute all of the 300-24 commands from this prompt. Following are some of the commands you can execute at the prompt:
Type... To... help show the following command summary list:
menu cls dir del ping logout exit quit Example... wilan>help menu menu return to the configuration menus wilan>menu cls dir exit logout quit ping del clear the terminal screen show a file directory log out of the command line interface or terminate a remote telnet session log out of the command line interface or terminate a remote telnet session log out of the command line interface or terminate a remote telnet session wilan>cls wilan>dir wilan>exit wilan>logout wilan>quit ping a remote IP address wilan>ping 198.168.200.5 delete a file wilan>del sample.txt You can contact Wi-LAN customer support for additional information about the command line interface. See Customer Support on page 3 for more information about contacting Wi-LAN. Version 1.1 - 01/04/00 63 Configuring Using the Menus 64 Version 1.1 - 01/04/00 Using SNMP Using the Wi-LAN SNMP MIB Included with each I.WiLL Access Point 300-24 unit (300-24), is a Simple Network Management Protocol (SNMP) permitting configuration, monitoring, and control of:
base stations via the ethernet remote units via the air Units in remote and hard-to-reach locations can be easily configured, and network managers can avoid or reduce downtime by monitoring network throughput, packet collision rates, and interference. SNMP is a protocol you can use to remotely manage a network element by polling, setting terminal values, and monitoring network statistics and events. It is the de-facto internet work management standard, designed to provide a mechanism for the exchange of management information in a TCP/IP-based internet environment. SNMP consists of the following three elements:
SNMP Element Manager Agent Management Information Block (MIB) Description This element is installed on the networks host computer and is controlled by the network administrator. From the host, the Manager configures Agents, or polls Agents for information. The Agent runs on each unit. An Agent accepts configuration commands from the Manager and collects network and terminal information specified in the MIB. The MIB is a database which is accessed by a specific set of commands that you can execute using the SNMP Manager. There is a standard MIB and a Wi-LAN customized MIB that stores information relevant to the operation of a wireless network. Version 1.1 - 01/04/00 65
Using SNMP Using the Wi-LAN MIB Object Identifier Nodes All OID (Object Identifier) nodes in the private Wi-LAN MIB are numbered 1.3.6.1.4.1.2686.n where n is a private Wi-LAN MIB node number or branch of numbers. This number is used in the nodes in the following pages. All nodes containing statistical information are cleared on powerup and reset. Values in all writeable nodes are stored in Flash memory and are retained until overwritten by the administrator, even following power down or reset. 66 Version 1.1 - 01/04/00 V e r s o n i
. 1 1
0 1 0 4
0 0 6 7 Wi-LAN MIB Object Identifier Nodes Following are descriptions of the nodes in the MIB for the 300-24:
Node #
Address/Node Object Type Syntax Access Description 1.1.1 1.1.2 1.1.3 1.1.4 1.1.5 1.1.6 1.1.7 1.1.8 1.1.9 1.3.6.1.4.1.2686.1.1.1 defaultImage INTEGER 1.3.6.1.4.1.2686.1.1.2 1.3.6.1.4.1.2686.1.1.3 ipAddr ipMask IpAddress IpAddress 1.3.6.1.4.1.2686.1.1.4 macAddr PhysAddress 1.3.6.1.4.1.2686.1.1.5 gatewayIpAddr 1.3.6.1.4.1.2686.1.1.6 snmpNmsIpAddr 1.3.6.1.4.1.2686.1.1.7 routingType 1.3.6.1.4.1.2686.1.1.8 stationType 1.3.6.1.4.1.2686.1.1.9 radioId 1.1.10 1.3.6.1.4.1.2686.1.1.10 networkId 1.1.11 1.3.6.1.4.1.2686.1.1.11 centerFreq 1.1.12-
