Proxim Wireless MB82HP49 Tsunami 8000 Point-to-Point and Point-to-multipoint Product User Manual

Proxim Wireless Corporation Tsunami 8000 Point-to-Point and Point-to-multipoint Product

User Manual

Tsunami® 8100 Series
(Point-to-point and Point-to-multipoint Products)
Software Management Guide
Products Covered
Tsunami® MP-8100-BSU / MP-8100-WD-HP
- Tsunami® MP-8100-SUA / MP-8100-WD-HP
- Tsunami® MP-8150-SUR / MP-815-WD-HP
- Tsunami® MP-8150-CPE
Tsunami® MP-8160-BSU
- Tsunami® MP-8160-SUA
- Tsunami® MP-8160-CPE
Tsunami® QB-8100-EPA
Tsunami® QB-8100-LNK
Tsunami® QB-8150-EPR
Tsunami® QB-8150-LNK
Tsunami® QB-8150-LNK-12/50
Copyright
© 2011 Proxim Wireless Corporation, Milpitas, CA. All rights reserved. Covered by one or more of the following U.S. patents: 5,231,634;
5,875,179; 6,006,090; 5,809,060; 6,075,812; 5,077,753. The content described herein are copyrighted with all rights reserved. No part of this
publication may be reproduced, transmitted, transcribed, stored in a retrieval system, or translated into any language in any form by any means
without the written permission of Proxim Wireless Corporation.
Trademarks
Tsunami®, Proxim, and the Proxim logo are the trademarks of Proxim Wireless Corporation. All other trademarks mentioned herein are the property of their
respective owners.
Disclaimer
Proxim reserves the right to revise this publication and to make changes in content from time-to-time without obligation on the part of Proxim to provide
notification of such revision or change. Proxim may make improvements or changes in the product(s) described in this manual at any time. When using
this device, basic safety precautions should always be followed to reduce the risk of fire, electric shock and injury to persons.
GPL License Note
Tsunami® products include software code developed by third parties, including software code subject to the GNU General Public License ("GPL") or GNU
Lesser General Public License ("LGPL"). Please see the GPL and LGPL Web sites to view the terms of each license.
To access the GPL Code and LGPL Code used, visit the Proxim Web site (http://support.proxim.com) to get a copy of the source. The GPL Code and
LGPL Code used in this device are distributed WITHOUT ANY WARRANTY and are subject to the copyrights of one or more authors.
For details, see the GPL Code and LGPL Code of this device and the terms of the GPL and LGPL.
Tsunami® 8100 Series - Software Management Guide
Documentation Version: 4.0
P/N 765-00131, November 2011
Tsunami® 8100 Series - Software Management Guide 2
Contents
Preface. . . 8
1 Overview . . . ........................................................................................................................................ 10
About Tsunami® 8100 Products . 10
Wireless Network Topology . 11
Point-to-Multipoint (PTMP). . . 11
Point-to-Point Link . . . 14
Multiple-Input-Multiple-Output (MIMO) . . . . 17
Wireless Outdoor Router Protocol (WORP) . . . . 17
2 Management and Monitoring Capabilities . . . .................................................................................... 19
Web (HTTP/HTTPS) Interface . . . . 19
Command Line Interface . . . . 19
HyperTerminal . . . 19
Telnet. . . 20
Secure Shell (SSH) . . . 20
SNMP Management . . . . 20
ProximVision ES . . . . 20
3 Device Initialization . . . 21
Initialization . . . . 21
ScanTool . . . 21
Initialize Device using ScanTool. . . 22
Modifying the IP Address of the Device using ScanTool . . . 23
Logging onto the Web Interface . 23
Home Page . . . 25
COMMIT . . . 26
REBOOT. . . 27
Factory Default Configuration . 27
4 Basic Configuration . . . ....................................................................................................................... 29
5 Advanced Configuration . . . 34
System . . . . 34
Network . 35
IP Configuration (Bridge Mode) . . . 36
IP Configuration (Routing Mode) . . . 38
IP Configuration (Routing Mode with PPPoE Client Enabled) 40
Ethernet . 42
Basic Ethernet Configuration . . . 42
Advanced Configuration . . . 43
Wireless . . . . 44
Tsunami® 8100 Series - Software Management Guide 3
Wireless Outdoor Router Protocol (WORP). . . 44
Wireless Interface Properties . . . 49
MIMO Properties . . . 57
Dynamic Frequency Selection (DFS) . . . 59
DDRS. . . 64
Security . . . . 68
Wireless Security . . . 68
RADIUS . . . 71
MAC ACL . . . 73
Quality of Service (QoS) . . . . 74
QoS Concepts and Definitions . . . 74
QoS Configuration . . . 79
QoS Configuration for a Management Station . . . 96
RADIUS Based SU QoS Configuration . 100
VLAN (Bridge Mode Only) . . . . 101
System-Level VLAN Configuration . . . 101
Ethernet VLAN Configuration . . . 102
RADIUS Based SU VLAN Configuration . 107
Filtering (Bridge Only) . 109
Protocol Filter . . . 110
Static MAC Address Filter . . . 113
Advanced Filtering. . . 116
TCP/UDP Port Filter . . . 118
Storm Threshold Filter . . . 120
WORP Intra Cell Blocking. . . 121
DHCP . . . . 125
DHCP Pool. . . 125
DHCP Server . . . 126
DHCP Relay (Routing Mode only). . . 127
IGMP Snooping . . . . 128
Routing Mode Features . . . . 130
Static Route Table . . . 130
Network Address Translation (NAT) . . . 132
RIP. . . 135
PPPoE End Point (SU Only) . . . 136
IP over IP Tunneling . . . 142
6 Management. . . ...................................................................................................................................... 147
System . 147
System Information . . . 147
Inventory Management . . . 148
Licensed Features . . . 149
Tsunami® 8100 Series - Software Management Guide 4
File Management . . . . 150
TFTP Server . . . 150
Text Based Configuration (TBC) File Management . . . 151
Upgrade Firmware. . . 153
Upgrade Configuration . . . 154
Retrieve From Device . . . 156
Services . . . . 159
HTTP/HTTPS. . . 159
Telnet/SSH . . . 160
SNMP . . . 162
Logs . . . 165
Simple Network Time Protocol (SNTP) . 167
Access Control . 169
Reset to Factory . . . . 170
Convert QB to MP . . . . 171
7 Monitor . . . 173
Interface Statistics . 173
Ethernet Statistics . . . 173
Wireless Statistics 175
PPPoE Statistics . . . 176
IP Tunnels . . . 177
WORP Statistics . . . . 179
General Statistics. . . 179
SU / End Point B Link Statistics. . . 181
BSU/End Point A Link Statistics. . . 184
QoS Statistics (BSU or End Point A Only) . . . 185
Active VLAN . 186
Bridge . . . . 187
Bridge Statistics . . . 187
Learn Table . . . 188
Network Layer . . . . 189
Routing Table . . . 189
IP ARP . . . 189
ICMP Statistics. . . 190
RIP Database . . . 191
RADIUS (BSU or End Point A only) . . . . 192
Authentication Statistics . . . 192
IGMP . . . . 193
Ethernet or Wireless Multicast List . . . 193
Router Port List . . . 194
Tsunami® 8100 Series - Software Management Guide 5
DHCP . . . . 194
Logs . 195
Event Log . . . 195
Syslog . . . 196
Debug Log . . . 196
Temperature Log . . . 197
Tools . 198
Wireless Site Survey. . . 198
Scan Tool. . . 199
sFlow® . . . 199
Console Commands . . . 204
SNMP v3 Statistics . . . . 204
8 Troubleshooting . . . 205
PoE Injector . . . . 206
Connectivity Issues . 206
Surge or Lightning Issues (For Connectorized devices) . 207
Setup and Configuration Issues . . . . 208
Application Specific Troubleshooting . 209
Wireless Link Issues . 210
Wired (Ethernet) Interface Validation . . . . 211
Wireless Interface Validation . 212
Recovery Procedures . 213
Soft Reset to Factory Defaults . . . 213
Hard Reset to Factory Defaults. . . 213
Forced Reload . . . 214
Setting IP Address using Serial Port . . . 216
Spectrum Analyzer . 217
Avoiding Interference . . . 218
Conclusion . . . 218
Miscellaneous . 218
Unable to Retrieve Event Logs through HTTPS . . . 218
A Feature Applicability . . . 219
B Parameters Requiring Reboot . . . .................................................................................................... 220
C Frequency Domains and Channels . . . 223
D SNR Information. . . 231
E Bootloader CLI and ScanTool. . . 235
Tsunami® 8100 Series - Software Management Guide 6
F Lightning Protection . . . .......................................................................................... 237
G Abbreviations . . . 238
H Statement of Warranty . . . ..................................................................................... 242
I Technical Services and Support. . . ....................................................................... 244
Tsunami® 8100 Series - Software Management Guide 7
Preface
Preface
This chapter contains information on the following:
About this Guide
Products Covered
Audience
Prerequisites
Related Documents
Documentation Conventions
About this Guide
This manual gives a jump-start working knowledge on the Tsunami® 8100 products. It explains the step-by-step procedure to
configure, manage and monitor these products by using Web Interface.
Products Covered
Tabulated below are the Tsunami® products that are covered in this guide along with the latest software version supported.
Product(s) Software Version Supported
Tsunami® MP-8100-BSU 2.4.0
Tsunami® MP-8100-SUA 2.4.0
Tsunami® MP-8150-SUR 2.4.0
Tsunami® MP-8150-CPE 2.4.0
Tsunami® MP-8160-BSU 2.4.0
Tsunami® MP-8160-SUA 2.4.0
Tsunami® MP-8160-CPE 2.4.0
Tsunami® QB-8100-EPA 2.4.0
Tsunami® QB-8100-LNK 2.4.0
Tsunami® QB-8150-EPR 2.4.0
Tsunami® QB-8150-LNK 2.4.0
Tsunami® QB-8150-LNK-12/50 2.4.0
Audience
The intended audience for this guide is the Network Administrator who installs and/or manages the device.
Prerequisites
The reader of this document should have working knowledge of Wireless Networks, Local Area Networking (LAN) concepts,
Network Access Infrastructures and Client-Server Applications.
Tsunami® 8100 Series - Software Management Guide 8
Preface
Related Documents
In addition to this guide, you can refer to the following documents that are available on the Proxim’s support site
http://support.proxim.com.
Quick Installation Guide (QIG) - A quick reference guide that provides essential information to install and configure
the device.
Hardware Installation Guide - A guide that provides an overview about the Tsunami® products, their installation
methods and hardware specifications.
Reference Guide - A guide that provides instructions on how to configure, manage and monitor the device by using
Command Line Interface.
Antenna Guides - A guide that gives insight on the recommended antennas and the ways to align them.
Safety and Regulatory Compliance Guide - A guide that provides country specific safety and regulatory norms to
be followed while installing the devices.
Documentation Conventions
Screenshots
This guide uses screenshots to explain the method to configure and manage the device using Web Interface. Based on your device,
the screenshots may vary. Hence, we request you to refer to the screenshots that are valid for your device.
Icon Representation
Name Image Meaning
Note A special instruction that draws attention of a user.
Important A note of significant importance that a user should be aware of.
Caution A warning that cautions a user of the possible danger.
Device Naming Conventions
Naming Convention Description
BSU Refers to a Base Station Unit
Subscriber / SU Mode / SU Refers to both SU and CPE
End Point A mode Refers to a device in End Point A mode
End Point B mode Refers to a device in End Point B mode
: A feature specific to a device is referred to by its name else by the common naming convention as tabulated above.
Tsunami® 8100 Series - Software Management Guide 9
1
Overview
This chapter contains information on the following:
About Tsunami® 8100 Products
Wireless Network Topology
- Point-to-Multipoint (PTMP)
- Point-to-Point Link
Multiple-Input-Multiple-Output (MIMO)
Wireless Outdoor Router Protocol (WORP)
1.1 About Tsunami® 8100 Products
Proxim’s Tsunami® 8100 product series, consists of point-to-point and point-to-multipoint devices that are designed to
provide wireless networking solutions to enterprises and business markets.
This product series consists of the following products:
Product Description Image
Tsunami® The Tsunami® MP-8100 Base Station unit, is a flexible wireless
MP-8100-BSU outdoor product that operates in 2.3 - 2.5 and 4.9 - 6.0 GHz
frequency bands. This connectorized device comes with a 3x3
MIMO radio and three N-Type connectors to connect external
antennas.
Tsunami® The Tsunami® MP-8100 Subscriber unit, is a flexible wireless
MP-8100-SUA outdoor product that operates in 2.3 - 2.5 and 4.9 - 6.0 GHz
frequency bands. This connectorized device comes with a 3x3
MIMO radio and three N-Type connectors to connect external
antennas.
Tsunami® The Tsunami® MP-8150 Subscriber unit comes with a 3x3 MIMO
MP-8150-SUR radio operating in 4.9 - 6.0 GHz frequency band.
This connectorized device comes with a 3x3 MIMO Radio and
three N-Type connectors to connect external antennas.
Tsunami® The Tsunami® MP-8150 Customer Premises Equipment comes with
MP-8150-CPE a high power 2x2 MIMO radio and 16 dBi integrated dual-polarized
panel antenna operating in 5.3 - 6.1 GHz frequency band.
Tsunami® The Tsunami® MP-8160 Base Station unit, is a flexible outdoor
MP-8160-BSU product that operates in 5.9 - 6.4 GHz frequency band. This
connectorized device comes with a high power 2x2 MIMO radio
and two N-Type connectors to connect external antennas.
Tsunami® The Tsunami® MP-8160 Subscriber unit, is a flexible outdoor
MP-8160-SUA product that operates in 5.9 - 6.4 GHz frequency band. This
connectorized device comes with a high power 2x2 MIMO radio
and two N-Type connectors to connect external antennas.
Tsunami® 8100 Series - Software Management Guide 10
Overview
Tsunami® The Tsunami® MP-8160 Customer Premises Equipment comes with
MP-8160-CPE a single high power 2x2 MIMO radio and 15 dBi integrated
dual-polarized panel antenna operating in 5.9 - 6.4 GHz frequency
band.
Tsunami® The Tsunami® QB-8100-EPA QuickBridge operates in 2.3 - 2.5 and
QB-8100-EPA 4.9 - 6.0 GHz frequency bands. This connectorized device comes
with a 3x3 MIMO radio and three N-Type connectors to connect
external antennas.
Tsunami® A pair of Tsunami® QB-8100-EPA devices form a link.
QB-8100-LNK
Tsunami® The Tsunami® QB-8150-EPR QuickBridge comes with a 2x2 MIMO
QB-8150-EPR radio and 23 dBi integrated dual-polarized panel antenna operating
in 4.9 - 6.0 GHz Band.
Tsunami® A pair of Tsunami® QB-8150-EPR devices form a link.
QB-8150-LNK
Tsunami® A pair of Tsunami® QB-8150-EPR-12 devices form a link.
QB-8150-LNK-12
The Tsunami® QB-8150-EPR-12 device comes with a high power
2x2 MIMO radio, 12 Mbps speed and 16 dBi integrated
dual-polarized panel antenna operating in 5.3 - 6.1 GHz frequency
band.
Tsunami® A pair of Tsunami® QB-8150-EPR-50 devices form a link.
QB-8150-LNK-50
The Tsunami® QB-8150-EPR-50 device comes with a high power 2x2
MIMO radio, 50 Mbps and 16 dBi integrated dual-polarized panel
antenna operating in 5.3 - 6.1 GHz frequency band.
1.2 Wireless Network Topology
1.2.1 Point-to-Multipoint (PTMP)
Point-to-multipoint is a wireless network that has a central communication device such as a Base Station Unit (BSU), providing
connectivity to multiple devices such as Subscribers (SUs) or clients. Any transmission of data that originates from the BSU is
received by all SUs; whereas, the data originating from any of the SU is received only by the BSU. This allows numerous sites in a
wide area to share resources, including a single high-speed connection to the Internet.
Tsunami® 8100 Series - Software Management Guide 11
Overview
Listed below are the applications, where Proxim’s Point-to-multipoint devices can be used:
Last Mile Access: Competitive broadband service access alternative to Digital Subscriber Line (DSL) or cable for
residences and T1 or Ethernet for businesses.
Security and Surveillance: High definition IP-surveillance cameras for monitoring city streets, airports, bridges,
seaports, transportation hubs, offices and warehouses.
Tsunami® 8100 Series - Software Management Guide 12
Overview
Metropolitan Area Network: Secure and reliable connectivity between city buildings.
Enterprise Campus Connectivity: Extend the main network to remote offices, warehouses or other buildings
without leased lines.
Tsunami® 8100 Series - Software Management Guide 13
Overview
Offshore Communications: Establishes connectivity between seashore and the ships that are nearing the port
locations, or connectivity between off-shore oil rigs and sea shore and so on.
Wireless Intelligent Transportation System (ITS): Increases the traffic efficiency and reduces the commuting time
in cities and metropolitan areas.
1.2.2 Point-to-Point Link
A point-to-point link is a dedicated wireless link that connects only two stations.
With a point-to-point link, you can set up a connection between two locations as an alternative to:
Leased lines in building-to-building connections
Wired Ethernet backbones between wireless access points in difficult-to-wire environments.
It is easy to set up a wireless point-to-point link as shown in the following figure. Each device is set up as either an End Point
A or an End Point B.
Tsunami® 8100 Series - Software Management Guide 14
Overview
Figure 1-1 Point-to-Point-Link
Listed below are the applications, where Proxim’s Point-to-Point devices can be used:
Backhaul to a Central POP: Avoids expensive installation and recurring charge of a second wireline backhaul to a
remote virtual POP.
Tsunami® 8100 Series - Software Management Guide 15
Overview
Repeater: Extends distance or overcomes path blockage by adding point-to-point hops
High-bandwidth Last Mile Access: Delivers Transparent LAN Services (TLS) to corporate parks.
High Availability and Link Aggregation: Achieves high availability and link aggregation in wireless medium by
using two parallel links and additional Link Aggregation Control Protocol (LACP) capable switches. This is applicable
only for QB-8100-EPA/LNK and QB-8150-EPR/LNK devices.
Tsunami® 8100 Series - Software Management Guide 16
Overview
Leased Line Redundancy: Eliminates recurring DS-3 leased line charges with one time installation charge of a
QuickBridge link.
Inter-POP Redundancy: Avoids downtimes caused by a wireline backhaul failure by adding a QuickBridge link as an
inter-POP redundancy.
1.3 Multiple-Input-Multiple-Output (MIMO)
Proxim’s
81xx Point-to-point and Point-to-multipoint devices support Multiple-Input-Multiple-Output
(MIMO) antenna
technology that uses multiple antennas at both the transmitter and receiver to improve communication performance. The
underlying technology of Proxim’s product radio(s) are based on a combination of MIMO and OFDM (Orthogonal Frequency
Division Multiplexing). MIMO-OFDM combination radios solve interference, fading and multipath problems On the receiver
side, having multiple receivers increases the amount of received power and also reduces multipath problems by combining
the received signals for each frequency component separately. Hence, MIMO significantly improves the overall gain.
MIMO also uses Spatial multiplexing transmission technique to transmit independent and separately encoded data signals from
each of the multiple transmit antennas while reusing or multiplexing in the space dimension. These independent data signals are
called Spatial streams. The transmitting antenna uses multiple radio Tx chains and signal paths to simultaneously transmit different
data streams, whereas the receiver combines the Rx signals resulting in higher throughput.
By increasing the number of receiving and transmitting antennas, the throughput of the channel increases linearly resulting in high
spectral efficiency.
1.4 Wireless Outdoor Router Protocol (WORP)
WORP is a protocol, designed by Proxim to optimize the performance of multi-play outdoor wireless Point-to-Point (PtP) and
Point-to-Multipoint (PTMP) links using packet radio technology, including the use of cutting edge
Multiple-Input-Multiple-Output (MIMO) technology.
WORP overcomes the performance degradation, which standards-based wireless technologies are susceptible to when used for
outdoor long-range connectivity.
Benefits:
More Net Bandwidth: WORP increases the overall net bandwidth of the multipoint system. The net bandwidth using
WORP is higher than any other protocol solution used in an outdoor environment. WORP is a more efficient protocol
that protects the system from packet collisions and transmits the data in an optimal way, which increases the overall
performance.
More Concurrent Subscribers: An outdoor point-to-multipoint solution based on 802.11 may connect from 5 to 10
remote nodes, but sometimes performance starts to suffer from collisions with as little as only 2 remote nodes. A
solution using WORP, on the other hand, can connect up to 100 remote nodes without adverse effects on usable
bandwidth, allowing more concurrent Subscriber Units (SU) to be active in a wireless multipoint environment.
Smart Scheduling: WORP uses smart scheduling for remote node polling to avoid wasting bandwidth on nodes that
have no traffic to be sent. The Base Station Unit (BSU) dynamically decides how frequently a remote node should be
polled based on the current traffic to and from each remote node and the priority settings for that traffic. The
scheduling is adapted dynamically to the actual traffic and further optimized by following the bandwidth limits as
configured for each remote node.
Dynamic Data Rate Selection (DDRS): DDRS enables WORP to dynamically adjust the data rate at which the
wireless traffic is sent. This feature is especially important in point-to-multipoint networks, when different SUs can
sustain different data rates because of the different distances from the BSU. With DDRS, WORP dynamically optimizes
the wireless data rate to each of the SUs independently, keeping the overall net throughput at the highest possible
level. This feature optimizes throughput even for links with different RF conditions on the BSU and SU, by optimizing
downlink
Tsunami® 8100 Series - Software Management Guide 17
Overview
Quality of Service: WORP ensures that the most important data arrives with priority by differentiating between
priorities of traffic as defined in the profiles for QoS (Quality of Service), similar to the 802.16 WiMAX QoS standard
definition.
Bandwidth Control: WORP allows service providers to control network bandwidth, protecting the network from
excessive bandwidth use by any one station. Additionally, it allows service providers to differentiate their service
offerings.
Asymmetric Bandwidth Controls
: Asymmetric bandwidth gives network managers the ability to set different
maximum bandwidth rates for a variety of customer groups. This allows service providers to further differentiate their
service offerings and maximize revenues.
Tsunami® 8100 Series - Software Management Guide 18
2
Management and Monitoring Capabilities
A Network administrator can use the following interfaces to configure, manage and monitor the devices.
Web Interface
Command Line Interface
Simple Network Management Protocol (SNMP)
ProximVision ES (PVES)
2.1 Web (HTTP/HTTPS) Interface
The Web interface (HTTP) provides easy access to configuration settings and network statistics from any computer on the
network. You can access the Web interface, through LAN (switch, hub and so on), the Internet, or with an Ethernet cable
connected directly to your computer’s Ethernet port.
HTTPS interface provides an HTTP connection over a Secure Socket Layer (SSL). HTTPS allows the user to access the device in
a
secure fashion using SSL over port 443. The device supports SSLv3 with a 128-bit encryption certificate maintained by the device
for secure communication between the device and the HTTP client. All communications are encrypted using the server and the
client-side certificate.
2.2 Command Line Interface
The Command Line Interface (CLI) is a text-based configuration utility that supports a set of keyboard commands and
parameters to configure, manage and monitor the device. You can enter the command statements composed of CLI
commands and their associated parameters. Commands can be issued from the keyboard for real-time control, or from scripts
that automate configuration. For example, when downloading a file, an administrator enters the download CLI Command
along with the IP Address, file name, and file type parameters.
2.2.1 HyperTerminal
You can access the CLI over a HyperTerminal serial connection. HyperTerminal is a program that connects to other
Computers, Telnet Sites, Bulletin Board Systems (BBS), Online Services, and Host Computers, by using either modem or a null
modem cable.
If you are using RS-232 cable, verify the following information in the HyperTerminal serial port setup:
Port COM1 (default)
Baud Rate 115200
Data 8-bit
Parity None
Stop 1-bit
Flow Content None
: If you are using Windows 7 then use Terminal Emulator program like Teraterm Pro for serial connection.
Tsunami® 8100 Series - Software Management Guide 19
Management and Monitoring Capabilities
2.2.2 Telnet
You can access the device through CLI by using Telnet. With Telnet, you can communicate with the device through LAN
(switch, hub and so on), the Internet, or with an Ethernet cable connected directly to your computer’s Ethernet port.
2.2.3 Secure Shell (SSH)
You can securely access the device through CLI by using Secure Shell (SSH). The device supports SSH version 2, for secure
remote CLI (Telnet) sessions. SSH provides strong authentication and encryption of session data. The SSH server has host keys
- a pair of asymmetric keys (a private key that resides on the device) and a public key that is distributed to clients that need to connect
to the device. Clients need to verify that it is communicating with the correct SSH server.
2.3 SNMP Management
You can also configure, manage and monitor the device by using the Simple Network Management Protocol (SNMP). This
requires an SNMP Manager Program (sometimes called MIB browser) or a Network Manager program using SNMP. The device
supports the following Management Information Base (MIB) files that describe the parameters that can be viewed and/or
configured over SNMP:
PXM-SNMP.mib (Enterprise MIB)
• RFC-1213.mib (MIB-II)
• RFC-1215.mib (Trap MIB)
RFC-1757-RMON.mib (Remote Monitoring)
• RFC-2571.mib (SNMP Framework)
RFC-3411-SNMP-FRAME-WORK.mib (SNMP Framework)
• RFC-2790.mib (Host Resources)
• RFC-3291-INET-ADDRESS-MIB.mib
• RFC-3412.mib (SNMP-MPD-MIB)
• RFC-3414.mib (SNMP-USER-BASED-SM-MIB)
• SFLOW.mib
The PXM MIB files are available on the Proxim support site (http://support.proxim.com). You must compile one or more of these
MIB files into your SNMP program’s database before you manage your device using SNMP.
The enterprise MIB (PXM-SNMP.mib) defines the Read and Read/Write objects that can be viewed or configured using SNMP.
These objects correspond to most of the settings and statistics that are available with other management interfaces. The MIB can
be opened with any text editor, such as Microsoft Word, Notepad, or WordPad.
2.4 ProximVision ES
ProximVision ES (commonly known as PVES) is Proxim’s Network Management System that helps to manage and administer your
wireless network effectively and efficiently. ProximVision ES combines industry-leading functionality with an intuitive user interface,
enabling Network Administrators and Help Desk staff to support and control a wireless network.
ProximVision ES offers you a single intelligent console from which you can manage, monitor, analyze and even configure your
device. For more information, see ProximVision ES user guide available at the Proxim’s support site at
http://support.proxim.com.
: This user guide explains the method to initialize and manage the device using Web Interface only. The
Reference Manual, a guide that explains the method to manage the device using Command Line
Interface, can be found at Proxim’s support site (http://support.proxim.com).
Tsunami® 8100 Series - Software Management Guide 20
3
Device Initialization
This chapter contains information on the following:
Initialization
ScanTool
Initialize Device using ScanTool
Modifying the IP Address of the Device using ScanTool
Logging onto the Web Interface
Home Page
COMMIT
REBOOT
Factory Default Configuration
3.1 Initialization
Once the device installation completes, you can access the device either through Command Line Interface, Web Interface or an
SNMP Interface.
: For installation procedure, please refer to the
Hardware Installation guide
available at Proxim’s support site
(http://support.proxim.com).
To access the device using CLI commands, connect a serial RS-232 cable to the Serial port of the device.
To access the device using Web or SNMP interface, connect an Ethernet cable to the Ethernet port of the device.
For all the modes of connection, you will need to configure the IP address of the device. As each network is different, a suitable
IP address on the network must be assigned to the device. This IP address helps you to configure, manage and monitor the
device through the Web Interface, SNMP, or Telnet/CLI. The device can have either a static or dynamic IP address. When set
to static, the user has to set the IP address manually; and if set to dynamic, the IP address is obtained dynamically from the
Dynamic Host Configuration Protocol (DHCP) server.
By default, the device IP Address is set to 169.254.128.132.
: Tsunami® MP-8160-CPE device does not have a Serial Port. However, the user has the flexibility to configure, manage and
monitor the device through command mode via Telnet.
3.1.1 ScanTool
Proxim’s ScanTool (Answer ID - 1735) is a software utility that runs on Microsoft Windows machine. By
using ScanTool, you can
Scan devices (Proxim devices only) available on the network
Obtain device’s IP address
Modify device’s IP Configuration parameters (IP Address, Address Type, Gateway and so on)
Launch the Web interface
Switch between the network adapters, if there are multiple network adapters in the Personal Computer
Tsunami® 8100 Series - Software Management Guide 21
Device Initialization
: ScanTool works only for Proxim devices. Also note that you may need to disable Windows Firewall (or add an
exception) for ScanTool to function or to detect the radio.
3.1.2 Initialize Device using ScanTool
To scan and locate the devices on a network by using ScanTool, do the following:
1. Power on, or reset the device.
2. To download Proxim’s ScanTool, log on to Proxim’s support site at http://support.proxim.com and search for ScanTool
with (Answer ID 1735). Upon successful download, start ScanTool by double-clicking the downloaded icon.
3. If your computer has more than one network adapter installed, you will be prompted to select the adapter for
scanning Proxim devices. You can use either an Ethernet or a Wireless Adapter. Select an adapter and click OK. The
following ScanList screen appears, which displays all devices that are connected to selected adapter.
Figure 3-1 ScanList - An Example
This screen contains the following device information:
MAC Address
System Name
IP Address
Uptime
System Description: The system description comprises the following information:
Device Description: For example, Tsunami MP-8100-BSU-WD
Firmware Version: For example, v2.4.0
Serial Number : For example, SN-11PI15010031
Bootloader Version: For example, BL - V1.3.1
4. Click Select Adapter, to change adapter settings.
5. Identify and select the MAC address of the device you want to initialize from the list and click Web Config to log on
to the Web Interface.
: If your device does not appear in the Scan List, click Rescan in the Scan List screen. If the device still does not appear in the
list, see Troubleshooting for suggestions. Note that after rebooting the device, it may take up to five minutes for the device
to appear in the Scan List.
Tsunami® 8100 Series - Software Management Guide 22
Device Initialization
3.1.3 Modifying the IP Address of the Device using ScanTool
To modify the IP address of a device using ScanTool, select the device from the scan list and click Change. A Change screen
appears as shown in the following figure. The system automatically populates the MAC Address, System Name, TFTP
Server IP Address and Image File Name of the device, which are read-only.
Figure 3-2 Modifying Device’s IP Address
1. Select the IP Address Type as either static or dynamic.
Static: When set to static, the IP address of the device is changed manually.
Dynamic: When set to dynamic, the IP address is dynamically generated by the DHCP server.
2. Type the appropriate IP Address, Subnet Mask, and the Gateway IP Address parameters.
3. Enter the SNMP Read/Write password in the Read/Write Password box. By default, it is public.
4. Click OK to save the details. The device automatically reboots.
To log on to the Web Interface, click Web Configuration.
The user is then prompted to enter its username and password. For more information on how to login, please see Logging onto
the Web Interface.
3.2 Logging onto the Web Interface
Once the device is connected to your network, use a web browser to configure, manage and monitor the device. Enter the default
IP address of the device (For example, http://169.254.128.132) in the address bar or access the Web Interface using ScanTool (see
Initialization).
You are now prompted to enter your username and password.
Tsunami® 8100 Series - Software Management Guide 23
Device Initialization
Figure 3-3 Login Screen
Based on the access credentials, two types of users can access the device. They are,
1. Administrator User: The Administrator user administers the entire device. This user type has the write access to all
the features of the device and also has the privilege to change his or her own password and that of the Monitor user
(the other user type). To change the password, refer to Services.
2. Monitor User - The Monitor user has only view access to all the features of the device. This user is restricted from the
following privileges:
Change the device functionality
Change his or her own password
Run any of the test tools like Link Test, Wireless Site Survey and so on. However, the user can view the logs and
statistics of the test tools.
The Monitor user is given the privilege to retrieve event logs and temperature logs for debugging.
To logon to the device,
1. Type a valid user name in the User Name box. The user name is admin for the Administrator user and monitor for
the Monitor user.
2. Type the password in the Password box. By default, the password is public for both the Administrator user and the
Monitor user.
:
By default the password is public. For security reasons, it is recommended to change the password after your first
logon to the device.
Depending on the settings made during the device initialization, the IP address may be either a dynamic IP address
assigned by a network DHCP server or a static IP address which is manually configured. Refer to ScanTool for
information on how to determine the device’s IP address and manually configure a new IP address.
If the connection is slow or unable to connect, use the Internet Explorer Tools option to ensure that you are not
using a proxy server for the connection.
If you are unable to log on to the configuration pages by using default user name and password, please check
with the administrator or follow Forced Reload procedures.
If using Internet Explorer, and you enter wrong password consecutively for three times, the HTTP session will get
disconnected. If case of other browsers, the login screen will reset until you enter correct password.
In the Internet Explorer, to get best results, click on Tools > Internet Options > General. Click Settings in the
Browsing History and select Every visit to the webpage”.
Tsunami® 8100 Series - Software Management Guide 24
Device Initialization
3.2.1 Home Page
Upon successful logon, the device home page appears.
Figure 3-4 Home Page
The home page contains the following information:
Device Description: The device description is displayed on the top-right corner of the home page. It displays the
logged in user type and the device name along with the latest firmware version.
System Summary: The System Summary screen displays the summary of system information such as System Name, IP
Address, Radio Mode, Interface Status, Event Log and so on.
COMMIT Button: See COMMIT
REBOOT Button: See REBOOT
Home: Display System Summary screen.
BASIC CONFIGURATION: The BASIC CONFIGURATION tab allows the user to configure the minimum set of
parameters required for a device to be operational and establish link in the network. For more details, see Basic
Configuration.
ADVANCED CONFIGURATION: The ADVANCED CONFIGURATION tab allows the user to configure the advanced
parameters of the device. For more details, see Advanced Configuration.
MANAGEMENT Tab: The MANAGEMENT tab allows the user to manage the device. For more details, see
Management.
MONITOR Tab: The MONITOR tab allows the user to monitor the device. For more details, see Monitor.
Tsunami® 8100 Series - Software Management Guide 25
Device Initialization
3.2.2 COMMIT
COMMIT
operation is used to apply the configuration changes onto the device. When changes are made to the
configuration parameters of the device, the changes will not take effect, until COMMIT is clicked. Some parameters may
require system reboot for the changes to take effect. On clicking
COMMIT
, the system evaluates all the configuration
dependencies and displays the configuration status.
Before applying commit, the system displays a confirmation message, as shown in the following figure:
Figure 3-5 Commit
Click OK, if you wish to commit the changed parameters.
On successful COMMIT operation, the following screen appears:
Figure 3-6 Commit Status
If the configured parameters requires reboot, on committing the following screen appears.
Figure 3-7 Commit Status with Reboot Message
Tsunami® 8100 Series - Software Management Guide 26
Device Initialization
3.2.3 REBOOT
Reboot operation is required for any change in the key parameters to take effect. For example, settings such as configuring the
Radio Mode, IP Address, and Network Mode need reboot to take effect.
It is recommended that the device must be rebooted immediately after modifying a rebootable parameter. On clicking Reboot,
system displays a confirmation window, as shown below.
Figure 3-8 Reboot
: It is always mandatory to commit the changes before REBOOT, otherwise the changes will not take effect. To
reboot the device, click OK.
3.3 Factory Default Configuration
Parameter BSU Mode/ SU Mode/
End Point A End Point B
User Password Public Public
System Name System-Name System-Name
Network Mode Bridge Bridge
Routing Disabled Disabled
IP Address 169.254.128.132 169.254.128.132
Subnet Mask 255.255.255.0 255.255.255.0
Address Type Static Static
Gateway IP Address 169.254.128.132 169.254.128.132
Network Name MY_NETWORK MY_NETWORK
Maximum Number of SUs (per BSU) As per license Not Applicable
Registration Timeout 10 Seconds 10 Seconds
DDRS Enabled Enabled
Input Bandwidth Limit As per license As per license
Output Band Limit As per license As per license
Security Profile Enabled with profile name Enabled with profile name
“WORP Security” “WORP Security”
Tsunami® 8100 Series - Software Management Guide 27
Device Initialization
Parameter BSU Mode/ SU Mode/
End Point A End Point B
RADIUS Profile Enabled with profile name Not Applicable
“Default Radius”
MAC Authentication Disabled Not Applicable
RADIUS MAC Authentication Disabled Not Applicable
Channel Bandwidth 20 MHz 20 MHz
Active Channel Selection Disabled Enabled
ATPC Enabled Enabled
Network Secret Public Public
QoS Unlimited BE Not Applicable
Management VLAN Disabled Disabled
VLAN Status Disabled Disabled
VLAN Mode (Ethernet) Transparent Transparent
Global Filtering Disabled Disabled
DHCP Server Disabled Disabled
STP/LACP Enabled (configured as Enabled (configured as
“passthru”) “passthru”)
DHCP Relay Disabled Disabled
IGMP Snooping Disabled Disabled
RIP Disabled Disabled
NAT Disabled Disabled
PPPoE Client Not Applicable Disabled in SU Mode
Not Applicable in End Point B
HTTP Management Interface Enabled Enabled
Telnet Management Interface Enabled Enabled
SNMP Management Interface Enabled with SNMPv1-v2c Enabled with SNMPv1-v2c
Simple Network Time Protocol (SNTP) Disabled Disabled
Management Access Control Disabled Disabled
Event Log Priority Notice Notice
SysLog Status Enabled Enabled
SysLog Priority Critical Critical
Tsunami® 8100 Series - Software Management Guide 28
4
Basic Configuration
The BASIC CONFIGURATION tab provides a one-place access to a minimum set of configuration parameters to quickly set up a
Point-to-point or Point-to-multipoint network.