1.1.21 1.1.22 1.3.6.1.4.1.2686.1.1.12 to 1.3.6.1.4.1.2686.1.1.21 vector1 to vector 10 1.3.6.1.4.1.2686.1.1.22 userPassword 1.1.23 1.3.6.1.4.1.2686.1.1.23 superPassword R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W File descriptor id of Image to boot on hard drive. ENET/OFDM bridge IP address. ENET/OFDM bridge IP mask ENET interface MAC address Default Gateway IP address SNMP NMS IP Address (Trap Destination) IP Routing Type: Bridge (1), Filter (3) OFDM Station Type: Base-Stn (1) or Remote (2) RF Station Identifier RF Network Identifier RF Center Frequency (2.410, 2.415, 2.430, 2.440, 2.450, 2.465, 2.470) RF Randomization Vector 1 to RF Randomization Vector 10 System Login User-Level Password R/W System Login Supervisor-Level Password i U s n g t h e W I i
L A N M B O b e c t I j d e n t i f i e r N o d e s IpAddress IpAddress INTEGER
(1, 3) INTEGER
(1, 2) INTEGER
(0..1023) INTEGER
(0..1023) INTEGER INTEGER
(0..65535) DisplayString
(Size 0..31) DisplayString
(Size 0..31) i U s n g S N M P 6 8 Node #
Address/Node Object Type Syntax Access Description 1.1.24 1.3.6.1.4.1.2686.1.1.24 autoLogoutMins INTEGER 1.1.25 1.3.6.1.4.1.2686.1.1.25 ethernetAccess 1.1.26 1.3.6.1.4.1.2686.1.1.26 wirelessAccess 1.1.27 1.3.6.1.4.1.2686.1.1.27 publicName 1.1.28 1.3.6.1.4.1.2686.1.1.28 privateName 1.1.29 1.3.6.1.4.1.2686.1.1.29 ipFilterTable INTEGER
(0, 1) INTEGER
(0, 1) DisplayString
(Size 0..31) DisplayString
(Size 0..31) SEQUENCE of IpFilterEntry 1.1.29.1 1.3.6.1.4.1.2686.1.1.29.1 ipFilterEntry IpFilterEntry 1.1.29.1.1 1.3.6.1.4.1.2686.1.1.29.1.1 ipFilterIndex 1.1.28.1.2 1.3.6.1.4.1.2686.1.1.28.1.2 ipFilterAddr 1.1.28.1.3 1.3.6.1.4.1.2686.1.1.28.1.3 ipFilterMask INTEGER IpAddress IpAddress R/W R/W R/W R/W R/W NA NA RO R/W R/W Input Inactivity Auto-Logout Timeout
(minutes) Enable/Disable Configuration Access Via Ethernet: Disabled (0), Enabled (1) Enable/Disable Wireless Configuration Access: Disabled (0), Enabled (1) SNMP Public Community Name SNMP Private Community Name The list of IP Filter Table entries. An IP Filter entry containing the IP address and mask of the filter. The 1-relative index of the filter in the table. The IP Filter net or host IP address. The mask applied to the filter host or net address. addr & mask = host or net number. For hosts, the mask should be 255.255.255.255. 1.1.30 1.3.6.1.4.1.2686.1.1.30 remoteTable 1.1.30.1 1.3.6.1.4.1.2686.1.1.30.1 remoteEntry SEQUENCE OF RemoteEntry RemoteEntry 1.1.30.1.1 1.3.6.1.4.1.2686.1.1.30.1.1 remoteIndex INTEGER NA The remote unit configuration table. NA RO A Remote Unit Configuration Table entry. The 1-relative index of a unit in the remote configuration table. 1.1.30.1.2 1.3.6.1.4.1.2686.1.1.30.1.2 remoteRadioId INTEGER R/W The radio id for a unit in the remote configuration table. V e r s o n i 1 1
0 1
0 4
0 0 V e r s o n i
. 1 1
0 1 0 4
0 0 6 9 Node #
Address/Node Object Type Syntax Access Description 1.1.30.1.3 1.3.6.1.4.1.2686.1.1.30.1.3 remoteUnits INTEGER 1.2.1 1.2.2 1.2.3 1.3.1 1.3.6.1.4.1.2686.1.2.1 reboot 1.3.6.1.4.1.2686.1.2.2 restFactory 1.3.6.1.4.1.2686.1.2.2 restPoweron 1.3.6.1.4.1.2686.1.3.1 systemStatus 1.3.2 1.3.6.1.4.1.2686.1.3.2 networkStatus 1.3.3 1.3.6.1.4.1.2686.1.3.3 thermalStatus 1.3.4 1.3.5 1.3.6 1.3.7 1.3.8 1.3.9 1.3.6.1.4.1.2686.1.3.4 totalHours 1.3.6.1.4.1.2686.1.3.5 systemHours 1.3.6.1.4.1.2686.1.3.6 powerCycles 1.3.6.1.4.1.2686.1.3.7 thermalFails 1.3.6.1.4.1.2686.1.3.8 loginOkays 1.3.6.1.4.1.2686.1.3.9 1.3.10 1.3.6.1.4.1.2686.1.3.10 loginFails localUser INTEGER reboot (1) INTEGER restore (1) INTEGER restore (1) INTEGER down (0), up (1) INTEGER off-line (0), on-line (1) INTEGER warning (0), normal (1) Counter Counter Counter Counter Counter Counter INTEGER loggedOut(0), loggedIn(1) R/W R/W R/W R/W RO The configuration units for a unit in the remote configuration table. System Reboot Command Restore the Factory Configuration Command Restore the Poweron Configuration Current System Status RO Current LAN Connection Status RO Current System Thermal Status RO RO RO RO RO RO RO Cumulative Run-Time Hours Current Run-Time Hours Since Poweron Total Power Cycle Count Total Thermal Shutdown Count Number of Successful Logins Number of Unsuccessful Login Attempts Local User Login Status i U s n g t h e W I i
L A N M B O b e c t I j d e n t i f i e r N o d e s i U s n g S N M P 7 0 Node #
Address/Node Object Type Syntax Access Description 1.3.11 1.3.6.1.4.1.2686.1.3.11 telnetUser 1.3.12 1.3.6.1.4.1.2686.1.3.12 ftpUser 1.3.13 1.3.14 1.3.15 1.3.16 1.4.1 1.4.2 1.4.3 1.4.4 1.4.5 1.4.6 1.4.7 1.4.8 1.4.9 1.4.10 1.4.11 1.4.12 1.4.13 1.4.14 V e r s o n i 1 1
0 1
0 4
0 0 1.3.6.1.4.1.2686.1.3.13 correctError 1.3.6.1.4.1.2686.1.3.14 uncorrectError 1.3.6.1.4.1.2686.1.3.15 bitErrorRate 1.3.6.1.4.1.2686.1.3.16 currentRssi 1.3.6.1.4.1.2686.1.4.1 etherRxFrames 1.3.6.1.4.1.2686.1.4.2 etherRxDropped 1.3.6.1.4.1.2686.1.4.3 etherRxErrors 1.3.6.1.4.1.2686.1.4.4 etherTxFrames 1.3.6.1.4.1.2686.1.4.5 etherTxDropped 1.3.6.1.4.1.2686.1.4.6 idmaEncodeFrames Counter 1.3.6.1.4.1.2686.1.4.7 idmaDecodeFrames Counter 1.3.6.1.4.1.2686.1.4.8 rsEncSFrames 1.3.6.1.4.1.2686.1.4.9 rsdecSFrames 1.3.6.1.4.1.2686.1.4.10 rsDecSseqErrors 1.3.6.1.4.1.2686.1.4.11 rsDecSseqXtra 1.3.6.1.4.1.2686.1.4.12 rsDecUncFrames 1.3.6.1.4.1.2686.1.4.13 rsDecUncBytes 1.3.6.1.4.1.2686.1.4.14 rsDecCorFrames Counter Counter Counter Counter Counter Counter Counter INTEGER loggedOut(0), loggedIn(1) INTEGER loggedOut(0), loggedIn(1) INTEGER INTEGER INTEGER INTEGER Counter Counter Counter Counter Counter RO Telnet User Login Status RO FTP User Login Status RO RO RO RO RO RO RO RO RO RO RO RO RO RO RO RO RO RO Correctable Error Rate Uncorrectable Error Rate Bit Error Rate Current Received Signal Strength Ethernet Frames Received Ethernet Receive Frames Dropped Ethernet Receive Errors Ethernet Frames Transmitted Ethernet Transmit Frames Dropped RS-Encoder IDMA Transfers RS-Decoder IDMA Transfers RS-Encoder Super Frames RS-Decoder Super Frames RS-Decoder Start Sequence Errors RS-Decoder Start Sequence Extra Bytes RS-Decoder Uncorrectable Frames RS-Decoder Uncorrectable Bytes RS-Decoder Correctable Frames Node #
Address/Node Object Type 1.4.15 1.4.16 1.4.17 1.4.18 1.4.19 1.4.20 1.4.21 1.4.22 1.4.23 1.4.24 1.3.6.1.4.1.2686.1.4.15 rsDecCorBytes 1.3.6.1.4.1.2686.1.4.16 upackSseqErrors 1.3.6.1.4.1.2686.1.4.17 upackSseqXtra 1.3.6.1.4.1.2686.1.4.18 upackHeadErrors 1.3.6.1.4.1.2686.1.4.19 throughputMax 1.3.6.1.4.1.2686.1.4.20 throughputAvg 1.3.6.1.4.1.2686.1.4.21 stackTxEther 1.3.6.1.4.1.2686.1.4.22 stackRxEther 1.3.6.1.4.1.2686.1.4.23 stackTxOfdm 1.3.6.1.4.1.2686.1.4.24 stackRxOfdm Syntax Counter Counter Counter Counter INTEGER INTEGER Counter Counter Counter Counter Access Description RO RO RO RO RO RO RO RO RO RO RS-Decoder Correctable Bytes Unpacking Start Sequence Errors Unpacking Start Sequence Extra Bytes Unpacking Header Errors Maximum Throughput Average Throughput Ethernet Frames Transmitted by Local Host Ethernet Frames Received for Local Host OFDM Frames Transmitted by Local Host OFDM Frames Received for Local Host V e r s o n i
. 1 1
0 1 0 4
0 0 7 1 i U s n g t h e W I i
L A N M B O b e c t I j d e n t i f i e r N o d e s Using SNMP 72 Version 1.1 - 01/04/00 Appendix A: Product Specification Overview Following is the specification for the I.WiLL 300-24 Access Point (300-24). The specification may change without notice. Contact Wi-LAN technical support to ensure that you are working with the most recent specification. See Customer Support on page 3 for information about contacting Wi-LAN. Specification General Specifications Modulation Method:
Wireless Data Rate:
Wire Data Rate:
RF Frequency Range:
Number of Channels:
Power Requirements:
Physical Dimensions:
Approvals:
Combined Direct Sequence Spread Spectrum
& Wide-band Orthogonal Frequency Division Multiplexing (W-OFDM) 30.0 Mbps 21 Mbps 2.4000 - 2.4835 GHz (unlicensed ISM band) 3 (center frequency can be set to any frequency in RF range in 1 MHz increments) 110W @ 115VAC/230VAC 50/60 Hz 43.2 x 37.47 x 9.25 centimeters
(14 x 14.75 x 3.75 inches) Industry Canada, FCC, CE, CEPT Product not available for sale until certification has been obtained. Version 1.1 - 01/04/00 73 Appendix A: Product Specification Radio Specifications Antenna Connector:
Mean OFDM Output Power:
Peak OFDM Power:
Receiver Sensitivity:
Network Support Packet Format:
LAN Connections:
Bridge Functionality:
"N" Male Connector
+15dBm nominal - see back of unit for measured output power 20dBm Note: You must use the Peak OFDM Output Power for link budget calculations.