To configure basic parameters of the device, click BASIC CONFIGURATION tab. The following screen appears:
Figure 4-1 Basic Configuration (BSU)
Tsunami® 8100 Series - Software Management Guide 29
Basic Configuration
Figure 4-2 Basic Configuration (SU)
Tsunami® 8100 Series - Software Management Guide 30
Basic Configuration
Figure 4-3 Basic Configuration (End Point B)
Tabulated below is the table which explains Basic parameters and the method to configure the configurable parameter(s):
Parameter Description
System Name Represents the system name of the device. By default, the system name is System-Name.
You can change the system name to the desired one. Please note that the length of the
name is limited to 64 characters.
Tsunami® 8100 Series - Software Management Guide 31
Basic Configuration
Parameter Description
Frequency Domain This parameter specifies the country of operation, permitted frequency bands and
regulatory rules for that particular country or domain. When you choose a frequency
domain, the Dynamic Frequency Selection (DFS) and Automatic Transmit Power Control
(ATPC) features are enabled automatically if the selected country and band has a
regulatory domain that requires it. The Frequency domain selection pre-selects and
displays only the allowed frequencies for the selected country or domain.
:
Devices sold only in United States are pre-configured to scan and display only the
outdoor frequencies permitted by the Federal Communications Commission
(FCC). No other countries, channels, or frequencies can be configured. Devices
sold outside United States support the selection of a country by the professional
installer. Any change in the Frequency Domain, requires device reboot.
If World 5 GHz is selected from the Frequency Domain drop-down menu,
channels only in the 5 GHz range are displayed for manual selection.
For a non US device, the default Frequency Domain selected is World 5GHz. For more
details on frequency domains, refer to Frequency Domains and Channels.
Radio Mode Represents the radio mode of the device. Based on the SKU, the radio mode is set to either
BSU, SU, End Point A or End Point B.
In case of a BSU device, you can toggle between BSU and SU modes. Similarly in case of
End Point A device, you can toggle between End Point A and End Point B. But note that a
change in radio mode will reset wireless and WORP parameters of the device after reboot.
Channel Bandwidth Represents the width of the frequency band that is used to transmit data on the wireless
interface. By default, it is set to 20 MHz. 40 MHz can be selected for higher throughputs
depending on the distance and signal quality. 5 and 10 MHz can be selected for greater
flexibility in spectrum selection.
Auto Channel Enables a device to select the best channel for data transmission on the wireless medium,
Selection (ACS) with less interference. By default, ACS is disabled on a BSU/End Point A and enabled on a
SU/End Point B device. When ACS is enabled on a BSU/End Point A, it scans all the
channels and selects the best channel during the start up. If ACS is enabled on the SU/End
Point B, it continuously scans all the channels till it connects to a BSU or End Point A
respectively.
: Irrespective of the ACS status, the BSU/Endpoint A will automatically select a new
channel upon radar detection.
Preferred Channel Applicable only when the Auto Channel Selection (ACS) is disabled. This parameter
enables you to select a specific channel (in the specified frequency domain) for the device
to operate.
Active Channel Displays the current active channel on which wireless interface is operating. When the
Auto Channel Selection parameter is enabled or when the device moves to a different
channel because of radar detection, this parameter enables you to view the current
operating channel.
Tsunami® 8100 Series - Software Management Guide 32
Basic Configuration
Parameter Description
DDRS Status Applicable only when Dynamic Data Rate Selection (DDRS) is enabled on the device. It
indicates that DDRS is enabled on the device. See DDRS.
Tx Rate Applicable only when Dynamic Data Rate Selection (DDRS) is disabled on the device. This
parameter represents the data transmission rate of the device. You can configure the
appropriate data rate based on the signal level.
: A change in Channel Bandwidth will reset the Tx Rate to default value.
Network Name Network name to identify a wireless network. The network name can be of minimum 2 or
maximum 32 characters. The default network name is MY_NETWORK.
: For a BSU and SU to establish a wireless link, both should in the same network. The
same applies to End Point A and End Point B as well.
Legacy Mode Applicable only to Tsunami® MP-8100-BSU device.
When enabled, allows the device to operate with the legacy products of the Tsunami® MP.11
family such as: MP.11 5054 series, 5012 series, 2454 series and so on. By default, this
parameter is disabled.
BSU / End Point A Applicable only to a SU/End Point B device.
Name
Represents the BSU/End Point A name to which SU/End Point B is connected.
IP Configuration, and See Network.
Default Gateway IP
Address
After configuring the required parameters, click OK and then COMMIT.
: Reboot the device, if you have configured any of the parameters with an asterisk symbol marked against them.
Tsunami® 8100 Series - Software Management Guide 33
5
Advanced Configuration
The ADVANCED CONFIGURATION tab provides a means to configure the following advanced features of the device:
System
Network
Ethernet
Wireless
Security
Quality of Service (QoS)
RADIUS Based SU QoS Configuration
VLAN (Bridge Mode Only)
RADIUS Based SU VLAN Configuration
Filtering (Bridge Only)
DHCP
IGMP Snooping
Routing Mode Features
5.1 System
The System tab enables you to configure system specific information.
To configure system specific parameters, navigate to ADVANCED CONFIGURATION > System. The System screen appears:
Figure 5-1 System Configuration
Tabulated below is the table which explains System parameters and the method to configure the configurable parameter(s):
Parameter Description
Radio Mode Represents the radio mode of the device. Based on the device, the radio mode is set to
either BSU, SU, End Point A or End Point B. In case of a BSU device, you can toggle
between BSU and SU modes. Similarly in case of End Point A or End Point B device, you can
toggle between End Point A and End Point B. But note that a change in radio mode will reset
wireless and WORP parameters of the device after reboot.
Tsunami® 8100 Series - Software Management Guide 34
Advanced Configuration
Parameter Description
Frequency Domain A valid frequency domain must be set before the device can be configured with any other
parameters. Selecting a frequency domain makes the device compliant with the allowed
frequency bands and channels for that regulatory domain. See Frequency Domain.
Network Mode The device can be configured in two network modes: Bridge and Routing. By default, the
network mode is Bridge mode.
Active Network Mode A change in the network mode (either Bridge or Routing mode) is applied on the device
only when the device is rebooted.
So, when the network mode is changed and the device is not rebooted, this parameter
displays the current operating network mode of the device.
Maximum MTU Largest size of the data packet that can be sent to/from the Ethernet interface of the
(Maximum device. By default, the MTU size is 1500 bytes. It can be configured with any value ranging
Transmission Unit) from 1500 to 2048 bytes. The MTU size excludes Ethernet Header(14 bytes) + Frame
Check Sequence (4 bytes) + VLAN Tag(4 bytes).
:
Not all devices support this parameter.
MTU is configurable only in Tsunami® MP-8150-CPE, Tsunami® MP-8160-CPE
and Tsunami® QB-8150-EPR-12/50 devices.
For optimal performance, MTU should be configured same on both local and
remote devices.
By default, Maximum MTU for Tsunami® MP-8100-BSU, Tsunami®
MP-8100-SUA, MP-8150-SUR, Tsunami® MP-8160-BSU, Tsunami®
MP-8160-SUA, Tsunami® QB-8100-EPA, Tsunami® QB-8150-EPR is not
configurable and set to 1500 excluding Ethernet Header(14 bytes) + Frame
Check Sequence (4 bytes) + VLAN Tag(4 bytes).
Frequency Filter Lower These parameters enable you to define the lower and upper frequency band edges, which
Edge, and helps to limit the available frequency band, for a given frequency domain, to a smaller
Frequency Filter Upper band. By limiting the frequency band, the time taken by a device to scan and connect to
Edge any other device in the network is reduced.
You can enter frequencies ranging from 0 to 10000 MHz. By default the lower frequency is
set to 0 MHz and higher frequency is set to 10000 MHz.
After configuring the required parameters, click OK, COMMIT and then REBOOT.
5.2 Network
The Network tab allows you to view and configure the network specific information of the device.
To view the current operating network mode of the device, navigate to ADVANCED CONFIGURATION > Network. If the
network mode of the device is configured in Bridge mode, then following screen appears:
Tsunami® 8100 Series - Software Management Guide 35
Advanced Configuration
Figure 5-2 Bridge Mode
If the network mode of the device is configured in Routing mode, then the following screen appears:
Figure 5-3 Routing Mode
5.2.1 IP Configuration (Bridge Mode)
To configure the IP parameters of the device when operating in Bridge mode, navigate to ADVANCED CONFIGURATION >
Network > IP Configuration. The following IP Configuration screen appears:
Figure 5-4 IP Configuration (Bridge Mode)
Tabulated below is the table which explains the method to configure IP parameters in Bridge mode:
Parameter Description
Ethernet
Please note that the number of Ethernet interfaces depend on your device.
Tsunami® 8100 Series - Software Management Guide 36
Advanced Configuration
Parameter Description
Address Type Specifies whether the Ethernet interface parameters are to be configured through
Dynamic Host Configuration Protocol (DHCP) or to be assigned statically.
By default, the address type is set to Static meaning which the user can manually
configure the network parameters. Select Dynamic to configure the device as a DHCP
client. If Dynamic is selected, the device obtains the IP parameters from a network DHCP
server automatically during the bootup. If you do not have a DHCP server or if you want to
manually configure the device’s IP settings, select Static.
: DHCP Client (IP Address Type Dynamic) is applicable in Bridge Mode, and is
applicable on wireless interface in Routing mode only when PPPoE is enabled .
IP Address Represents the IP address of the Ethernet interface.
When the address type is set to Static (default address type), the static IP address by
default is set to 169.254.128.132. When set to static, you can manually change the IP
address.
When the address type is set to Dynamic, this parameter is read-only and displays the
device IP address obtained from the DHCP server. The device will fallback to
169.254.128.132, if it cannot obtain the IP address from the DHCP server.
Subnet Mask Represents the subnet mask of the Ethernet interface.
When the address type is set to Static (default address type), the subnet mask by default is set to
255.255.255.0. When set to static, you can manually change the subnet mask.
When the address type is set to Dynamic, this parameter is read-only and displays the
device current subnet mask obtained from the DHCP server. The subnet mask will fallback
to 255.255.255.0, if the device cannot obtain the subnet mask from the DHCP server.
Default Gateway IP Address
IP Address Represents the gateway IP address of the device.
When the address type is set to Static (default address type), the gateway IP address by
default is set to 169.254.128.132. When set to static, you can manually change the
gateway IP address.
When the address type is set to Dynamic, this parameter is read-only and displays the
device’s current gateway IP address that is obtained from the DHCP server. The gateway IP
address will fallback to 169.254.128.132, if it cannot obtain the gateway IP address from a
DHCP server.
DNS
Primary IP Address Represents the IP address of the Primary DNS Server.
When the address type is set to Dynamic, this parameter is read-only and displays the
DNS Primary IP Address obtained from the DHCP server. If the address type is set to Static,
then you will have to manually enter the primary IP Address.
Tsunami® 8100 Series - Software Management Guide 37
Advanced Configuration
Parameter Description
Secondary IP Address Represents the IP address of the Secondary DNS Server.
When the address type is set to Dynamic, this parameter is read-only and displays the
DNS Secondary IP Address obtained from the DHCP server. If the address type is set to
Static then you will have to manually enter the secondary IP Address.
After configuring the required parameters, click OK, COMMIT and then REBOOT.
5.2.2 IP Configuration (Routing Mode)
To configure the IP parameters of the device when operating in Routing mode, navigate to ADVANCED CONFIGURATION >
Network. The IP Configuration screen appears:
Figure 5-5 IP Configuration (Routing Mode)
Tabulated below is the table which explains the method to configure IP parameters in Routing mode:
Parameter Description
Ethernet
Please note that the number of Ethernet interfaces depend on your device.
Tsunami® 8100 Series - Software Management Guide 38
Advanced Configuration
Parameter Description
IP Address Represents the IP address of the Ethernet interface.
By default, the static IP address for Ethernet1 is set to 169.254.128.132 and for Ethernet2 it is
set to 169.254.129.132.
You can manually change the IP address.
Subnet Mask Represents the subnet mask of the Ethernet interface.
By default, the static subnet mask is set to 255.255.255.0. You can manually change the
subnet mask.
Wireless
IP Address Represents the IP address of the wireless interface.
By default, the static IP address is set to 169.254.130.132. You can manually change the IP
address.
Subnet Mask Represents the subnet mask of the wireless interface.
By default, the static subnet mask is set to 255.255.255.0. You can manually change the
subnet mask.
Default Gateway IP Address
IP Address Represents the gateway IP address of the device.
By default, the Gateway IP address is set to 169.254.128.132. You can manually change
the gateway IP address.
DNS
Primary IP Address Represents the IP Address of the Primary DNS Server.
Secondary IP Address Represents the IP Address of the Secondary DNS Server.
After configuring the required parameters, click OK, COMMIT and then REBOOT.
:
• To obtain dynamic IP address of the SU over WORP,
Scenario 1: When BSU and SU are in Bridge Mode with DHCP Client enabled in SU, and if DHCP server is
behind BSU, SU will get the IP Address over WORP.
Scenario 2: When BSU is in Routing Mode and SU is in Bridge mode and DHCP server is in a different network than
SU, then we need to configure DHCP relay in BSU to get the IP for SU over WORP.
Scenario 3: When BSU is in Routing mode and SU in Bridge mode with DHCP server running on wireless
interface of BSU, then SU will get the IP address from BSU.
Tsunami® 8100 Series - Software Management Guide 39
Advanced Configuration
5.2.3 IP Configuration (Routing Mode with PPPoE Client Enabled)
: IP Configuration in Routing mode with PPPoE client enabled is applicable only in SU mode. See PPPoE End Point
(SU Only)
To configure the IP parameters of the device when configured in Routing mode with PPPoE client enabled, navigate to
ADVANCED CONFIGURATION > Network. The IP Configuration screen appears:
Figure 5-6 IP Configuration (Routing Mode with PPPoE Client Enabled)
Tabulated below is the table which explains the method to configure IP parameters in Routing mode with PPPoE client
enabled:
Parameter Description
Ethernet
Please note that the number of Ethernet interfaces depend on your device.
IP Address Represents the IP address of the Ethernet interface.
By default, the static IP address for Ethernet1 is set to 169.254.128.132 and
169.254.129.132 for Ethernet2. You can manually change the IP address.
Subnet Mask Represents the subnet mask of the Ethernet interface.
By default, the static subnet mask is set to 255.255.255.0. You can manually change the
subnet mask.
Tsunami® 8100 Series - Software Management Guide 40
Advanced Configuration
Parameter Description
Wireless (PPPoE)
Address Type This parameter specifies whether the wireless interface parameters are to be configured
through PPPoE server or to be assigned statically.
By default, the address type is set to PPPoE-ipcp meaning which the PPPoE client obtains the
IP parameters from a network PPPoE server automatically during the bootup. To
manually configure the PPPoE Client’s IP settings, select Static.
IP Address Represents the IP address of the wireless interface.
When the address type is set to PPPoE-ipcp, this parameter is read-only and displays the
PPPoE client’s IP address obtained from the PPPoE server. The client will fallback to
169.254.130.132, if it cannot obtain the IP address from the PPPoE server.
When the address type is set to Static, the IP address by default is set to
169.254.130.132. You can manually change the IP address.
Subnet Mask Represents the subnet mask of the wireless interface.
When the address type is set to PPPoE-ipcp, this parameter is read-only and is set to Host Mask
as it is a point-to-point interface. The client will fallback to 255.255.255.0, if it
cannot obtain the IP address from the PPPoE server.
When the address type is set to Static, the subnet mask by default is set to
255.255.255.0. You can manually change the subnet mask.
Default Gateway IP Address
IP Address Represents the gateway IP address of the device.
When the address type is set to PPPoE-ipcp, this parameter is read-only and displays the
PPPoE client’s gateway IP address (which is nothing but the IP address of the PPPoE server).
If it cannot obtain the IP address from a PPPoE server, then there will be no gateway for
the device.
When the address type is set to Static, the gateway IP address by default is set to
169.254.128.132. You can manually change the gateway IP address.
DNS
Primary IP Address Represents the IP Address of the Primary DNS Server.
Secondary IP Address Represents the IP Address of the Secondary DNS Server.
After configuring the required parameters, click OK, COMMIT and then REBOOT.
Tsunami® 8100 Series - Software Management Guide 41
Advanced Configuration
5.3 Ethernet
The Ethernet tab allows you to view and configure the Ethernet interface properties of the device.
5.3.1 Basic Ethernet Configuration
To view and perform basic Ethernet configuration, navigate to ADVANCED CONFIGURATION > Ethernet. The Ethernet
Interface Properties screen appears:
Figure 5-7 Basic Ethernet Configuration
Tabulated below is the table which explains Basic Ethernet parameters and the method to configure the configurable
parameter(s):
Parameter Description
MAC Address Displays the MAC address of the Ethernet interface.
Operational Speed Displays the current operational speed of the Ethernet interface.
Tabulated below is the maximum operational speed of the Ethernet interface product
wise:
Product Maximum Speed
• Tsunami® MP-8100-BSU 1 Gbps
• Tsunami® MP-8100-SUA
• Tsunami® MP-8150-SUR
• Tsunami® MP-8160-BSU
• Tsunami® MP-8160-SUA
• Tsunami® QB-8100-EPA
• Tsunami® QB-8100-LNK
• Tsunami® QB-8150-EPR
• Tsunami® QB-8150-LNK
• Tsunami® MP-8150-CPE 100 Mbps
• Tsunami® MP-8160-CPE
• Tsunami® QB-8150-EPR-12/50
Tsunami® 8100 Series - Software Management Guide 42
Advanced Configuration
Parameter Description
Operational Tx Mode Displays the current operational transmission mode of the Ethernet interface. It supports
two types of transmission modes:
Half Duplex: Allows one-way data transmission at a time.