-78dBm nominal for quasi-error free (10-9 BER) operation - see back of unit for measured Receiver Sensitivity IEEE 802.3 and Ethernet II
(High-level protocol transparent) 10BaseT and 100BaseTX Self-learning packet filtering by MAC address
(protocol independent) Media Support:
10BaseT or 100BaseTX Wireless Networking Protocols Network Topologies:
Point-to-Point, Point-to-Multipoint, Multipoint-
to-Multipoint Repeater Mode:
User Configurable RF Collision Management:
Polling, with Dynamic Time Allocation Security IP Filtering Configuration, Management, and Diagnostics Configuration Methods:
SNMP, Telnet, RS-232 Management Port SNMP:
Management Port:
Management Port Functionality:
Version I, Standard and Enterprise MIBs Menu driven ASCII interface via RS-232, DB-9 connector Supports system configuration, security, access control, wireless LAN diagnostics and management 74 Version 1.1 - 01/04/00 Appendix B: Monitor and Test Links Overview You can monitor and test the 300-24 link once it is powered up, has an antenna attached to it, and is receiving data. All link mode statistics appear in the MAC Layer Statistics window. See Viewing the MAC Layer Statistics on page 39 for detailed information about the window. You need to monitor the following three link mode statistics:
Received Signal Strength Indicator (RSSI) Null Depth Fade Margin Monitoring RSSI The RSSI is the strength of the received signal in dBm (decibels referenced to a milliWatt). When monitoring the RSSI, ensure that it meets the following statistical criteria:
RSSI Element Noise Floor Signal to Noise Ratio Quasi Error Free RSSI Required for Quasi Error Free Operation Required Measurement
-95dBm 17dBm for quasi error free operation 1 error in 109 bits after forward error correction
-95dBm + 17dBm = -78dBm Receiver Sensitivity
-78dBm In a real application, a fade margin is required to allow for rain fading or other reception anomalies. See Monitoring Fade Margin on page 76 for more information. At the other extreme, the receive signal strength cannot be greater than -45dBm or the receive LNA will saturate. If the RSSI is greater than -45dBm you must add sufficient attenuation at the remote site to bring the RSSI down to an acceptable level. Note: Check the back of the 300-24 unit for a label identifying that a RSSI Correction Factor has been applied to the unit. If so, apply the following correction factor:
Actual_RSSI = RSSI - RSSI_Correction_Factor Version 1.1 - 01/04/00 75
Appendix B: Monitor and Test Links Monitoring Null Depth The Null Depth is the ratio in dB between the strongest OFDM carrier and the weakest carrier. A Null Depth of greater than 0 dB indicates that there is no multipath reception. Some multipath is usually present in your link, however adjustments to the position or location of the receive antenna at the remote site can minimize the Null Depth. In some cases, you cannot adjust the antenna position and location of the receive antenna at a remote site. Monitoring Fade Margin The Fade Margin is the receive power in excess of the minimum required for error free operation. See Monitoring RSSI on page 75 for information about receive power. Fade Margin is computed for you using the following formula:
Formula Example Variables Fade Margin = RSSI - Null Depth - Receiver Sensitivity RSSI Null Depth Receiver Sensitivity Fade Margin
-62dBm 3dB
-78dBm 13dB Calculation Fade Margin = -62dBm - 3dB - -78dBm Fade Margin = 13dB Thus, we have verified that the correct Fade Margin of 13dB is displayed. Note: Check the back of the 300-24 unit for a label identifying that a Fade Margin Correction Factor has been applied to the unit. If so, apply the following correction factor:
Actual Fade_Margin = Fade_Margin - Fade_Margin_Correction_Factor Performing a Link Test Linktest is a diagnostic tool for setting up and diagnosing links. Typically, you use linktest when you:
initially set up a remote diagnose a problem link Linktest generates pseudo-random packets of information that are transmitted to the station ID provided. The unit, or station ID, compares the pseudo-random data and accumulates bit errors, RSSI, Fade Margin, and Forward Error Correction (FEC) statistics. These statistics and regenerated pseudo-random data are sent in a packet back to the originating unit. The originating unit then compares the pseudo-random data and at approximately one second intervals, displays the accumulated statistics in the configuration menus. Before you start a linktest, you need the station ID of the base station. See Setting the RF IDs and Center Frequency on page 58 for information about viewing station ID settings. 76 Version 1.1 - 01/04/00
Performing a Link Test To start a linktest 1. At the remote station from which you are performing the linktest, access the configuration menus. See Accessing the Menus on page 31 for more information about accessing the menus. 2. Press the Esc key until you enter the command line mode. See Using the 300-24 Command Line on page 63 for more information about the command line. The following command line appears:
wilan>
3. At the command line prompt, type:
linktest <station id of the basestation>
4. Press the Enter key. The following linktest results appear:
R = Remote to the unit running linktest. L = Local to the unit running linktest. RSSI Fade Margin FEC corrected BER(x1E6) R L R L R L R L
-52 -51 22 22 0 0 0 0
-52 -53 22 21 0 0 0 0
-52 -52 22 22 0 0 0 0
-52 -53 22 20 0 0 0 0
-52 -52 22 23 0 0 0 0
-53 -52 21 23 0 0 0 0
-52 -52 22 22 0 0 0 0 Following is a description of the information displayed in the linktest results screen:
This... Indicates... R L RSSI Fade Margin BER(x1E6) FEC Corrected The statistics corresponding to the base station receive. Note: This applies if you are running linktest on the remote to the base station. The statistics corresponding to the remote unit receive. Note: This applies if you are running linktest on the remote to the base station. The received signal strength indicator. The fade margin is calculated as the number of dB that the received signal strength exceeds the minimum receiver sensitivity. The bit error rate after forward error correction. The byte errors that were corrected by forward error correction. Version 1.1 - 01/04/00 77 Appendix B: Monitor and Test Links Note: If the link is bad and packets generated by the linktest are not received at the other end, the following message appears:
No packets received 5. Press any key to exit linktest and return to the command line prompt. 78 Version 1.1 - 01/04/00 Appendix C: Upgrading Software Overview You can upgrade the software on the 300-24 using one of the following methods:
upgrading the new software via FTP installing the new software EEPROMS in the unit This section provides instruction on how to upgrade your software via FTP; instructions on how to install new software EEPROMS are including in the shipment of new EEPROMS. Upgrading Software via FTP This procedure uses the IP address 192.168.3.85 in all steps. The IP address you use should be for your specific 300-24 unit. You can download all new software to your 300-24 unit through an FTP connection from your computer. This procedure assumes that you have a copy of the updated software on your computer. Contact Wi-LAN customer support for assistance downloading the updated software from the Wi-LAN FTP server to your local computer. See Customer Support on page 3 for information about contacting Wi-LAN support. To upload software via FTP 1. Start a DOS session on your computer. For information about starting a DOS session, refer to your Windows online help. 2. At the c:\ prompt, type:
cd \projects\wib\current\bin Note: The new software must be saved on your computer in the above directory. 3. Type ftp <IP address of the 300-24 unit>
Note: There is a space between ftp and the IP address. The following example uses the IP address 192.168.3.85 for the 300-24 unit. The DOS session window appears as:
The IP address for your specific 300-24 unit will appear here. c:\projects\wib\current\bin ftp 192.168.3.85 Connected to 192.168.3.85 220 Wi-LAN 300-24 OFDM Ethernet Bridge FTP Server User (192.168.3.85(none)):
Version 1.1 - 01/04/00 79
Appendix C: Upgrading Software 4. At the User prompt, type ofdm. 5. Press the Enter key. The password prompt appears. 6. At the Password prompt, type the supervisor password for the 300-24 unit. Note: The password is configured in the configuration menus. See Setting Passwords on page 44 for more information about setting the password and to view the default password. 7. Press the Enter key. The DOS session window appears as:
C:\projects\wib\current\bin> ftp 192.168.3.85 Connected to 192.168.3.85 220 Wi-LAN 300-24 OFDM Ethernet Bridge FTP Server User (192.168.3.85(none)):ofdm 331 Password required Password:
230 Supervisor logged in ftp>
8. At the ftp prompt, type put ..\<filename>
where
<filename> represents the image file you are downloading. Note: There is a space after you type put. 9. Press the Enter key. The file starts downloading to the 300-24, and when the download is complete the DOS session window appears as:
C:\projects\wib\current\bin> ftp 192.168.3.85 Connected to 192.168.3.85 220 Wi-LAN 300-24 OFDM Ethernet Bridge FTP Server User (192.168.3.85(none)):ofdm 331 Password required Password:
230 Supervisor logged in ftp>put ..\<filename>
200 Port set okay 150 Opening binary mode connection 226 Transfer complete 10484 bytes sent in 0.11 seconds (95.31 Kbytes/sec) ftp>bye 10. At the ftp> prompt, type bye. The prompt returns to c:\projects\wib\current\bin>, and the ftp connection is closed. 80 Version 1.1 - 01/04/00 Upgrading Software via FTP Using the Upgraded Software Once you have uploaded the new software, you need to configure the unit to start using it. To select the upgraded software
! Use the configuration menus to select the new software. Follow the procedures in Setting the Default Image on page 46 to select the new software. Version 1.1 - 01/04/00 81 Appendix C: Upgrading Software 82 Version 1.1 - 01/04/00 Glossary A B agent In a SNMP context, the agent runs on each unit. An agent accepts configuration commands from the manager and collects network and terminal information specified in the MIB. antenna A device which takes electromagnetic energy from a circuit or wire and radiates it into space rather than confining it. antenna gain Gain of the antenna over a dipole (dBd) or theoretical (dBi). attenuation Any loss in signal strength, due to resistance, absorption, capacitance, or any characteristic of the medium or design of the system. bandwidth The span in hertz, that the information-bearing signal occupies or requires, or the difference in hertz between the lowest and highest frequencies of a band. baud A measurement unit which defines the number of symbols per second (or signaling units per second). BER Bit Error Rate. A percentage of bits per million, showing the number of bits in error compared to the data bits actually sent. Version 1.1 - 01/04/00 83 Glossary C D 84 cable loss The signal loss experienced as it passes through the coax cable. Expressed in dB. channel The width of the spectrum band taken by a radio signal, usually measured in kilohertz (kHz). chip rate Chip rate signifies the time occupied by that single frequency. Also the period of a code clock, or the output of a code generator during one clock interval. coaxial cable A type of wire where the inner conductor is surrounded by an outer conductor. The outer conductor serves as an electrical shield. collision The situation that exists when two users try to send a signal over the same medium at the same time, and the signal uses the same frequencies. CRC Cyclic Redundancy Checksum Code. Based on mathematical theories, the CRC allows a small number of checking bits to show whether the overall stream of bits has any errors in it. dB Decibel. A relative measure of power used to specify power gains and losses. The difference in power P1 and P2 expressed in dB is:
dB
10 log P1