Full Duplex: Allows two-way transmission simultaneously.
Speed And TxMode Enables the user to select the speed and transmission mode of the Ethernet interface. By
default, it is set to Auto. When set to Auto (recommended to set), both the transmitter and
the receiver negotiate and derive at the best transmission mode.
: Please ensure the same transmission modes are configured on the transmitter and
the receiver device.
Admin Status This parameter is applicable only when the device support more than one Ethernet
interface. By default, both the Ethernet interfaces of the device are enabled. The first
Ethernet interface is always enabled; whereas the second Ethernet interface can be either
enabled or disabled as desired.
After configuring the required parameters, click OK and then COMMIT.
Reboot the device, if you have changed the Admin Status configuration.
5.3.2 Advanced Configuration
The Advanced Configuration feature enables you to achieve high availability and link aggregation in wireless medium by using
two parallel links and additional Link Aggregation Control Protocol (LACP) capable switches.
: Applicable only to Tsunami® QB-8100-EPA, Tsunami® QB-8100-LNK, Tsunami® QB-8150-EPR, and
Tsunami® QB-8150-LNK.
To view and perform advanced Ethernet configuration, click Advanced in the Ethernet Interface Properties screen. The
following screen appears:
Figure 5-8 Advanced Ethernet Configuration
Tsunami® 8100 Series - Software Management Guide 43
Advanced Configuration
Tabulated below is the table which explains Advanced Ethernet parameters and the method to configure the configurable
parameter(s):
Parameter Description
Auto Shutdown This parameter facilitates LACP capable Ethernet switches to use two Quick Bridge links to
achieve higher throughput and redundancy. By default, it is Disabled.
If Auto Shutdown is enabled on the Ethernet Interface, then the Ethernet port will be
automatically disabled, when the wireless link goes down. It will be automatically enabled once
the wireless link is up again.
: This feature works only if STP/LACP Frames is set to passthru (See ADVANCED
CONFIGURATION > Filtering)
Tsunami® Quick Bridge devices that are part of LACP link cannot be managed through the
switches, so it is recommended to use the second ethernet port for management.
After configuring the required parameters, click OK and then COMMIT.
5.4 Wireless
The Wireless tab allows you to configure the wireless properties for the radio interface of the device.
5.4.1 Wireless Outdoor Router Protocol (WORP)
WORP is protocol, designed by Proxim that protects the network from packet collisions and solves the hidden node problem to
transmit the data in an optimal way.
To configure the WORP properties, navigate to ADVANCED CONFIGURATION > Wireless > Interface1 > WORP. The
WORP Configuration screen appears:
Tsunami® 8100 Series - Software Management Guide 44
Advanced Configuration
Figure 5-9 WORP Configuration
Tabulated below is the table which explains WORP parameters and the method to configure the configurable parameter(s):
Parameter Description
Mode Represents the device type (BSU, SU, End Point A or End Point B)
BSU Name Applicable only to SU. It specifies the name of the BSU to which a SU can establish wireless
connection. If this parameter is left blank, SU can establish a link with any BSU.
End Point A Name Applicable only in End Point B mode. It specifies the name of the End Point A to which End
Point B can establish wireless connection. If this parameter is left blank, End Point B can
establish a link with any End Point A.
Network Name It is a unique name given to a logical network. Devices only within this logical network can
establish wireless connection.
The Network Name can be of 2 to 32 characters in length. By default it is MY_NETWORK.
Tsunami® 8100 Series - Software Management Guide 45
Advanced Configuration
Parameter Description
Max SUs Represents the maximum number of SUs that can register with a BSU. The maximum SUs
are limited to the licensed number of SUs.
: Applicable only in BSU mode.
WORP MTU WORP MTU (Maximum Transmission Unit) is the largest size of the data payload in wireless
frame that can be transmitted. The MTU size can range from 350 to 3808 bytes for High
throughput modes and 350 to 2304 bytes for legacy mode. The default and maximum
value of the WORP MTU is 3808 bytes for higher throughput and 2304 bytes for legacy
mode.
Super Framing Super Framing refers to the mechanism that enables multiple Ethernet/802.3 frames to be
packed in a single WORP data frame. When the WORP MTU size is configured larger than the
Ethernet frame size, then WORP constructs a super frame with size of the WORP MTU
configured and pack multiple Ethernet frames. It results in reducing the number of frames
transmitted over wireless medium thereby conserving wireless medium and increasing the
overall throughput. By default it is Enabled.
Sleep Mode A BSU can put SUs in sleep mode when there is no data transmission during the past 15
seconds. This reduces the traffic congestion in the wireless medium and preserves the
wireless bandwidth for other SUs in the network. BSU polls sleeping SUs once in every 4
seconds to maintain the wireless connection. By default, it is Disabled.
: Applicable only in BSU mode.
Multi Frame Bursting To achieve higher throughput, WORP protocol allows the transmitter or receiver to send
multiple data frames in sequence without waiting for acknowledgment for every data
frame and treats it as a single burst. During the burst transmission, the receiver is not
allowed to interrupt the transmitter. After compilation of the burst, the receiver response by
sending the acknowledgement.
By default, the Multi Frame Bursting feature is Enabled on the device. When Multi Frame
Bursting is enabled, the maximum data frames that can be transmitted for each burst can be
configured as part of Quality of Service (QoS).
: Though Multi Frame Bursting configuration is not applicable from SU/End Point B,
the SU/End Point B does Multi Frame Bursting under the control of BSU/End Point A
respectively.
Tsunami® 8100 Series - Software Management Guide 46
Advanced Configuration
Parameter Description
Auto Multi Frame Auto Multi Frame Bursting feature takes effect only when Multi Frame Bursting feature is
Bursting Enabled.
When this feature is enabled, the device monitors all active QoS Service Flow Classes and
determines the highest priority QoS Service Flow Class for every wireless connection. The device
enables the burst transmission for the active highest priority QoS Service Flow Class and
disables the burst transmission for other active lower priority QoS Service Flow Classes. By default,
Auto Multi Frame Bursting is Enabled on the device.
:
• When using Software Version 2.4.0, it is recommended to disable Auto Multi
Frame Bursting.
• Though Auto Multi Frame Bursting configuration is not applicable from
SU/End Point B, the SU/End Point B does Auto Multi Frame Bursting under the
control of BSU/End Point A respectively.
Registration Timeout Represents the maximum time for a SU to register with a BSU or vice versa, or an End Point
B to register with an End Point A or vice versa. The registration timeout value can be set in the
range 1 to 10 seconds. The default registration timeout value is 10 seconds.
Retry Count Represents the maximum number of times the data is retransmitted by the transmitter
over the wireless medium, if acknowledgement from the peer is not received. The Retry
Count parameter can be configured in the range 0 to 10 seconds. By default, it is set to 3.
DDRS Status
: Applicable only when DDRS is enabled.
It is a read-only parameter that displays the status of the DDRS feature. For more details
refer to DDRS.
Tx Rate Represents the modulation rate at which the packets are transmitted from the wireless
device. Please note that the a change in Channel Bandwidth, Guard Interval and Number
of Data Streams will reset Tx rate to default values.
: Applicable only when the DDRS is disabled on the device. See DDRS.
Input or Output This parameter limits the data received or transmitted to the wireless interface. It limits the
Bandwidth Limit data from a minimum of 64 Kbps to the maximum value specified in the License File.
: Input/Output Bandwidth throttling does not throttle broadcast/multicast traffic.
These traffic can be trottled by the Maximum Information Rate (MIR) /
Committed Information Rate (CIR) configured for DL-L2 Broadcast BE in QoS
Service Flow. See QoS Service Flow Configuration (SFC)
Tsunami® 8100 Series - Software Management Guide 47
Advanced Configuration
Parameter Description
Bandwidth Limit Type Specifies the action performed when the traffic utilization exceeds the configured input or
output limits. By default it is set to Shaping.
Policing: When the traffic utilization reaches the configured limit, the excess traffic
will be discarded.
Shaping: When the traffic utilization reaches the configured limit, the excess traffic
will be buffered and sent at the rate specified in the Output Bandwidth Limit.
Security Profile Name The Security Profile Name represents the encryption method used to encrypt the data over
the wireless medium. The default configured Security Profile Name is WORP Security. See
Security.
Radius Profile Name The Radius Profile Name, containing the IP address of the RADIUS server, is used to
authenticate a SU or an End Point B. See RADIUS.
: Not applicable in SU mode and End Point B mode.
MAC ACL Status When enabled, based on the configured ACL list, the BSU/End Point A decides if SU/End
Point B can register with them respectively.
: Not applicable in SU mode and End Point B mode.
Radius MAC ACL This parameter is used to enable authentication using RADIUS server. When enabled, the
Status BSU or End Point A contacts the RADIUS server for authenticating the SU or End Point B
during the registration process.
: Not applicable in SU mode and End Point B mode.
Poll BackOff on When enabled, the BSU will back-off polling the SUs that timeout (due to interference or
Timeout low SNR etc).
When multiple SUs are connected, it is possible that some SUs are performing well without
much retransmissions and other SUs are timing out. In such as scenario to make sure that
the good SUs do not suffer due to under performing SUs it is recommended to enable this
parameter.
By default this parameter is disabled. It is recommended that this parameter should be
enabled only when there is a mix of good and bad SUs and when good SUs are really
suffering.
After configuring the required parameters, click OK and then COMMIT.
:
• Modifying any of the WORP parameters result in temporary loss of connectivity between transmitter and receiver.
Tsunami® 8100 Series - Software Management Guide 48
Advanced Configuration
• MAC ACL Status and Radius MAC ACL Status parameters cannot be enabled simultaneously.
• When you modify WORP parameters and click COMMIT, it may result in brief interruption.
5.4.2 Wireless Interface Properties
To configure the wireless interface properties, navigate to ADVANCED CONFIGURATION > Wireless > Interface 1 >
Properties. The Wireless Interface Properties screen appears depending on your device:
Figure 5-10 Wireless Interface Properties
The Wireless Interface Properties screen is classified under two categories: Basic and Advanced.
Tsunami® 8100 Series - Software Management Guide 49
Advanced Configuration
Basic Configuration
Under Basic Configuration screen, you can configure and view the following parameters.
Parameter Descriptions
Channel Bandwidth By default, the channel bandwidth is set to 20 MHz. 40 MHz can be selected for higher
throughputs depending on the distance and signal quality. 5 and 10 MHz can be selected for
greater flexibility in spectrum selection.
: A change in Channel Bandwidth will reset the Tx Rate and Maximum EIRP to
default.
Channel Offset
: Applicable only to Tsunami® MP-8160-BSU; Tsunami® MP-8160-SUA;
Tsunami® MP-8150-CPE; Tsunami® MP-8160-CPE; Tsunami®
QB-8150-EPR-12/50 devices.
The Channel Offset parameter helps to change the operating channel center frequency. If the
predefined center frequencies are not desirable, user can shift the center frequency to suit the
requirements by configuring the Channel Offset. By default, the Channel Offset is set to 0. You
can configure the Channel Offset in the range -2 to +2 MHz.
For example, consider a channel number 100 with center channel frequency set to 5500 MHz.
If the Channel Offset is set to 0 MHz, the center channel frequency remains at 5500 MHz. If you
configure the Channel Offset to 2MHz then the center channel frequency will change to
5502MHz. Similarly for a Channel Offset of -2MHz, the center channel
frequency is changed to 5498 MHz.
: Even though the center channel frequency is changed, the channel number still
remains same, in this case 100.
Auto Channel Auto Channel Selection (ACS) enables the device to determine the best channel for
Selection (ACS) wireless data transmission with less interference.
If ACS is enabled on the BSU/End Point A, it scans all the channels and selects the best
channel at the startup. If ACS is enabled on the SU/End Point B, it continuously scans all the
channels till it finds a suitable BSU/End Point A and connects to it. By default, ACS is
disabled on BSU/End Point A and enabled on SU/End Point B.
: On BSU/End Point A, ACS is performed only during startup.
Preferred Channel Allows the user to select and operate in the preferred channel.
Preferred channel can be configured only when ACS is disabled. If Dynamic Frequency
Selection (DFS) is active, the device will automatically pick a new channel when radar
interference is detected.
Tsunami® 8100 Series - Software Management Guide 50
Advanced Configuration
Parameter Descriptions
Active Channel A read-only parameter that displays the current operating channel on which the wireless
interface is operating.
: Active Channel can be different from Preferred Channel if radar interface is
detected.
Satellite Density Satellite Density setting helps achieve maximum bandwidth in a wireless network. It
influences the receive sensitivity of the radio interface and improves operation in
environments with high noise level. Reducing the sensitivity of the device enables
unwanted “noise” to be filtered out (it disappears under the threshold).
You can configure the Satellite Density to be Disable, Large, Medium, Small, Mini, or
Micro. By default, Satellite Density is set to Large. The Medium, Small, Mini, and Micro
settings are appropriate for higher noise environments; whereas, Large is appropriate for a
lower noise environment. A long distance link can have difficulty in maintaining a
connection with a small density setting because the wanted signal can disappear under
the threshold. Consider both noise level and distance between the peers in a link when
configuring this setting. The threshold should be chosen higher than the noise level, but
sufficiently below the signal level. A safe value is 10dB below the present signal strength.
If the Signal-to-Noise Ratio (SNR) is not sufficient, you may need to set a lower data rate or
use antennas with higher gain to increase the margin between wanted and unwanted
signals. In a point-to-multipoint link, the BSU or End Point A should have a density setting
suitable for an SU or End Point B, especially the ones with the lowest signal levels (longest
links). Take care when configuring a remote interface; check the available signal level first,
using Remote Link Test.
Tabulated below are the Sensitivity Threshold Values corresponding to various Satellite
Density values:
Satellite Density Receive Sensitivity Defer Threshold
Threshold
Large -96 dbm -62 dbm
Medium -86 dbm -62 dbm
Small -78 dbm -52 dbm
Mini -70 dbm -42 dbm
Micro -62 dbm -36 dbm
: When the remote interface is accidentally set to small and communication is lost,
it cannot be reconfigured remotely and a local action is required to restore the
communication link. Therefore, the best place to experiment with the level is at
the device that can be managed without going through the link. If the link is
lost, the setting can be adjusted to the correct level to bring the link back.
Tsunami® 8100 Series - Software Management Guide 51
Advanced Configuration
Parameter Descriptions
ATPC Status If Adaptive Transmit Power Control (ATPC) is enabled, then the device automatically
adjusts the transmit power to avoid saturation of remote receiver, which could cause data
errors leading to lower throughput and link outage. If disabled, user can manually adjust the
transmit power. By default, ATPC is enabled on the device.
Transmit Power Control (TPC) is calculated based on two factors:
• Equivalent Isotropically Radiated Power (EIRP)
• Maximum Optimal SNR
• Antenna Gain
: In BSU, the ATPC considers the EIRP only; where as in SU, End Point A
and End Point B both EIRP and Maximum SNR are considered.
Tsunami® 8100 Series - Software Management Guide 52
Advanced Configuration
Parameter Descriptions
Max EIRP The maximum effective power that a radio antenna is allowed to radiate as per the
regulatory standard. By default, the maximum EIRP is set as per the regulatory
requirements for each frequency domain.
Tabulated below are the default maximum EIRP values that are set according to regulatory
domain:
Regulatory Frequency Max EIRP (dBm)
Domain (MHz)
PTP Mode (QB) PTMP Mode (MP)
World All Unlimited (100) Unlimited (100)
United States 2402-2472 32 + 2/3(antenna BSU: 36
gain) SU/CPE: 32 + 2/3
(antenna gain)
4940 - 4990 33 (20 MHz) 33 (20 MHz)
30 (10 MHz) 30 (10 MHz)
27 (5 MHz) 27 (5 MHz)
5250 - 5330 30 30
5735 - 5835 53 36
Canada 4940 - 4990 33 (20 MHz) 33 (20 MHz)
30 (10 MHz) 30 (10 MHz)
27 (5 MHz) 27 (5 MHz)
5250 - 5330 30 30
5490 - 5590 30 30
5650 - 5710 30 30
5730 - 5860 53 36
Europe 2402 - 2472 20 20
(including UK) 5490 - 5590 30 30
5650 - 5710 30 30
5735 - 5875 36 36
Russia 5150 - 5350 33 33
5350 - 5650 Unlimited (100) Unlimited (100)
5650 - 6425 53 53
Taiwan 5490 - 5710 30 30
5735 - 5835 36 36
Tsunami® 8100 Series - Software Management Guide 53
Advanced Configuration
Parameter Descriptions
Regulatory Frequency Max EIRP (dBm)
Domain (MHz) PTP Mode PTMP Mode
India 5825 - 5875 36 36
Brazil 5470 - 5725 30 30
5725 - 5850 Unlimited (100) 32 + 2/3(antenna
gain)
Australia 5470 - 5600 30 (20 and 40 MHz) 30 (20 and 40 MHz)
27 (10 MHz) 27 (10 MHz)
24 (5 MHz) 24 (5 MHz)
5650 - 5725 30 (20 and 40 MHz) 30 (20 and 40 MHz)
27 (10 MHz) 27 (10 MHz)
24 (5 MHz) 24 (5 MHz)
5725 - 5850 36 36
:
The maximum EIRP is not defined in the above table then it is set to 100
(unlimited EIRP).
Maximum EIRP criterion is enforced only when ATPC is enabled.
Active TPC A read-only parameter which displays the TPC applied by the device to adjust the transmit
power, when ATPC is enabled.
: In case of BSU, the Active TPC refers to the TPC applied to the broadcast
packets. To view Active TPC of each link, refer to SU / End Point B Link
Statistics.
Active EIRP A read-only parameter which displays the current EIRP that a radio antenna radiates.
Active Power A read-only parameter which displays the current power radiated by the radio.
Tsunami® 8100 Series - Software Management Guide 54
Advanced Configuration
Parameter Descriptions
TPC This parameter enables you to manually set the Transmit Power Control (TPC) value when
ATPC is disabled. You can manually set TPC ranging from 0 to 25 dBm.
With TPC, you can adjust the output power of the device to a lower level. This is
performed to reduce interference with the neighboring devices. It can be helpful when
higher gain antenna is used without violating the maximum radiated output power for a
country or regulatory domain. By default, it is set to 0 dBm.
:
TPC only lets you decrease the output power; it does not let you increase the
output power beyond the maximum allowed defaults for the selected frequency
and country.