P2 dBd The gain or loss of an antenna referenced to a standard dipole. Gain of a Standard Dipole = 2.14 dBi. dBi The gain or loss of an antenna referenced to an isotropic (theoretical point source) radiator. This measure is used with only antennas, as it quantifies gain or loss of a physical radiator with respect to a theoretical one. dBm A power measurement referenced to one milli-Watt. This is an absolute measure of power rather than a relative measure such as a gain or a loss. DB9 A D-shaped connector with 9 pins. Version 1.1 - 01/04/00 E F I M EEPROM Electrically Erasable Programmable Read-Only Memory. Non-volatile memory. ERP Effective Radiated Power. The power radiating from an antenna taking into account the output power from the transmitter, connector losses, cable losses, and the antenna gain. ETSI European Telecommunications Standards Institute. fade margin The amount that the system gain plus the total antenna gain exceeds the path loss is called the fade margin. The fade margin is calculated as the number of dB that the received signal strength exceeds the minimum receiver sensitivity. Fresnel Zone The Fresnel Zone is the expansion of the RF signal radio angles in the vertical plane near the middle of the RF path. IEEE Institute of Electrical and Electronics Engineers. interference Any signal that tends to hamper the normal reception of a desired signal. ISM Industrial, Scientific, and Medical. It is the license-exempt radio band in North America and some European countries. It is also referred to as part 15.247 in the FCC regulation that defines the parameters for use of the ISM band in the U.S., including power outputs, spread-spectrum, and noninterference. MAC Address Media Access Controller Address. Alphanumeric characters that uniquely identify a network-connected device. Management Information Block See MIB. manager When used in SNMP, this element is installed on the networks host computer and is controlled by the network administrator. From the host, the manager configures agents, or polls agents for information. Version 1.1 - 01/04/00 85 Glossary O P R S 86 MIB Management Information Block. The MIB is a database which is accessed by a specific set of commands that you can execute using the SNMP Manager. There is a standard MIB and a Wi-LAN customized MIB that stores information relevant to the operation of a wireless network. OID nodes Object Identifier Nodes. These are the individual nodes in a MIB. See SNMP and MIB. path loss The total loss from one end of the path to the other. This includes propagation losses, cable losses, and any other losses that impact the system performance. propagation loss The signal loss experienced as it travels through the air. Expressed in dB. RF System of communication employing electromagnetic waves propagated through space. Because of varying characteristics, radio waves of different lengths are employed for different purposes and are usually identified by their frequency. RS-232/422/423/485 Standards for serial communications, which define the voltages, currents, data rates, and other factors about the signals to be used, as well as single-ended, differential, and multi-drop operation. sensitivity The minimum signal strength required for usable performance. Expressed in dBm. SNMP Simple Network Management Protocol. A protocol you can use to remotely manage a network element by polling, setting terminal values, and monitoring network statistics and events. It is the de-facto internet work management standard, designed to provide a mechanism for the exchange of management information in a TCP/IP-based Internet environment. spread spectrum Any of a group of modulation formats in which a RF bandwidth much wider than necessary is used to transmit an information signal so that a signal-to-noise improvement may be gained in the process. Version 1.1 - 01/04/00 system gain The maximum path loss that the system can support for usable data transmission. W W-OFDM Wide-band Orthogonal Frequency Division Multiplexing. A modulation scheme that encodes data inside a radio frequency signal. OFDM sends a high-speed signal concurrently on different frequencies. This allows for very efficient use of bandwidth and provides for robust communications that can transmit through interferences, such as occurring noise and stray and reflected signals, that can encumber radio communications. Version 1.1 - 01/04/00 87 Glossary 88 Version 1.1 - 01/04/00 Index Numerics 10/100 BaseT Ethernet connector 7 A about this guide 1 access types setting 42 accessing configuration menus 3134 adaptors in shipping package 9 adjusting antennas 29 agent 65 antenna gain 19 link budgets 18 requirements 19 antennas attaching to mast 27 coaxial cable requirements 27 connector 7, 74 drip loops 27 fine-tuning 29 in shipping package 9 installation requirements 10 installing 27 outdoor 10 polarity requirements 27 pre-installation tasks 10 selecting 19 weatherproofing requirements 27 arrow keys setting in telnet sessions 34 audience guide 1 automatic timeouts logging in after 45 setting 45 B back panel 5, 7 connectors 7 base stations configuring 57 pre-configuring 12 RF station ID 13 basic command line 63 Bit Error Rate (BER) linktest displays 77 measuring 25 bridge functionality 74 C cable loss calculating 21 link budgets 18 ratings 21 cables calculating loss 21 in shipping package 9 requirements 11 using surge suppressors 11 calculating cable loss 21 effective radiated power 19 Fresnel radius 21 link budgets 17 path loss 22 propagation loss 20 system gain 18 center frequencies configuring 58, 59 channels number of 73 coaxial cables for antennas 27 Version 1.1 - 01/04/00 89 Index collision management RF 74 colors of LEDs 6 command line basic commands 63 community names setting 43 configuration menus accessing 31 accessing through a console 32 accessing via telnet 33 exiting 34 logging into 33 navigating 31 using arrow keys 34 configuration settings restoring 48 restoring factory configuration 48 restoring poweron settings 48 configuring center frequencies 58 default gateway IP address 55 ethernet MAC address 53 internet IP address 