TPC can be configured in the steps of 0.5 dB
Antenna Gain The sensitivity of the radio card can be modified when detecting radar signals in
accordance with ETSI, FCC, and IC Dynamic Frequency Selection (DFS) requirements. As
the radar detection threshold is fixed by ETSI, the FCC, and IC and a variety of antennas with
different gains may be attached to the device, you must adjust this threshold to account for
higher than expected antenna gains. This can avoid false radar detection events which can
result in frequent change in the Frequency channels.
Configure the threshold for radar detection at the radio card to compensate for increased
external antenna gains. The Antenna Gain value ranges from 0 to 40 dBi. For devices with
connectorized antenna, the Antenna Gain by default is set to zero dBi.
Tabulated below are the default Antenna Gain, for devices with integrated antenna:
Product (s) Antenna Gain
Tsunami® MP-8150-SUR 23 dBi
Tsunami® MP-8150-CPE 16 dBi
Tsunami® MP-8160-CPE 15 dBi
Tsunami® QB-8150-EPR/ 23 dBi
Tsunami® QB-8150-LNK
Tsunami® QB-8150-EPR-12/50 16 dBi
Wireless Inactivity Resets the wireless interface if there is no change in the Tx and Rx Packet Count in the
Timer specified interval of time. The default value is set to 10 seconds (disabled if set to 0
seconds) and can be configured between 5 to 600 seconds.
Tsunami® 8100 Series - Software Management Guide 55
Advanced Configuration
Parameter Descriptions
Legacy Mode When Legacy Mode is enabled, the BSU can interoperate with the legacy products of the
Tsunami MP.11 family: MP.11 5054 series, 5012 series, 2454 series and so on.
By default, it is disabled.
: Applicable only to Tsunami® MP-8100-BSU.
After configuring the required parameters, click OK and then COMMIT.
Reboot the device, if you have changed any of the Wireless Interface parameters with asterisk (*) symbol marked against
them.
Advanced
To view Advanced parameters, click Advanced tab in the Wireless Interface Properties screen. The following screen
appears:
Figure 5-11 Advanced Wireless Properties
The following table lists the Advanced Wireless properties parameters and their description. Note that these parameters are
read-only and can be configured only through CLI or SNMP.
Parameter Description
ATPC Lower Margin SNR Upper Limit = Maximum Optimal SNR
and SNR Initial = SNR Upper Limit - ATPC Upper Margin
ATPC Upper Margin SNR Lower Limit = SNR Initial - ATPC Lower Margin
ATPC Algorithm, after reducing the power to honor the Maximum EIPR limit, adjusts the
power based on Maximum Optimal SNR, ATPC Upper Margin and ATPC Lower Margin. To
begin with, ATPC will adjust the power to bring the SNR to SNR Initial and adjusts power
only when the current SNR goes beyond the SNR Upper Limit and SNR Lower Limit.
Click Local SNR-Table, to view the optimal SNR values that are exchanged with the peer for optimal throughput.
Tsunami® 8100 Series - Software Management Guide 56
Advanced Configuration
5.4.3 MIMO Properties
The MIMO Properties tab allows you to configure the Multiple-Input-Multiple-Output (MIMO) parameters that enable to
achieve high throughput and longer range.
To configure MIMO properties, navigate to ADVANCED CONFIGURATION > Wireless > Interface1 > MIMO Properties. The
MIMO Properties screen appears:
Figure 5-12 3x3 MIMO Properties
Figure 5-13 2x2 MIMO Properties
Tabulated below is the table which explains MIMO parameters and the method to configure the configurable parameters:
Parameter Description
MIMO Properties
Tsunami® 8100 Series - Software Management Guide 57
Advanced Configuration
Parameter Description
Frequency Extension Frequency Extension is applicable only when the Channel Bandwidth is set to 40 MHz.
While choosing 40MHz bandwidth, you can select either 40 PLUS (Upper Extension
Channel) or 40 MINUS (Lower Extension Channel). 40 PLUS means the center frequency
calculation is done for 20MHz and add another 20MHz to the top edge of 20MHz. 40
MINUS means the center frequency calculation is done for 20MHz and add another 20MHz
to the bottom edge of 20MHz.
Guard Interval Guard Interval determines the space between symbols being transmitted. The guard
interval can be configured as either Short GI - 400n seconds or Full GI-800n seconds.
In 802.11 standards, when 40 MHz Channel Bandwidth is configured then Short GI can be used
to improve the overall performance and throughout.
By default, Full GI is enabled for 5 MHz, 10 MHz and 20 MHz channels.
: Short GI-400 nSec is valid only for 40 MHz channel bandwidth.
Data Streams MIMO radio uses multiple antennas for transmitting and receiving the data.
The data streams supported by the device are as follows:
Single: In single data stream, the data frames are transmitted in parallel over all the
antennas. This stream is recommended for longer range.
Dual: In dual data stream, the data frames are distributed across the antennas and
transmitted. This stream is recommended for higher throughput.
: Data streams is not applicable when DDRS is enabled.
Antenna Status
Tx Antenna Status Allows the user to select the antenna(s) for data transmission. Select the checkbox against
each antenna(s) for data transmission and click Ok.
: Atleast two Tx antenna ports should be enabled when Data Stream is dual, or
DDRS Stream Mode is set to auto or dual.
Rx Antennas Status Allows the user to select the antenna(s) for receiving data. Select the checkbox against
each antenna(s) for receiving data and click Ok.
: Atleast two Rx antenna ports should be enabled when Data Stream is dual, or
DDRS Stream Mode is set to auto or dual.
: Modifying the Guard Interval and Data Stream configuration values, will reset the Tx Rate to default value.
Tsunami® 8100 Series - Software Management Guide 58
Advanced Configuration
After configuring the required parameters, click OK and then COMMIT.
Reboot the device, if you have changed any of the MIMO parameters with asterisk (*) symbol marked against them.
5.4.4 Dynamic Frequency Selection (DFS)
The Tsunami® products support Dynamic Frequency Selection (DFS) for FCC, IC, and ETSI regulatory domains per FCC Part 15
Rules for U-NII devices, IC RSS-210, and ETSI EN 301-893 regulations, respectively. These rules and regulations require that the
devices operating in the 5 GHz band must use DFS to prevent interference with RADAR systems.
: DFS is not applicable in case of Tsunami® MP-8160-BSU, Tsunami® MP-8160-SUA and Tsunami®
MP-8160-CPE devices.
5.4.4.1 DFS in BSU or End Point A mode
Explained below is the DFS functionality and the way it operates on a BSU or in End Point A devices.
1. Based on the selected frequency (regulatory) domain, DFS is automatically enabled on the device.
2. During bootup,
if ACS is disabled on the device, the device chooses the Preferred Channel to be the operational channel.
: By default, Automatic Channel Selection (ACS) is disabled on the BSU or a device in End Point A mode.
if ACS is enabled, then the device scans all the channels and selects the channel with the best RSSI to be the
operational channel.
3. Once the operating channel is selected, the device scans the channel for the presence of the RADAR for a duration of
the configured Channel Wait Time (by default configured to 60 seconds). During this time, no transmission of data
occurs.
4. If no RADAR is detected, the device starts operating in that channel.
5. If RADAR is detected, the channel is blacklisted for 30 minutes. Now, ACS will scan all the non-blacklisted channels
and select the channel with best RSSI. Upon choosing the best channel, the device again scans the selected channel
for the presence of the RADAR for a duration of the configured Channel Wait Time. Again, during this time no
transmission of data occurs.
6. If no RADAR is detected, it operates in that channel else repeats step 5.
7. While operating in a channel, the device continuously monitors for potential interference from a RADAR source (this is
referred to as in-service monitoring). If RADAR is detected, then the device stops transmitting in that channel. The
channel is added to the blacklisted channel list.
8. A channel in the blacklisted listed can be purged once the Non Occupancy Period (NOP) has elapsed for that channel.
:
• When a channel is blacklisted, all its sub-channels that are part of the current channel bandwidth are also
blacklisted.
• For Europe 5.8 GHz channel, once the device finds a RADAR free channel (after 60 seconds RADAR scan), it does not
perform scan for the next 24 hours. This is not applicable when device is rebooted or a particular channel got blacklisted
earlier.
• Even if the preferred channel is configured with a DFS channel manually, the SU will scan for the BSU/End PointA's
channel and associates automatically.
Tsunami® 8100 Series - Software Management Guide 59
Advanced Configuration
5.4.4.2 DFS in SU or End Point B Mode
Explained below is the DFS functionality and the way it operates on SU or End Point B.
1. When SU/End Point B has no WORP link, it scans continuously all the channels in the configured Frequency Domain
for the presence of BSU/End Point A. If suitable BSU/End Point A is found in any scanned channel, the SU or End Point
B tries to establish WORP link.
2. After selecting the suitable BSU/End Point A’s channel,
If SU/End Point B DFS is disabled, then SU/End Point B tries to connect to BSU/End Point A.
If SU/End Point B DFS is enabled, the SU/End Point B scans the selected channel for the presence of the RADAR for
a duration of the configured Channel Wait Time (by default configured to 60 seconds). During this time, if the
SU/End Point B detects radar, the channel is blacklisted and it starts scanning on non-blacklisted channels for a
BSU/End Point A as given in step 1. If no radar is detected, a connection will be established.
3. While WORP link is present, the SU/End Point B continuously monitors the current active channel for potential
interference from a RADAR source (this is referred to as in-service monitoring).
If RADAR is detected, the SU/End Point B sends a message to the BSU or End Point A indicating the RADAR
detection on the active channel and blacklists that channel for Non Occupancy Period (NOP). The default NOP is
30 Minutes.
On receiving the RADAR detection message from SU/End Point B, the BSU/ End Point A blacklists the active
channel and ACS starts scanning for an interference free channel.
: The BSU blacklist the channel only when the number of SUs reporting the RADAR equals or exceeds the
configured SUs Reporting RADAR parameter.
4. A blacklisted channel can be purged once the Non Occupancy Period (NOP) has elapsed.
:
• On the SU/End Point B, if the preferred channel is configured with a DFS channel then SU will scan all the channels even if
ACS is disabled.
• When a channel is blacklisted, all its sub-channels that are part of that channel bandwidth are also blacklisted.
For detailed information on DFS enabled countries, see Frequency Domains and Channels.
Tsunami® 8100 Series - Software Management Guide 60
Advanced Configuration
To configure DFS parameters, navigate to ADVANCED CONFIGURATION > Wireless > Interface 1 > DFS. The Dynamic
Frequency Selection (DFS) screen appears.
Figure 5-14 DFS Configuration (BSU Mode)
Tsunami® 8100 Series - Software Management Guide 61
Advanced Configuration
Figure 5-15 DFS Configuration (SU/End Point B Mode)
Tabulated below is the table which explains DFS parameters and the method to configure the configurable parameter(s):
Parameter Description
Channel Wait Time One the device selects the best channel, it scans that channel for the presence of RADAR
for a period of set Channel Wait Time. The wait time can be configured in the range 0 to 3600
sec. By default, the wait time is set to 60 seconds.
SUs Reporting RADAR
Applicable only to BSU.
When a SU detects a RADAR, it reports to BSU. The BSU will take a decision on whether to
blacklist this channel based on SUs Reporting RADAR parameter. If the number of SU
reporting RADAR equals or exceed the configured SUs Reporting RADAR parameter then BSU
blacklists that channel. If SUs reporting the RADAR is less than this configured value then BSU
continues to operate in the same channel. The range varies depending on the product license.
By default, it is set to 0.
DFS Status Applicable only to SU or End Point B devices.
A SU or End Point B devices have the option to either enable or disable DFS. By default,
DFS is disabled.
After configuring the required parameters, click OK and then COMMIT.
Tsunami® 8100 Series - Software Management Guide 62
Advanced Configuration
5.4.4.3 Blacklist Information
The blacklisted table displays all the channels that are blacklisted.
Parameter Description
Channel Number Indicates the channel that is blacklisted.
Reason Specifies the reason for blacklisting a channel.
Following are the reasons for blacklisting a channel:
1. Remote Radar: A SU/End Point B detects a RADAR and informs BSU/End Point A
accordingly.
2. Local Radar: The device detects the RADAR on its own.
3. Unusable: For bandwidths more than 5 MHz, channels that are not usable because
they fall in the frequency range of other radar/manual blacklisted channels. For
example, if channel 110 is blacklisted, then channels 108, 109, 111, 112 will
become unusable for 20 MHz bandwidth.
4. Manual: A channel is manually blacklisted by the administrator.
Time Elapsed The time elapsed since the channel was blacklisted due to radar. When the channel is
blacklisted due to the presence of a radar, it will be de-blacklisted after 30 Minutes.
This parameter is applicable for radar blacklisted channels only.
Click Refresh, to view updated/refreshed blacklisted channels.
5.4.4.4 Manual Blacklist
This tab enables you to manually blacklist a channel.
However, there are few conditions to be followed while blacklisting channels:
When ACS is disabled, the preferred channel and its sub-channels that are part of the current channel bandwidth
cannot be manual blacklisted.
When WORP link is UP, the active channel and its sub-channels that are part of the current channel bandwidth cannot
be manual blacklisted.
When DFS/ACS is enabled, atleast one channel and its sub-channels that are part of the current channel bandwidth
should be available for operation. That is, all channels cannot be blacklisted.
To manual blacklist channels, click Manual Blacklist under Dynamic Frequency Selection (DFS) screen. The following
screen appears:
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Figure 5-16 Manual Blacklist
Select the channels that you want to blacklist by entering the start and end channels in the Start Channel and End Channel
boxes
respectively.
Next, click Add. All the selected channels are added to the Blacklisted Channels table.
To remove any blacklisted channel, enter the Start and End Channel of the blacklisted channels and then click Remove
button.
To refresh channel entries, click Refresh.
5.4.5 DDRS
Dynamic Data Rate Selection (DDRS) feature adjusts the transmission data rate to an optimal value to provide the best
possible throughput according to the current communication conditions and link quality.
The factors for adjusting the transmission data rate are,
1. Remote average Signal-to-noise (SNR) ratio
2. Number of retransmissions
DDRS can be configured separately on each device (BSU mode/ SU mode /End Point A mode/ End Point B mode).
5.4.5.1 DDRS Configuration
To configure DDRS on the device, navigate to ADVANCED CONFIGURATION > Wireless > Interface 1 > DDRS. The DDRS
Configuration screen appears:
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Figure 5-17 Basic DDRS Configuration
The DDRS Configuration is classified under two categories, namely, Basic and Advanced.
Basic Configuration
Under Basic Configuration screen, you can configure the following parameters.
Parameter Description
DDRS Status Enables the user the either enable or disabled DDRS feature on the device. By default, it is
enabled on the device.
Stream Mode Select the stream mode as either Auto, Single or Dual. By default, the Auto mode is
selected. Based on the selected stream modes, DDRS dynamically chooses the data rate.
Dual: Select Dual, for higher throughput.
Single: Select Single, for reliability and longer range.
Auto: When configured to Auto, DDRS decides on the stream modes based on the
environment conditions.
: Stream Mode is not valid in legacy mode.
Maximum Rate Represents the maximum data rate that DDRS can dynamically choose to provide the best
possible throughput. The default value depends on the channel bandwidth and the
number of streams.
: A change in Frequency Domain, Channel Bandwidth, Guard Interval and Data
Stream will reset maximum data rate to defaults.
After configuring the required parameters, click OK and then COMMIT.
Advanced Configuration
To view Advanced Configuration parameters, click Advanced tab in the DDRS Configuration screen. The following screen
appears depending on your device:
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Advanced Configuration
Figure 5-18 Advanced DDRS Configuration
The following table lists the Advanced Configuration parameters and their description. Note that these parameters are
read-only and can be configured only through CLI or SNMP.
Parameter Description
Minimum Rate and Represents the minimum and maximum data rate between which the DDRS dynamically
Maximum Rate selects the transmission data rate. These varies depending on the configured Data
Streams, Channel Bandwidth and Guard Interval.
Lower SNR Correction Represents the margin value to be added to the Minimum Required SNR, for the purpose
of removing the data rate from the valid data rate table. Doing so, avoids Hysteresis in the
dynamic data rate.
By default, it is configured to 10 dB.
Upper SNR Correction Represents the margin value to be added to the Minimum Required SNR, for the purpose
of adding the data rate to the valid data rate table. Doing so, avoids Hysteresis in the
dynamic data rate.
By default, it is set to 3 dB.
Rate Increment RTX Represents a threshold for the percentage of retransmissions, below which the rate can be
Threshold increased. By default, it is set to 25%.
: If the percentage of retransmissions is between “Rate Increment RTX Threshold”
and “Rate Decrement RTX Threshold” then the current operation rate is
maintained.
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Rate Decrement RTX Represents a threshold for percentage of retransmissions, above which the rate can be
Threshold decreased. By default, it is set to 30%. Please note that if the percentage of
retransmissions is between “Rate Increment RTX Threshold” and “Rate Decrement RTX
Threshold” then the current operation rate is maintained.
Chain Balance In the case of MIMO, the difference in SNR between two chains must be less than or equal
Threshold to this threshold for the chains to be considered as “Balanced”. By default, it is set to 15
dB.
:
This parameter is applicable only for “Auto” stream mode.
When “Auto” stream mode is configured and if chains are not balanced, then
Single Stream rates are considered.
Rate Back Off Interval The DDRS algorithm constantly attempts higher data rates, when the current rate is stable.
If not successful, it goes back to older stable rate. Before the next attempt, it waits for a
minimum duration. This duration starts with 10 seconds and increases exponentially up to
Rate Back Off Interval and remains at this value. By default, it is set to 300 seconds.
Click Local SNR-Table, to view the optimal SNR values that are exchanged with the peer for optimal throughput.
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Figure 5-19 An Example - SNR Information
These SNR values vary depending on your device. For device specific SNR information, see SNR Information.
5.5 Security
5.5.1 Wireless Security
The Wireless Security feature helps to configure security mechanisms to secure the communication link between a BSU and a SU,
and a link between End Point A and End Point B. By default, a security profile (WORP Security) is preconfigured with the default
configuration for WORP security. Altogether, device allows to create 8 security profiles as required. Even though 8 security profiles
can be created, only one security profile can be active at a time. The active security profile is configured as part of the WORP
property Security Profile Name. For a security profile to be active, it must be enabled. Refer to Wireless Outdoor Router Protocol
(WORP) for more details.
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: Configure the same security profile on the either ends to establish a connection.
To configure the Wireless security profile, navigate to ADVANCED CONFIGURATION > Security > Wireless Security. The
Wireless Security Configuration screen appears:
Figure 5-20 Wireless Security Configuration
Tabulated below is the table which explains Wireless Security parameters:
Parameter Description
Profile Name Specifies the security profile name. By default, it is WORP Security.
Entry status Enables a user to either Enable or Disable the security profile on the device.By default, it
is enabled.
Edit Enables you to edit the existing security profiles. Click Edit to modify any of the security
profile parameters.
After configuring the required parameters, click OK and then COMMIT.
5.5.1.1 Creating a New Security Profile
To create a new security profile, click Add in the Wireless Security Configuration screen. The following Wireless Security Add
Row screen appears:
Figure 5-21 Creating a New Security Profile
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Tabulated below is the table which explains the method to create a new Security Profile:
Parameter Description
Profile Name A name to uniquely identify a security profile name.
Encryption Type Select encryption type as either None, WEP, TKIP or AES-CCM.
1. None - If the encryption type is selected as None, then there exist no security to the
data frames transmitted over the wireless medium.
2. WEP (Wired Equivalent Privacy) - Represents the WEP Encryption type, which
uses RC4 stream cipher for confidentiality and CRC-32 for integrity. The supported
key lengths for WEP are 5/13/16 ASCII Characters or 10/26/32 Hexadecimal digits.
- Key1 / Key 2 / Key 3 / key 4: You can configure a maximum of four WEP keys.
Enter 5/13/16 ASCII Characters or 10/26/32 Hexadecimal digits for WEP keys.
- Transmit Key: Select one out of the four keys described above as the default
transmit key, which is used for encrypting and transmitting the data.
3. TKIP - Represents the TKIP Encryption type, which uses RC4 stream cipher for
confidentiality. TKIP provides per-packet key mixing, a message integrity check and a
re-keying mechanism. It uses 128-bit keys for encryption. The key length for TKIP is 16
ASCII characters or 32 Hexadecimal digits.
- Key1 / Key 2 / Key 3 / key 4: You can configure a maximum of four TKIP keys.
Enter 16 ASCII Characters or 32 Hexadecimal digits.
- Transmit Key: Select one out of the four keys described above as the default
transmit key, which is used for encrypting and transmitting the data.
4. AES-CCM - Represents CCM Protocol with AES Cipher restricted to 128 bits.
Key: Enter 16 ASCII Characters or 32 Hex Digits for AES-CCM encryption keys.
Entry status Enables a user to either Enable or Disable the security profile on the device. By default, it
is enabled.
Network Secret Enter the WORP Protocol Secret Key, ranging from 6 to 32 characters, used for
authenticating a SU with a BSU, and an End Point B with End Point A. The network secret
should be same for a BSU and SU. Similarly, the network secret should be same for an End Point
A and an End Point B.
:
A maximum of 8 security profiles can be created.
A Quick Bridge support AES-CCM encryption type only.
Special characters like - = \ " ' ? / space are not allowed while configuring the keys.
All four Keys (Key1, Key2, Key3, Key4) must be of same length and same type, that is, all four Keys must
be either ASCII Characters or Hexadecimal digits.
Transmit Key can be any one of the four keys, provided all the four keys are same in a SU and BSU, or End
Point devices.
WEP and TKIP Encryption Types are supported only in legacy Modes.
The encryption mode should not be selected as AES-CCM while the device is interoperating with legacy
Tsunami® MP.11 family devices which include 954-R, 2454-R, 4954-R, 5054-Series, and 5012-Series.
After configuring the required parameters, click Add and then COMMIT.
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Sample Security Profile Configuration
End Point A End Point B
Profile Name WORP Security WORP Security
Encryption Type AES-CCM AES-CCM
Key 1234567890abcdef1234567890abcdef 1234567890abcdef1234567890abcdef
(32 Hexadecimal digits) (32 Hexadecimal digits)
or or
publicpublic1234 publicpublic1234
(16 ASCII Characters) (16 ASCII Characters)
Entry Status Enable Enable
Network Secret public public
5.5.1.2 Editing an existing Security Profile
To edit the parameters of the existing security profiles, click Edit icon in the Wireless Security Configuration screen.
The Wireless Security Edit Row screen appears:
Figure 5-22 Wireless Security Edit Row
Edit the required parameters and click OK and then COMMIT.
5.5.2 RADIUS
:Applicable only to a BSU and End Point A devices.
The RADIUS tab allows you to configure a RADIUS authentication server on a BSU/End Point A that remotely authenticates a SU or
an End Point B while registering with a BSU or an End Point A respectively. These servers are also used to configure few features
(VLAN and QoS) on a SU.
A RADIUS server profile consists of a Primary and a Secondary RADIUS server that can act as Authentication servers.
Configuration of Secondary Authentication Server is optional. The RADIUS server is applicable only when it is enabled in the
WORP Configuration page.
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To configure the RADIUS Server profile, navigate to ADVANCED CONFIGURATION > Security > RADIUS. The following
RADIUS Server Profile screen appears:
Figure 5-23 Configuring RADIUS Server Profile
Tabulated below is the table which explains RADIUS Server parameters and the method to configure the configurable
parameter(s):
Parameter Description
Profile Name A name that represents the Radius Server profile. By default, it is Default Radius.
Max Retransmissions Represents the maximum number of times an authentication request may be retransmitted
to the configured RADIUS server. The range is 0 to 3. By default, it is set to 3.
Message Response Represents the response time (in seconds) for which that the BSU/End Point A should wait
Time for the RADIUS server to respond to a request. The range is 3 to 9 seconds. By default, it is
set to 3 seconds.
Re Authentication Represents the time period after which the RADIUS server should re-authenticate a SU or
Period an End Point B. The re-authenticate period ranges from 900 to 65535 seconds. By default,
the re-authentication period is set to 0.
Entry status A read-only parameter which displays the status of the RADIUS server profile as Enabled.
The Entry status cannot be disabled or edited.
Server Type For better accessibility and reliability, you can configure two RADIUS servers:
1. Primary RADIUS Server
2. Secondary RADIUS Server
The secondary RADIUS server serves as backup when the primary RADIUS server is down or not
reachable.
IP Address Represents the IP address of the primary and secondary RADIUS servers.
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Parameter Description
Server Port Specifies the port number that is used by the BSU/End Point A and the RADIUS server to
communicate. By default, RADIUS Authentication Server communicates on port 1812.
Shared Secret Specifies the password shared by the BSU/End Point A and the RADIUS server to
communicate. The default password is public.
Care should be taken to configure same Shared Secret on both BSU/End Point A and
RADIUS Server, otherwise no communication is possible between BSU/End Point A and
RADIUS server.
Entry Status You can either enable or disable the configured RADIUS servers. By default, the Primary
RADIUS server is enabled and the secondary RADIUS server is disabled.
After configuring the required parameters, click OK and then COMMIT.
Listed below are the points to be noted before configuring the Radius Server Profile,
1. Message Response Time should always be less than WORP Registration Timeout.
2. If Max Retransmissions is configured as Zero, then retransmissions does not occur.
3. The value of Max Retransmissions multiplied by Message Response Time should be less than WORP
Registration Timeout value.
5.5.3 MAC ACL
:Applicable only to a BSU and End Point A mode.
The MAC ACL feature allows only the authenticated SUs/End Point Bs to access the wireless network. Please note that MAC
Authentication is supported only on the wireless interface. The MAC ACL feature is applicable only when it is enabled in the
WORP Configuration page.
To configure the MAC Access Control List, navigate to ADVANCED CONFIGURATION > Security > MAC ACL. The MAC
Access Control screen appears:
Figure 5-24 MAC Access Control Configuration
Select the Operation Type as either Allow or Deny.
Allow: Allows only the SUs/End Point Bs configured in the MAC Access Control Table to access the wireless network.
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Deny: Does not allow the SUs/End Point B devices configured in the MAC Access Control Table to access the wireless
network.
Click OK, if you have changed the Operation Type parameters.
5.5.3.1 Add SUs/End Point B to MAC Access Control Table
To add entries to MAC Access Control table, click Add in the MAC Access Control screen. The MAC ACL Add Row screen
appears:
Figure 5-25 MAC ACL Add Row
1. Type the MAC Address of the SU/End Point B.
2. Add comments, if any.
3. Select the Entry Status as either Enable or Disable.
4. Next, click Add.
:
• The maximum number of SUs/End Point Bs that can be added to the MAC ACL table is 250.
• Either RADIUS MAC or Local MAC can be enabled at one time.
5.5.3.2 Edit the existing SUs/End Point B from MAC Access Control Table
To edit the existing SUs/End Point B from MAC Access Control Table, edit parameters from the MAC Access Control Table in MAC
Access Control screen and click OK.
5.6 Quality of Service (QoS)
The Quality of Service (QoS) feature is based on the 802.16 standard and defines the classes, service flows, and packet
identification rules for specific types of traffic. The main priority of QoS is to guarantee a reliable and adequate transmission quality
for all types of traffic under conditions of high congestion and bandwidth over-subscription.
There are already several pre-defined QoS classes, SFCs and PIRs available that you may choose from which cover the most
common types of traffic. If you want to configure something else, you start building the hierarchy of a QoS class by defining PIRs;
you define the QoS class by associating those PIRs to relevant SFCs with priorities to each PIR within each SFC. Qos can be applied
on standard 802.3 ethernet frames as well as PPPoE encapsulated frames.
5.6.1 QoS Concepts and Definitions
QoS feature is applicable for BSU or End Point A only. You may define different classes of service on a BSU or End Point A that
can then be assigned to the SU or End Point B that is associated, or that may get associated, with that BSU or End Point A.
You can create, edit, and delete classes of service that are specified below in the following hierarchy of parameters:
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Packet Identification Rule (PIR) - up to 64 rules, including 18 predefined rules
Service Flow class (SFC) - up to 32 SFCs, including 8 predefined SFCs; up to 8 PIRs may be associated per SFC
Class List - Priority for each rule within each SF class - 0 to 255, with 0 being lowest priority
QoS class - up to 8 QoS classes, including 5 predefined classes; up to 8 SFCs may be associated per QoS class
5.6.1.1 Packet Identification Rule (PIR)
A Packet Identification Rule is a combination of parameters that specifies what type of traffic is allowed or not allowed. You can
create a maximum of 64 different PIRs, including 18 predefined PIRs. Also, you can create, edit, and delete PIRs that contain
none, one, or more of the following classification fields:
• Rule Name
IP ToS (Layer 3 QoS identification)
802.1p tag (layer 2 QoS identification)
IP Protocol List containing up to 4 IP protocols
• VLAN ID
• PPPoE Encapsulation
Ether Type (Ethernet Protocol identification)
Up to 4 TCP/UDP Source port ranges
Up to 4 TCP/UDP Destination port ranges
Up to 4 pairs of Source IP address + Mask
Up to 4 pairs of Destination IP address + Mask
Up to 4 source MAC addresses + Mask
Up to 4 destination MAC addresses + Mask
: IP Address, TCP/UDP Port, MAC Address need to be configured separately and associate those classification in PIR
details if required.
A good example is provided by the 18 predefined PIRs. Note that these rules help identify specific traffic types:
1. All - No classification fields, all traffic matches
2. L2 Multicast
a. Ethernet Destination (dest = 0x010000000000, mask = 0x010000000000)
3. L2 Broadcast
a. Ethernet Destination (dest = 0xffffffffffff, mask = 0xffffffffffff)
4. Cisco VoIP UL
a. TCP/UDP Source Port Range (16,000-33,000)
b. IP Protocol List (17 = UDP)
5. Vonage VoIP UL
a. TCP/UDP Source Port Range (5060-5061, 10000-20000)
b. IP Protocol List (17 = UDP)
6. Cisco VoIP DL
a. TCP/UDP Destination Port Range (16,000-33,000)
b. IP Protocol List (17 = UDP)
7. Vonage VoIP DL
a. TCP/UDP Destination Port Range (5060-5061, 10000-20000)
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b. IP Protocol List (17 = UDP)
8. TCP
a. IP Protocol List (6)
9. UDP
a. IP Protocol List (17)
10. PPPoE Control
a. Ether Type Rule (Ether Type = DIX-Snap, Ether Value = 0x8863)
11. PPPoE Data
a. Ether Type Rule (Ether Type = DIX-Snap, Ether Value = 0x8864)
12. IP
a. Ether Type Rule (Ether Type = DIX-Snap, Ether Value = 0x0800)
13. ARP
a. Ether Type Rule (Ether Type = DIX-Snap, Ether Value = 0x0806)
14. Expedited Forwarding
a. IP TOS/DSCP (ToS low=45(0x2D), ToS high=45(0x2D), ToS mask = 63(0x3F))
15. Streaming Video (IP/TV)
a. IP TOS/DSCP (ToS low=13(0x0D), ToS high=13(0x0D), ToS mask = 63(0x3F))
16. 802.1p BE
a. Ethernet Priority (low=0, high=0) (this is the equivalent of the User Priority value in the TCI (Tag Control
Information) field of a VLAN tag)
17. 802.1p Voice
a. Ethernet Priority (ToS low=6, ToS high=6) (this is the equivalent of the User Priority value in the TCI (Tag Control
Information) field of a VLAN tag)
18. 802.1p Video
a. Ethernet Priority (ToS low=5, ToS high=5) (this is the equivalent of the User Priority value in the TCI (Tag Control
Information) field of a VLAN tag)
: Two different VoIP rule names have been defined for each direction of traffic, Uplink (UL) and Downlink (DL), (index
numbers 4 to 7). This has been done to distinguish the proprietary nature of the Cisco VoIP implementation as
opposed to the more standard Session Initiation Protocol (SIP) signaling found, for example, in the Vonage-type VoIP
service.
5.6.1.2 Service Flow Class (SFC)
A Service Flow class defines a set of parameters that determines how a stream of application data that matches a certain
classification profile will be handled. You can create up to 32 different SFCs, including 8 predefined SFCs. Also, you can create,
edit, and delete SFCs that contain the following parameters and values:
• Service flow name
Scheduling type - Best Effort (BE); Real-Time Polling Service (RTPS)
Service Flow Direction - Downlink (DL: traffic from End Point ABSU to End Point BSU); Uplink (UL: traffic from SU/End
Point B to BSU/End Point A)
Maximum sustained data rate (or Maximum Information Rate (MIR) - specified in units of 1 Kbps from 8 Kbps up to
the maximum rate specified in the license.
Minimum reserved traffic rate (or Committed Information Rate (CIR) - specified in units of 1 Kbps from 0 Kbps up to
the maximum rate specified in the license.
Maximum Latency - specified in increments of 1 ms steps from a minimum of 5 ms up to a maximum of 100 ms
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Tolerable Jitter - specified in increments of 1 ms steps from a minimum of 0 ms up to the Maximum Latency (in ms)
Traffic priority - zero (0) to seven (7), 0 being the lowest, 7 being the highest
Maximum number of data messages in a burst - one (1) to sixteen (16), which affects the percentage of the maximum
throughput of the system
Entry Status - Enable, Disable, and Delete
: Note that traffic priority refers to the prioritization of this specific Service Flow.
The device tries to deliver the packets within the specified latency and jitter requirements, relative to the moment of receiving the
packets in the device. For delay-sensitive traffic, the jitter must be equal to or less than the latency. A packet is buffered until an
interval of time equal to the difference between Latency and jitter (Latency - Jitter) has elapsed. The device will attempt to
deliver the packet within a time window starting at (Latency - Jitter) until the maximum Latency time is reached. If the SFC’s
scheduling type is real-time polling (RTPS), and the packet is not delivered by that time, it will be discarded. This can lead to loss of
packets without reaching the maximum throughput of the wireless link. For example, when the packets arrive in bursts on the
Ethernet interface and the wireless interface is momentarily maxed out, then the packets at the “end” of the burst may be timed out
before they can be sent.
Users can set up their own traffic characteristics (MIR, CIR, latency, jitter, etc.) per service flow class to meet their unique
requirements. A good example is provided by the 8 predefined SFCs:
1. UL-Unlimited BE
a. Scheduling Type = Best Effort
b. Service Flow Direction = Uplink
c. Entry Status = Enable
d. Maximum Sustained Data Rate = 102400 Mbps e. Traffic Priority = 0
2. DL-Unlimited BE (same as UL-Unlimited BE, except Service Flow Direction = Downlink)
3. DL-L2 Broadcast BE (same as UL-Unlimited BE, except Service Flow Direction = Downlink)
4. UL-G711 20 ms VoIP RTPS
a. Schedule type = RTPS (Real time Polling Service)
b. Service Flow Direction = Uplink
c. Entry Status = Enable
d. Maximum Sustained Data Rate = 88 Kbps
e. Minimum Reserved Traffic Rate = 88 Kbps
f.
Maximum Latency = 20 milliseconds g. Traffic Priority = 1
5. DL-G711 20 ms VoIP rtPS (same as UL-G711 20ms VoIP rtPS, except Service Flow Direction = Downlink)
6. UL-G729 20 ms VoIP rtPS (same as UL-G711 20ms VoIP rtPS, except Maximum Sustained Data Rate and Committed
Information rate = 66 Kbps)
7. DL-G729 20 ms VoIP rtPS (same as UL-G729 20ms VoIP rtPS, except Service Flow Direction = Downlink)
8. DL-2Mbps Video
a. Schedule type = Real time Polling
b. Service Flow Direction = Downlink
c. Initialization State = Active
d. Maximum Sustained Data Rate = 2 Mbps
e. Minimum Reserved Traffic Rate = 2 Mbps
f. Maximum Latency = 20 milliseconds
g. Traffic Priority = 1
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Note that two different VoIP Service Flow classes for each direction of traffic have been defined (index numbers 4 to 7) which follow
the ITU-T standard nomenclatures: G.711 refers to a type of audio companding and encoding that produces a 64 Kbps bitstream,
suitable for all types of audio signals. G.729 is appropriate for voice and VoIP applications, but cannot transport music or fax
tones reliably. This type of companding and encoding produces a bitstream between 6.4 and 11.8 Kbps (typically 8 Kbps) according
to the quality of voice transport that is desired.
5.6.1.3 QoS Class
A QoS class is defined by a set of parameters that includes the PIRs and SFCs that were previously configured. You can create up to
eight different QoS classes, including five predefined QoS classes. Up to eight SF classes can be associated to each QoS class, and
up to eight PIRs can be associated to each SF class. For example, a QoS class called “G711 VoIP” may include the following SFCs:
“UL-G711 20 ms VoIP rtPS” and “DL-G711 20 ms VoIP rtPS”.