52 internet IP mask 52 IP filters for remote stations 59 IP routing options 54 IP settings 5256 methods 31 OFDM station type 57 polling lists 61 radios 5762 RF IDs 58 RF network IDs 58 SNMP NMS trap IP address 55 stations before installation 11 connecting 300-24 to LAN 29 for installations 29 to LAN 74 connectors 10/100 BaseT Ethernet 7 antenna 7, 74 back panel 7 DB9 serial port 7 front panel 5 serial port 5, 7 conventions in this guide 2 copyright notice v customer support e-mail messages 3 for missing items 10 in North America 3 outside of North America 3 phone numbers 3 D data encryption 74 data rates wire 73 wireless 73 dB dBd 17 dBi 17 dBm 17 terms used 17 DB9 serial port connector 7 default IP gateway address 55 passwords 12 system image file 46 definitions antenna gain 18 cable loss 18 dBd 17 dBi 17 dBm 17 ERP 18 null depth 76 path loss 18 propagation loss 18 sensitivity 18 system gain 18 distances between sites 10 setting in menus 15 drip loops antennas 27 E effective radiated power 18 calculating 19 formula 19 e-mail messages customer support 3 ethernet access setting 42 ethernet MAC address setting 53 90 Version 1.1 - 01/04/00 events tracking 50 exiting linktests 78 menus 34 F face plate for rack installations 30 factory configuration restoring 48 fade margins 11, 22 linktests 77 monitoring 76 FEC linktest displays 77 fields MAC Layer Statistics window 39 System Current Status window 37 System Revision Information window 35 System Software ROM Images window 36 fine-tuning antennas 29 format packet 74 formulas effective radiated power 19 Fresnel radius 21 path loss 22 propagation loss 20 system gain 18 frequency range RF 73 Fresnel radius calculations 21 formulas 21 Fresnel zone 20 front panel 5 connectors 5 illustration 5 LEDs 6 FTP using to upgrade software 79 functionality bridge 74 management port 74 Index G getting help 3 grounding 10 using the ground screw 8 guide audience 1 conventions 2 copyright notices v user notices v H hardware verifying revision numbers 27 viewing version 35 I image files rebooting 47 setting 46 installation requirements 9 shipping package contents 9 installing AC Power Level Switch 27 antennas 27 base stations 2729 completing connections 29 on a rack 30 powering up units 27 rack size 30 remote stations 2729 verifying hardware revision numbers 28 verifying RF port 28 verifying software revision numbers 28 intended audience 1 internet IP mask setting 52 IP address setting 52 IP filters configuring for remote stations 59 IP mask setting 52 IP routing option setting 54 IP settings configuring 5256 default gateway IP address 55 ethernet MAC address 53 Version 1.1 - 01/04/00 91 Index IP settings (cont) internet IP mask 52 IP routing options 54 SNMP NMS trap IP address 55 ISM band 1 L LAN connections 74 from 300-24 29 LEDs colors 6 on front panel 6 status 6 types 6 lightening arrestors 10 link budgets antenna gain 18 cable loss 18 calculating 17 effective radiated power 18 path loss 18 propagation loss 18 sensitivity 18 system gain 18 variables 18 verifying 24 link mode monitoring 7576 link statistics measuring 24 linktests 76 BER 77 exiting 78 fade margins 77 FEC 77 performing 7678 performing on remotes 76 RSSI 77 locations of units in site 10 logging in after automatic timeout 45 to menus 33 loopback mode entering 49 M MAC layer statistics resetting 50 viewing 39 window fields 39 bit error rate 25 link statistics 24 media support 74 menus management port functionality 74 measuring accessing through a console 32 exiting 34 logging into 33 MIB 65 modes Wi-LAN OID nodes 6771 missing items contacting customer support 10 entering loopback mode 49 entering normal mode 49 repeater 74 modulation method 73 monitoring fade margin 76 link mode 7576 null depth 76 RSSI 75 N names system image files 35 navigating configuration menus 31 network topologies 74 nodes OID 66 noise floor 75 normal mode entering 49 notices copyright v user v null depth definition 76 monitoring 76 92 Version 1.1 - 01/04/00 O OFDM station selecting type 12 OID nodes 66 outdoor antennas 10 output power 74 overview completing pre-installation 9 configuring the menus 31 get started 5 installing base and remote stations 27 monitor link mode 75 of sections 1 product 1 production specification 74 setting the RF link 17 upgrading software 79 P packet format 74 panels back 5, 7 connectors on back 7 connectors on front 5 front 5 LEDs on front 6 passwords default 12 setting supervisor passwords 44 setting user passwords 44 path loss calculating 22 formula 22 link budgets 18 phone numbers customer support 3 physical dimensions of 300-24 73 rack size 30 polarity requirements antennas 27 polling lists configuring 61 pre-configuring 14 power AC power switch 27 output 74 requirements 73 supply cord 9 Version 1.1 - 01/04/00 poweron settings restoring 48 pre-configuring base stations 12 polling list 14 RF station ID 13 stations 1115 pre-installation 915 cable requirements 11 fade margins 11 planning physical layout 10 prerequisites 9 radio path 10 weather requirements 11 preliminary site layout 10 product specification 73 propagation loss calculating 20 formula 20 Fresnel zone 20 link budgets 18 Q quasi error free 75 R rack installations 30 rack size 30 radio paths checking 10 checking before installation 10 radios configuring 5762 configuring polling lists 61 resetting statistics 50 setting OFDM station type 57 RAM in 300-24 35 ratings of cable loss 21 rebooting system image files 47 receiver sensitivity 74 regulatory approvals 73 regulatory bodies ETS 20 FCC 20 Industry Canada 20 Index 93 Index remote stations configuring 57 configuring IP filters 59 performing linktests 76 RF station ID 13 repeater mode 74 requirements installation 9 power 73 RSSI 75 resetting MAC layer statistics 50 radio statistics 50 statistics 50 restoring factory configuration settings 48 poweron configuration settings 48 RF collision management 74 frequency range 73 links 17 RF IDs configuring 58 configuring network ID 58 pre-configuring stations ID 13 RF ports verifying 28 ROM in 300-24 35 RS-232 