In turn, the SFC named “UL-G711 20 ms VoIP rtPS” may include the following rules: “Cisco VoIP UL” and “Vonage VoIP UL”. You
can create, edit, and delete QoS classes that contain the following parameters:
QoS class name
Service Flow (SF) class name list per QoS class (up to eight SF classes can be associated to each QoS class)
Packet Identification Rule (PIR) list per SF class (up to eight PIRs can be associated to each SF class)
Priority per rule which defines the order of execution of PIRs during packet identification process. The PIR priority is a
number in the range 0-255, with priority 255 being executed first, and priority 0 being executed last. The PIR priority
is defined within a QoS class and can be different for the same PIR in some other QoS class. If all PIRs within one QoS
class have the same priority, the order of execution of PIR rules will be defined by the order of definition of SFCs, and
by the order of definition of PIRs in each SFC, within that QoS class.
A good example of this hierarchy is provided by the five predefined QoS classes:
1. Unlimited Best Effort
a. SF class: UL-Unlimited BE
- PIR: All; PIR Priority: 0
b. SF class: DL-Unlimited BE
- PIR: All; PIR Priority: 0
2. L2 Broadcast Best Effort
a. SF class: DL-L2 Broadcast BE
- PIR: L2 Broadcast; PIR Priority: 0
3. G711 VoIP
a. SF class: UL-G711 20 ms VoIP rtPS
- PIR: Vonage VoIP UL; PIR Priority: 1
- PIR: Cisco VoIP UL; PIR Priority: 1
b. SF class: DL-G711 20 ms VoIP rtPS
- PIR: Vonage VoIP DL; PIR Priority: 1
- PIR: Cisco VoIP DL; PIR Priority: 1
4. G729 VoIP
a. SF class: UL-G729 20 ms VoIP rtPS
- PIR: Vonage VoIP UL; PIR Priority: 1
- PIR: Cisco VoIP UL; PIR Priority: 1
b. SF class: DL-G729 20 ms VoIP rtPS
- PIR: Vonage VoIP DL; PIR Priority: 1
- PIR: Cisco VoIP DL; PIR Priority: 1
5. 2Mbps Video
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a. SF class: DL-2Mbps Video
- PIR: Streaming Video (IP/TV); PIR Priority: 1
5.6.2 QoS Configuration
There are several pre-defined QoS classes, SFCs, and PIRs available that cover the most common types of traffic. If you want to
configure something else, build the hierarchy of a QoS class as follows:
1. Define PIR MAC Address, IP Address and TCP/UDP Port Entries.
2. Define PIRs and specify packet classification rules, associate MAC Address/IP Address/TCP-UDP Port Entries if required.
3. Define SFCs
4. Define QoS Class by associating PIRs with relevant SFC.
5. Assign priorities to each PIR within each SFC.
For detailed instructions on configuring a management station (a single station used for managing an entire network), refer to QoS
Configuration for a Management Station.
QoS PIR MAC Address Configuration
1. Navigate to ADVANCED CONFIGURATION > QoS > PIR List > MAC Address Entries, the QoS PIR MAC Address
Entries screen appears:
2. Three predefined MAC Address entries are displayed in this page. You can configure a maximum of 256 entries. MAC
Address and Mask combination should be unique. This MAC Address entry can be referred in the PIR Rule’s Source or
Destination MAC Address Classification. MAC Entry referred by any PIR rule cannot be deleted.
Figure 5-26 QoS PIR MAC Address Entries
3. Click OK.
To Add a New PIR MAC Address Entry,
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List > MAC Address Entries, the QoS PIR MAC Address
Entries screen appears.
b. Click Add on the QoS PIR MAC Address Entries screen to add a new entry. The following screen appears for
configuring the MAC Entry Details.
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Figure 5-27 QoS PIR MAC Address Add Entry
c. Provide the MAC Address, Mask, Comment, Entry Status details and click Add. Comment field can be used to identify
when this particular entry is referred in PIR Rule/QoS Class.
The bit that is enabled in the “MAC Mask” configuration, the corresponding bit’s value in the “MAC Address” configuration
should match with the same bit of the incoming traffic’s MAC Address (other bits of the incoming traffic are ignored). Then it
is considered as matching traffic and the rest are unmatched traffic. The following is explained with the help of an example:
1. Creating Matching profile for single MAC address
To apply QoS classification for traffic which is originated / destined from / to a Device only. MAC
Address: 00:20:A6:00:00:01
MAC Mask
: FF:FF:FF:FF:FF:FF
In this example, all bits in the MAC Mask are enabled, so incoming traffic’s MAC address should exactly match with
specified configured MAC Address (that is, 00:20:A6:00:00:01). Other traffics are considered as non-matching traffic.
2. Creating Matching profile for all MAC Address
MAC Address: 00:00:00:00:00:00
MAC Mask: 00:00:00:00:00:00
In this example, all bits in the MAC Mask are disabled, so any traffic is considered as matching traffic.
3. Creating Matching Profile for Broadcast MAC Address
MAC Address: FF:FF:FF:FF:FF:FF
MAC Mask: FF:FF:FF:FF:FF:FF
4. Creating Matching Profile for all Multicast MAC Address
MAC Address: 01:00:00:00:00:00
MAC Mask: 01:00:00:00:00:00
5. Creating Matching Profile for range of MAC Address (00:20:A6:00:00:01 to 00:20:A6:00:00:FF)
MAC Address: 00:20:A6:00:00:00
MAC Mask: FF:FF:FF:FF:FF:00
QoS PIR IP Address Configuration
1. Navigate to ADVANCED CONFIGURATION > QoS > PIR List > IP Address Entries, the QoS PIR IP Address Entries
screen appears. A single predefined IP Address entry is displayed. You can configure a maximum of 256 entries. IP
Address, Subnet Mask combination should be unique. This IP Address entry can be referred in the PIR Rule’s Source or
Destination IP Address Classification. IP Address Entry referred by any PIR rule cannot be deleted.
2. Click OK.
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Figure 5-28 QoS PIR IP Address Entries
To Add a New PIR IP Address Entry,
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List > IP Address Entries. The QoS PIR IP Address
Entries screen appears
b. Click Add on the QoS PIR IP Address Entries screen to add a new entry. The following screen appears for
configuring the IP Address Entry Details.
Figure 5-29 QoS PIR IP Address Add Entry
c. Provide the IP Address, Subnet Mask, Comment, Entry Status details and click Add. Comment field can be used by
the user to identify when this particular entry is referred in PIR Rule or QoS Class.
QoS PIR TCP/UDP Port Configuration
1. Navigate to ADVANCED CONFIGURATION > QoS > PIR List > TCP/UDP Port Entries. The QoS PIR TCP/UDP Port
Entries screen appears. Three predefined TCP/UDP Port Entries are displayed. You can configure a maximum of 256
entries. Start Port, End Port combination should be unique. This TCP/UDP Port entry can be referred in the PIR Rule’s
Source or Destination TCP/UDP Port Classification. TCP/UDP Port Entry referred by any PIR rule can not be deleted.
2. Click OK.
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Figure 5-30 QoS PIR TCP/UDP Port Entries
To Add a New PIR TCP/UDP Port Entry,
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List > TCP/UDP Port Entries. The QoS PIR TCP/UDP
Port Entries screen appears.
b. Click Add on the QoS PIR TCP/UDP Port Entries screen to add a new entry. The following screen appears for
configuring the IP Address entry details.
Figure 5-31 QoS PIR TCP/UDP Port Add Entry
c. Provide the Start Port, End Port, Entry Status details and click Add. Comment field can be used to identify when
this particular entry is referred in PIR Rule or QoS Class.
5.6.2.1 QoS PIR Configuration
1. Navigate to ADVANCED CONFIGURATION > QoS > PIR List. The QoS PIR Entries screen appears. 18 predefined
PIR Rules are displayed in this page. You can configure a maximum of 64 entries. PIR Rule Name should be unique.
This PIR Rule can be referred in the QoS Class’s Service Flow Details. PIR rule referred by any QoS Class cannot be
deleted.
2. Click OK.
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Figure 5-32 QoS PIR Entries
To Add a New PIR Rule,
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List. The QoS PIR Entries screen appears.
b. Click Add on the QoS PIR Entries screen to add a new entry. The following screen appears for configuring the
New PIR Entry.
Figure 5-33 QoS PIR Add Entry
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c. Provide the PIR Name, Entry Status details and click Add.
PIR Rule Clarification Details
1. Navigate to ADVANCED CONFIGURATION > QoS > PIR List and click Details for editing a particular PIR Rule.
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Figure 5-34 QoS PIR Edit Entry
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Parameter Description
Rule Name This parameter specifies the Name of the Packet Identification Rule (PIR) and can have a
length of 1-32 characters.
ToS Rule This parameter is used to enable or disable a TOS rule. Enter the values for the following to
specify the ToS-related configuration:
• ToS Low
• ToS High
• ToS Mask
Ether Priority Rule This parameters is used to enable or disable 802.1p priority rule. Enter the values for the
following to specify 802.1p priority configuration:
• Priority Low
• Priority High
VLAN Rule This parameters allows to enable or disable VLAN rule. Enter the VLAN ID when the VLAN
rule is enabled.
PPPoE Encapsulation This parameter is used to classify PPPoE traffic.
If you Enable/disable the PPPoE Configuration, it will automatically disable the
Ether Type Rule. User can configure it again by enabling Ether Type Rule.
When PPPoE Encapsulation is enabled, incoming packet will be checked again
Ether value “0x8864” and look for PPPoE Protocol Id value “0x0021”(IP Protocol)
by default. User can modify the PPPoE Protocol Id. All other classification rules
which are specified in the PIR rule will work only if the PPPoE Protocol Id is
“0021”.
Ether Value is not valid when PPPoE Encapsulation is enabled.
Ether Type Rule This parameters is used to enable or disable Ether Type rule. Enter the values for the
following to specify the Ether Type rule related configuration:
• Ether Type
PPPoE Protocol Id
• Ether Value
:
PPPoE Protocol Id is not valid if PPPoE Encapsulation is disabled.
Ether Value is not valid if PPPoE Encapsulation is enabled.
Adding Protocol ID
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List. Click Details. The Qos PIR Edit Entry screen
appears.
b. Navigate to Protocol Id Entries tab and then click Add to add a new Protocol entry. The following screen
appears.
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Figure 5-35 QoS PIR Protocol ID
c. Enter the details and click Add. For deleting an entry, click Delete for the corresponding entry in PIR Details
screen.
Adding TCP/UDP Source Port Numbers
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List. Click Details. The Qos PIR Edit Entry screen
appears.
b. Navigate to TCP/UDP Source Port Entries tab and then click Add to add a new entry. The following screen
appears.
Figure 5-36 QoS PIR TCP/UDP Source Port Add Entry
c. All the Entries present in the PIR TCP/UDP Port Entries are displayed in the TCP/UDP Port Entry Table. Select the
appropriate radio button and click Add. When an entry is added for the specific PIR, the entry gets displayed in
the existing TCP/UDP Port Entries table. For deleting an entry, click Delete for the corresponding entry in the PIR
Details page.
Adding TCP/UDP Destination Port Numbers
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List. Click Details. The Qos PIR Edit Entry screen
appears.
b. Navigate to TCP/UDP Destination Port Entries tab and then click Add to add a new entry. The following screen
appears.
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Figure 5-37 QoS PIR TCP/UDP Destination Port Add Entry
c. All the entries present in the PIR TCP/UDP Port Entries are displayed in the TCP/UDP Port Entry Table. Select the
appropriate radio button and click Add. When an entry is added for a specific PIR, it gets displayed in the existing
TCP/UDP Port Entries table. For deleting an entry, click Delete for the corresponding entry in the PIR Details page.
Adding Source IP Address
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List. Click Details. The Qos PIR Edit Entry screen
appears.
b. Navigate to Source IP Address Entries tab and then click Add to add a new entry. The following screen appears:
Figure 5-38 QoS PIR Source IP Address Add Entry
c. All the entries present in the PIR IP Address Entries are displayed in the IP Address Entry Table. Select the
appropriate radio button and click Add. After adding the entry for this specific PIR, it is displayed in the Existing IP
Address Entries table. For deleting an entry, click Delete for the corresponding entry in the PIR Details page.
Adding Destination IP Address
a. Navigate to ADVANCED CONFIGURATION > QoS > PIR List. Click Details. The Qos PIR Edit Entry screen
appears.
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b. Navigate to Destination IP Address Entries tab and then click Add to add a new entry. The following screen
appears.
Figure 5-39 QoS PIR Destination IP Address Add Entry
c. All the entries present in the PIR IP Address Entries are displayed in the IP Address Entry Table. Select the
appropriate radio button and click Add. After adding the entry for this specific PIR, it is displayed in the Existing IP
Address Entries table. For deleting an entry, click Delete for the corresponding entry in the PIR Details page.
Adding Source MAC Address
a. Click Add to add a new entry. The following screen appears.
Figure 5-40 QoS PIR Source MAC address Add Entry
b. All the entries present in the PIR MAC Address Entries are displayed in the MAC Address Entry Table. Select the
appropriate radio button and click Add. After adding the entry for this specific PIR, it is displayed in the Existing
MAC Address Entries table. For deleting an entry, click Delete for the corresponding entry in the PIR Details page.
Adding Destination MAC Address
a. Click Add to add a new entry. The following screen appears.
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Figure 5-41 QoS PIR Destination MAC address Add Entry
b. All the entries present in the PIR MAC Address Entries are displayed in the MAC Address Entry Table. Select the
appropriate radio button and click Add. After adding the entry for this specific PIR, it is displayed in the Existing
MAC Address Entries table. For deleting an entry, click Delete for the corresponding entry in the PIR Details page.
5.6.2.2 QoS Service Flow Configuration (SFC)
1. Click ADVANCED CONFIGURATION > QoS > SFC List. Eight predefined SFCs are displayed in this page. This table
allows the user to configure maximum of 32 entries. Service Flow Name should be unique. This SFC can be referred in
the QoS Class’ Details. SFC referred by any QoS Class cannot be deleted.
Figure 5-42 QoS Service Flow Entries
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Adding a New Service Flow (SFC):
a. Click Add to add new entry. The following screen appears for configuring the New PIR Entry.
Figure 5-43 QoS Service Flow Add Entry
2. Specify details for the Service Flow Name, Scheduler Type, Traffic Direction, MIR, CIR, Max Latency, Tolerable Jitter,
Traffic Priority, Max Messages in Burst and Entry Status.
3. Click
Add
.
Parameter Description
Service Flow Name Specifies the Name of the Service Flow. It can be of length 1-32 characters. T
: Special characters - = \ \"\ ' ? \\ / space are not allowed.
Scheduler Type Specifies the Scheduler methods to be used. Scheduler type supports BE (Best Effort), RTPS
(Real-Time Polling Service).
Traffic Direction Specifies the Direction (Downlink or Uplink) of the traffic in which the configuration has to
be matched.
MIR (Maximum Specifies the maximum bandwidth allowed for this Service Flow. This value ranges from 8
Information Rate) kbps to maximum value specified in the license file.
CIR (Committed Specifies the reserved bandwidth allowed for this Service Flow. This value ranges from 0 to
Information Rate) maximum value specified in the license file.
Max Latency Specifies the Latency value. This value ranges from 5 to 100 ms.
Tolerable Jitter Specifies the Jitter value. This value ranges from 0 to 100 ms.
Traffic Priority Specifies the priority of the Service flow when multiple Service flows are assigned to single
QoS Class. This value ranges from 0 to 7.
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Parameter Description
Max Messages in Specifies the maximum number of messages that can be sent in a burst. This value ranges
Burst from 1 to 16.
: Reducing the number of messages impacts the throughput.
Entry Status Specifies the Service Flow status.
5.6.2.3 QoS Class Configuration
1. Click ADVANCED CONFIGURATION > QoS > Class List. Five predefined QoS Classes are displayed in this page.
You can configure maximum 8 entries. QoS Class Name should be unique. This QoS Class can be referred in the
Default QoS Class or L2 Broadcast QoS Class. Any QoS Class referred cannot be deleted.
2. Click OK.
Figure 5-44 QoS Class Details
Parameter Description
Default QoS Class This parameter specifies the QoS Class profile that needs to be associated with an SU or
End Point B which is not listed in the QoS SU or End Point B List but connected.
L2 Broadcast QoS This parameter specifies WORP to use this particular class for WORP broadcast facility.
Class L2 Broadcast QoS Class is valid only for Downlink Direction. QoS Class assigned to this
profile should have at least one Downlink SFC.
4. Add a New QoS Class:
a. Click Add to add new entry. The following screen appears for configuring the New Class Entry.
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Figure 5-45 QoS Class Add Entry
b. Specify the QoS Class Name, Service Flow Name PIR Rule Name Priority and Entry Status and click Add.
Parameter Description
Class Name Specifies the Name of the QoS Class. This name length can range from 1 to 32 characters.
: Special characters - = \ \"\ ' ? \\ / space are not allowed.
Service Flow Name Specifies the Service Flow to be associated with the QoS Class. Select one of the possible
SFCs that have been previously configured in the SFC List.
PIR Rule Name Specifies the PIR Rule need to be associated with this Service Flow. Select one of the
possible PIRs that have been previously configured in the PIR List.
Priority Specifies priority or order of execution of PIRs during packet identification process.
The PIR priority is a number that can range from 0-255, with priority 255 being executed
first, and priority 0 being executed last. The PIR priority is defined within a QoS class, and
can be different for the same PIR in some other QoS class. If all PIRs within one QoS class
have the same priority, the order of execution of PIR rules will be defined by the order of
definition of SFCs, and by the order of definition of PIRs in each SFC, within that QoS class.
Entry Status Specifies the status of the QoS Class as enable/disable.
Adding Service Flows in QoS Class
1. Click on the corresponding Details of the QoS Class for adding more Service Flows. Each QoS Class can have
maximum 8 Service Flows. At least there should be one service flow per QoS Class. The following screen is displayed to
configure the new SFC entry inside the QoS Class.
2. Click OK.
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Figure 5-46 QoS Class Service Flow Details
3. Click Add. The following screen appears for association of the new SFC in this QoS Class.
Figure 5-47 QoS Class Service Flow Add Entry
4. Specify the Service Flow Name, PIR Rule Name, Priority and Entry Status and click Add to add a new entry.
Adding PIR in QoS Class
1. Click on the corresponding Details provided in the Service Flow of a particular QoS Class. Maximum 8 PIR rules can be
associated per SFC of an QoS Class. At least there should be one PIR per SFC of an QoS Class. The following screen
appears to associate the new PIR entry inside an SFC of an QoS Class.