Management Port Configuration 31 RSSI linktest display 77 maximum dBm 75 monitoring 75 noise floor 75 quasi error free 75 receiver sensitivity 75 required for quasi error free operation 75 signal to noise ratio 75 statistical criteria 75 S scrambling 74 security access types 42 community names 43 setting automatic timeouts 45 setting passwords 44 system 42 selecting antennas 19 OFDM station type 12 sensitivity link budget variable 18 serial port connector 5, 7 setting automatic timeouts 45 default gateway IP address 55 default system image file 46 distance between sites 10 ethernet access 42 internet IP address 52 internet IP mask 52 IP routing options 54 passwords 44 RF center frequencies 59 SNMP NMS trap IP address 55 SNMP private community name 43 SNMP public community names 43 supervisor passwords 44 user passwords 44 wireless access 42 shipping package contents 9 signal to noise ratio 75 sites determining distance between 10 SNMP agent 65 configuration 31 MIB 65 OID nodes 66 setting community names for 43 setting private community names 43 setting public community names 43 version 74 Wi-LAN MIB 6571 SNMP NMS trap IP address setting 55 software uploading via FTP 79 verifying revision numbers 27 specifications product 73 stations pre-configuring 11 setting distance between 15 94 Version 1.1 - 01/04/00 statistics MAC layer statistics 50 radio statistics 50 resetting 50 status LEDs 6 supervisors setting passwords 44 surge suppressors at cable entry 11 System Current Status window fields 37 system gain calculation 18 formula 18 how to use 18 variables 18 system image files names 35 rebooting 47 setting the default 46 versions 35 working with 4647 system information MAC layer statistics 39 system software ROM images 36 viewing 35 viewing current system status 37 viewing system revision 35 System Revision Information window system security 42 System Software ROM Images window fields 35 fields 36 T telnet accessing configuration menus 33 configuration 31 setting arrow keys in sessions 34 tracking events 50 troubleshooting 3 U units locations in site 10 upgraded software using 81 Version 1.1 - 01/04/00 upgrading software 7981 via FTP 79 users notices v setting passwords 44 V variables link budgets 18 system gain 18 verifying hardware revision numbers 27 link budgets 24 RF ports 28 software revision numbers 27 versions hardware 35 system image files 35 viewing current system status 37 system revision information 35 system software ROM images 36 W weatherproofing antennas 27 requirements 11 wire data rate 73 wireless access setting 42 wireless data rate 73 Index 95
| frequency | equipment class | purpose | ||
|---|---|---|---|---|
| 1 | 2001-06-04 | 2415 ~ 2465 | DTS - Digital Transmission System | Original Equipment |
| app s | Applicant Information | |||||
|---|---|---|---|---|---|---|
| 1 | Effective |
2001-06-04
|
||||
| 1 | Applicant's complete, legal business name |
Wi Lan Inc
|
||||
| 1 | FCC Registration Number (FRN) |
0007024714
|
||||
| 1 | Physical Address |
2891 Sunridge Way N.E.
|
||||
| 1 |
Calgary, AB, N/A T1Y 7K7
|
|||||
| 1 |
Canada
|
|||||
| app s | TCB Information | |||||
| n/a | ||||||
| app s | FCC ID | |||||
| 1 | Grantee Code |
K4B
|
||||
| 1 | Equipment Product Code |
AP01
|
||||
| app s | Person at the applicant's address to receive grant or for contact | |||||
| 1 | Name |
I**** G****
|
||||
| 1 | Title |
Regulatory/Certification
|
||||
| 1 | Telephone Number |
403-2********
|
||||
| 1 | Fax Number |
403-2********
|
||||
| 1 |
i******@wi-lan.com
|
|||||
| app s | Technical Contact | |||||
| n/a | ||||||
| app s | Non Technical Contact | |||||
| n/a | ||||||
| app s | Confidentiality (long or short term) | |||||
| 1 | Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?: | Yes | ||||
| 1 | Long-Term Confidentiality Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?: | No | ||||
| if no date is supplied, the release date will be set to 45 calendar days past the date of grant. | ||||||
| app s | Cognitive Radio & Software Defined Radio, Class, etc | |||||
| 1 | Is this application for software defined/cognitive radio authorization? | No | ||||
| 1 | Equipment Class | DTS - Digital Transmission System | ||||
| 1 | Related OET KnowledgeDataBase Inquiry: Is there a KDB inquiry associated with this application? | No | ||||
| 1 | Modular Equipment Type | Does not apply | ||||
| 1 | Purpose / Application is for | Original Equipment | ||||
| 1 | Composite Equipment: Is the equipment in this application a composite device subject to an additional equipment authorization? | No | ||||
| 1 | Related Equipment: Is the equipment in this application part of a system that operates with, or is marketed with, another device that requires an equipment authorization? | No | ||||
| 1 | Grant Comments | This authorization is approved under the interim blanket waiver for Digital Transmission Systems meeting the requirements pursuant to the Further Notice of Proposed Rulemaking and Order, ET Docket No. 99-231 (FCC 01-158). The authorization is conditioned upon compliance with any final rules that may be adopted in the proceeding. | ||||
| 1 | Is there an equipment authorization waiver associated with this application? | No | ||||
| 1 | If there is an equipment authorization waiver associated with this application, has the associated waiver been approved and all information uploaded? | No | ||||
| app s | Test Firm Name and Contact Information | |||||
| 1 | Firm Name |
Nemko Canada Inc.
|
||||
| 1 | Name |
S**** B******
|
||||
| 1 | Telephone Number |
613-7********
|
||||
| 1 | Fax Number |
613-7********
|
||||
| 1 |
s******@nemko.com
|
|||||
| Equipment Specifications | |||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
| 1 | 1 | 15C | 2415.00000000 | 2465.00000000 | 0.0700000 | ||||||||||||||||||||||||||||||||||||
some individual PII (Personally Identifiable Information) available on the public forms may be redacted, original source may include additional details
This product uses the FCC Data API but is not endorsed or certified by the FCC