2. Click OK.
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Figure 5-48 QoS Class PIR Details
3. Click Add. The following screen appears for association of the new PIR rule in an SFC already associated in an QoS
Class.
Figure 5-49 QoS Class PIR Add Entry
4. Specify the PIR Rule Name, Priority and Entry Status and click Add to add a new entry.
5.6.2.4 QoS SU or End Point B List Configuration
1. Navigate to ADVANCED CONFIGURATION > QoS > SU or End Point B List. By default, the table does not have any
entry. User can configure the Wireless MAC Address of the SU or End Point B here and associate the QoS Class that is
to be used for that particular SU or End Point B.
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Figure 5-50 QoS SU or End Point B List Entries
2. If an SU or End Point B is not in the list and is associated, the default QoS class configuration is applied.
Adding a New SU or End Point B
1. Navigate to ADVANCED CONFIGURATION > QoS > SU or End Point B List. The QoS SU or End Point B Entries
screen appears.
2. Click Add to add a new entry. The following QoS SU or End Point B Table Add Row screen appears.
Figure 5-51 QoS SU or End Point B Table Add Row
3. Specify the Wireless Mac Address of the SU or End Point B, Class Name, Comment and Entry Status and click Add.
Previously defined Class Name can be viewed in the Class Name drop-down box.
:
• QoS SU Entries configuration can be done locally or through a RADIUS Server.
• Local configuration takes priority over RADIUS Based QoS configuration.
• RADIUS Configuration is applicable only when the RADIUS MAC ACL Status is enabled on the BSU.
• When the link is down, the RADIUS configuration is lost.
5.6.3 QoS Configuration for a Management Station
As stated previously, the QoS feature enables prioritization of traffic and allocation of the available bandwidth based on that
prioritization. The system is designed in such a way that higher priority traffic preempts lower priority traffic, keeping lower
priority traffic on hold until higher priority traffic finishes. This mechanism ensures that the available bandwidth is always
given first to the higher priority traffic; if all the bandwidth is not consumed, the remaining bandwidth is given to the lower
priority traffic.
If QoS is not properly configured, the system becomes difficult to access in heavily loaded networks. One of the side effects of this
misconfiguration is ping time-out, which is usually interpreted as a disconnection of the pinged node. However, with the correct
QoS configuration, every node in the network can be reached at any point of time.
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Advanced Configuration
The following configuration instructions explain how to configure the system so that configuration parameters can always be
changed, and ping requests and responses get higher priority in order to show the actual connectivity of the pinged node.
The configuration suggested here assumes that the whole network is managed from a single work station, called the
management station. This station can be connected anywhere in the network, and can be recognized by either its IP address, or by
its MAC Ethernet address if the network uses DHCP.
In this configuration, any traffic coming from or going to the management station is treated as management traffic.
Therefore, the management station should be used only for configuration of the Quick Bridge nodes in the network and to check
connectivity of the nodes, but it should not be used for any throughput measurements.
: While this QoS configuration is used, the TCP or UDP throughput should not be measured from the
management station.
Step 1: Add Packet Identification Rules
To recognize management traffic, the system needs to recognize ARP requests or responses and any traffic coming from or going
to the management station.
A. Confirm the Attributes of the Existing ARP PIR
The default QoS configuration contains the PIR called “ARP,” which recognizes ARP requests or responses by the protocol
number 0x0806 in the Ethernet Type field of the Ethernet packet. Confirm that the ARP PIR parameters are correct, as
follows:
1. Navigate to ADVANCED CONFIGURATION > QoS > PIR list.
2. Click Details corresponding to the ARP PIR.
3. Confirm the following attributes:
Rule Name: ARP
• Status: Enable
Enable Ether Type Rule: Yes (checkbox is selected)
— Ether Type: DIX-Snap
— Ether Value: 08:06(hex)
B. Create New PIRs to Recognize Management Traffic
To recognize the traffic coming from or going to the management station, the system must contain two additional PIRs: one with
either the destination IP address or the destination MAC address equal to the management station’s IP or MAC address, and
another with either the source IP address or the source MAC address equal to the management station’s IP or MAC address.
The following examples explain PIR rules based on the IP Address of the Management Station.
1. Navigate to ADVANCED CONFIGURATION > QoS > PIR list > IP Address Entries.
2. Click Add. The screen for adding the Management Station's IP Address appears. Enter proper IP Address, Subnet
mask as 255.255.255.255, Entry status as Enable and then click Add. This adds the Management Station’s IP details
in the IP Address Entries of the PIR List.
3. Navigate to ADVANCED CONFIGURATION > QoS > PIR list.
4. Add PIR Rule for Source IP Address.
a. Click Add. The screen for adding the New PIR Rule appears. Enter the PIR Rule Name as “Management Station
SRC IP”, Entry status as Enable and click Add. This adds the new PIR rule in the PIR List. By default, no
classification rules are applied.
b. Navigate to ADVANCED CONFIGURATION > QoS > PIR list. Click Details for “Management Station SRC IP” PIR
rule. This displays all the classification rule details for this particular rule.
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c. Click Add that corresponds to Source IP Address Entries. This displays a screen for referring the Management
Station’s IP Address. New Entry Table displays all the IP Address Entries of the PIR List. Select the option button
corresponding to the Management Station and then click Add. This adds the IP Address of the Management
Station to the Existing Entries. Click Back and the new entry appears in the Source IP Address Entries Table.
5. Add PIR Rule for Destination IP Address.
a. Click Add. This displays a screen for adding the New PIR Rule. Enter the PIR Rule Name as “Management Station
DST IP”, Entry status as Enable and then click Add. This adds the new PIR rule in the PIR List. By default, no
classification rules are applied.
b. Navigate to ADVANCED CONFIGURATION > QoS > PIR list. Click Details corresponding to the “Management
Station DST IP” PIR rule. This displays the classification rule details for this particular rule.
c. Click Add corresponding to Destination IP Address Entries. This displays a screen for referring the Management
Station’s IP Address. New Entry Table displays all the Entries of the IP Address Entries of the PIR List. Select the
option button corresponding to the Management Station and click Add. This adds the IP Address of the
Management Station to the Existing Entries. Click Back and the new entry appears in the Destination IP Address
Entries Table.
Step 2: Add Service Flow Classes
To handle management traffic, the system needs two Service Flow Classes: one for uplink traffic and one for downlink traffic.
1. Configure the Downlink Service Flow.
a. Navigate to ADVANCED CONFIGURATION > QoS > SFC list.
b. Click
Add
.
c. Enter the following parameters:
• Service Flow Name: DL-Management
• Scheduler Type: RtPS
• Traffic Direction: Downlink
• MIR: 1000
• CIR: 1000
• Max Latency: 20
• Tolerable Jitter: 10
• Priority: 7
• Max Messages in Burst: 16
• Entry Status: Enable
d. Click Add. The DL-Management Service Flow is added to the QoS SFC List.
2. Configure the Uplink Service Flow.
a. Navigate to ADVANCED CONFIGURATION > QoS > SFC list.
b. Click
Add
.
c. Enter the following parameters:
• Service Flow Name: UL-Management
• Scheduler Type: RtPS
• Traffic Direction: Uplink
• MIR: 1000
• CIR: 1000
• Max Latency: 20
• Tolerable Jitter: 10
• Priority: 7
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• Max Messages in Burst: 16
• Entry Status: Enable
d. Click Add. The UL-Management SF is added to the QoS SFC List.
NOTE: The input and output bandwidth limits set on the End Point A or BSU or on the End Point B or SU are used for
limiting aggregate bandwidth used by the SU or End Point B. These limits override any limit imposed by MIR in the
SFC. Therefore, these limits should be set to at least 1000 kbps (MIR values in UL-Management and DL-Management
SFCs).
Step 3: Configure QoS Classes
Finally, the DL-Management SFC and UL-Management SFCs created in Step 2 must be added to each QoS Class used by the
Quick Bridge network. Additionally, within the QoS class, these SFC must have the three PIRs mentioned in Step 1 associated
with them.
1.
Add SFCs to QoS Class.
a. Navigate to ADVANCED CONFIGURATION > QoS > Class list.
b. Click Details corresponding to the first class (Unlimited Best Effort) you wish to modify.
c. Under the QoS Class Service Flow, click Add.
d. Configure the following parameters, and click Add. This adds the New SFC & PIR relation to the QoS Class.
• Service Flow Name: DL-Management
• PIR Rule Name: ARP
• PIR Priority: 63
• Entry Status: Enable.
e. Again click Add under the QoS Class Service Flow Details.
f. Configure the following parameters and click Add. This adds the New SFC & PIR relation to the QoS Class.
• Service Flow Name: UL-Management
• PIR Rule Name: ARP
• PIR Priority: 63
• Entry Status: Enable
2. Add PIRs to SFCs within the QoS Class.
a. Navigate to ADVANCED CONFIGURATION > QoS > Class list.
b. Click Details corresponding to the first class (Unlimited Best Effort) you wish to modify.
c. Under the QoS Class Service Flow Details, click Details corresponding to the DL-Management Service Flow.
d. Under the QoS Class PIR Details heading, click Add.
e. Add the Management Station DST IP PIR to this Service Flow by configuring the following parameters:
• PIR Rule Name: Management Station DST IP
• PIR Priority: 63
• Entry Status: Enable
f.
Click Add. This PIR is added to the first Qos Class (Unlimited Best Effort) Service Flow’s (DL-Management) list.
g. Add the Management Station SRC IP PIR to this Service Flow by configuring the following parameters:
• PIR Rule Name: Management Station SRC IP
• PIR Priority: 63
• Entry Status: Enable
h. Return to the Class List and repeat steps 2 - 7 for the UL-Management Service Flow in this class.
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5.7 RADIUS Based SU QoS Configuration
RADIUS based QoS configuration enables you to configure QoS parameters on a SU through RADIUS Server. This way of
configuring QoS parameters, reduces the task of manually configuring QoS parameters on each SU available on the network.
Explained below is the process followed to configure QoS parameters on a SU from a RADIUS Server.
Figure 5-52 RADIUS Based QoS Configuration
To establish a connection with the BSU, the SU sends a registration request to BSU. On receiving the registration request, the
BSU sends an Access request along with the SU MAC address, to the RADIUS Server. The RADIUS Server then checks the
authentication of the user. If it is an authenticated user, it sends an Access-Accept response along with Vendor assigned QoS
parameter’s value to the BSU. On receiving the response, the BSU sends the response to the SU. The received QoS parameters
are then applied on the SU.
Tabulated below are the vendor specific attributes:
Name of the attribute Vendor Attribute Attribute Value
Assigned Format
Attribute
Number
QoS Class Index 34 Decimal 1 - 8
QoS Class SU Table Status 35 Decimal 1 - Enable / 2 - Disable
:
• RADIUS Based QoS configuration takes priority over Local QoS configuration.
• When the link is down, the configuration received from the RADIUS is lost.
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5.8 VLAN (Bridge Mode Only)
The Virtual Local Area Network (VLAN) feature helps in logical grouping of network host on different physical LAN segments, which
can communicate with each other as if they are all on the same physical LAN segment.
With VLANs, you can conveniently, efficiently, and easily manage your network in the following ways:
• Define groups
Reduce broadcast and multicast traffic to unnecessary destinations
- Improve network performance and reduce latency
• Increase security
- Secure network restricts members to resources on their own VLAN
The SUs and End Point devices support QinQ VLAN feature that enables service providers to use a single VLAN ID to support
multiple customer VLANs by encapsulating the 802.1Q VLAN tag within another 802.1Q frame. The benefits with QinQ are,
Increases the VLAN space in a provider network or enterprise backbone
Reduce the number of VLANs that a provider needs to support within the provider network for the same number of
customers
Enables customers to plan their own VLAN IDs, without running into conflicts with service provider VLAN IDs
Provides a simple Layer 2 VPN solution for small-sized MANs (Metropolitan Area Networks) or intranets
Provides customer traffic isolation at Layer 2 within a service provider network
: VLAN can be configured in Bridge Mode only.
5.8.1 System-Level VLAN Configuration
To configure system-level VLAN parameters, navigate to ADVANCED CONFIGURATION > VLAN. The VLAN configuration
screen appears.
Figure 5-53 System-Level VLAN Configuration
1. VLAN Status: This parameter is used to either enable or disable VLAN feature on the device. By default, this
parameter is disabled. To enable VLAN, select the VLAN Status box. If VLAN status is enabled, it indicates that locally
configured VLAN parameters will be applied on the device. If VLAN status is disabled, it indicates that the device is open for
remote VLAN configuration.
2. Management VLAN Id: This parameter enables the user to configure VLAN Id for management frames (SNMP, ICMP,
Telnet and TFTP). The stations that manage the device must tag the management frames with the management VLAN
Id. By default, the Management VLAN Id is set to -1 which indicates no tag is added to the management frame. To set
VLAN tag to the management frame, enter a value ranging from 1 to 4094.
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: Before setting the Management VLAN Id, make sure that the station that manages the device is a member of the
same VLAN; else, your access to the device will be lost.
3. Management VLAN Priority: This parameter is used to set IEEE 802.1p priority for the management frames. By
default, the priority is set to 0. To set the VLAN priority, enter a value ranging from 0 to 7.
4. Double VLAN (Q in Q) Status: Q in Q (also called as Double VLAN or Stacked VLAN) mechanism expands the VLAN
space by tagging the tagged packets, thus producing a “double-tagged” frame. The expanded VLAN space allows the
service provider to provide certain services, such as Internet access on specific VLANs for specific customers, and still
allows the service provider to provide other types of services for their other customers on other VLANs.
By default, Double VLAN is disabled on the device. To enable, select Enable from the Double VLAN (Q in Q) Status box
and click OK.
:
• If Double VLAN (Q in Q) Status is enabled, device expects Double VLAN tagged packet in DownLink
Direction. Management can be accessed with single VLAN/Double VLAN based on the management VLAN ID
configured.
• Only SU, End Point A and End Point B support Double VLAN (Q in Q) feature.
5. Service VLAN TPID: The Tag Protocol Identifier (TPID) helps to identify the frame as VLAN tagged frame. By default
the Service VLAN TPID is set to 0x8100. To interwork with few vendor devices that set the TPID to 0x9100, the device
allows the user to configure Service VLAN TPID as 0x9100. In this case, when a QinQ packet goes out of the device,
the Ether type of outer VLAN tag is changed to 0x9100.
6. Service VLAN Id: This parameter enables the user to configure outer/service provider VLAN ID for the data frames. By
default, the Service VLAN ID is set to -1 which indicates no outer/service VLAN tag is added to the data frame. To set
VLAN tag to the frame, enter a value ranging from 1 to 4094.
: When Double VLAN is enabled on the device, the Service VLAN ID should not be set to -1.
7. Service VLAN Priority: This parameter is used to set IEEE 802.1p priority in outer/service VLAN tag for the data
frames. By default, the priority is set to 0. To set the VLAN priority, enter a value ranging from 0 to 7.
5.8.2 Ethernet VLAN Configuration
You can configure VLAN on the ethernet interface(s) by using any one of the following VLAN Modes:
1. Transparent Mode
2. Access Mode
3. Trunk Mode
5.8.2.1 Transparent Mode
Transparent mode can be configured in a BSU, SU and End Point devices. This mode is equivalent to NO VLAN support and is the
default mode. It is used to connect VLAN aware or unaware networks. In this mode, the device transfers both tagged and untagged
frames received on the Ethernet or WORP interface.
To configure the Ethernet interface of the device in VLAN Transparent Mode, navigate to ADVANCED CONFIGURATION > VLAN
> Ethernet. The VLAN Ethernet Configuration screen appears:
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Figure 5-54 Transparent Mode
Tabulated below is the table which explains the method to configure the device in Transparent mode:
Parameters Description
Interface Displays the name of the Ethernet interface.
VLAN Mode Select the VLAN mode as Transparent.
: When the device is configured in Double VLAN mode, do not configure the
Ethernet interface of the device in Transparent Mode.
Click OK and then COMMIT.
: Wireless Interface of the device will always be in transparent mode. There is no support provided to edit the VLAN
parameters of the wireless interface.
5.8.2.2 Access Mode
Access Mode can be configured in a SU, End Point A and End Point B. This mode is used to connect VLAN aware networks with
VLAN unaware networks.
The ingress untagged traffic received on the Ethernet interface are tagged with the configured Access VLAN Id and Access VLAN
priority before forwarding to the WORP interface. Similarly all egress tagged frames with specified VLAN Id are untagged at
the Ethernet interface and then forwarded. Based on the Management VLAN ID configuration, both tagged and untagged
management frames can access the device from the WORP interface. However, only untagged management frames can
access the device from the Ethernet Interface; the tagged frames are dropped.
To configure the Ethernet interface of the device in Access Mode, navigate to ADVANCED CONFIGURATION > VLAN >
Ethernet. The VLAN Ethernet Configuration screen appears:
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Figure 5-55 Access Mode
Tabulated below is the table which explains the method to configure the device in Access Mode:
Parameter Description
Interface Displays the name of the Ethernet interface.
VLAN Mode Select the VLAN mode as Access and click OK.
Access VLAN Id Enter the Access VLAN Id in the Access VLAN Id box. The untagged data frames received
at the Ethernet interface are tagged with this configured VLAN Id and then forwarded to
the WORP interface. By default, the Access VLAN Id is set to -1 which indicates no tag is
added to the data frame. To set Access VLAN tag to the data frame, enter a value ranging
from 1 to 4094.
: When Double VLAN is enabled on the device, the Access VLAN ID should not be
set to -1.
Access VLAN Priority
This parameter is used to set IEEE 802.1p priority for the data frames. By default, the
priority is set to 0. To set the Access VLAN priority, enter a value ranging from 0 to 7.
Click OK and then COMMIT.
5.8.2.3 Trunk Mode
Trunk Mode can be configured in a BSU, SU, End Point A and End Point B. This mode is used to connect VLAN aware
networks with VLAN aware networks. In the Trunk mode, the Ethernet interface of the device forwards only those tagged
frames whose VLAN Id matches with a VLAN Id present in the trunk table.
If the device receives untagged frames and the Allow Untagged Frames functionality is disabled, then the untagged packets
are dropped.
If the Allow Untagged Frames functionality is enabled, then functionality varies based on the device:
In case of a BSU, the untagged packets are forwarded to the destination.
In case of a SU, End Point A and End Point B, the device behaves as in Access Mode for untagged traffic. The
untagged frames are tagged with the configured Port VLAN ID and forwarded to the destination.
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Advanced Configuration
: Mixed VLAN Mode = Trunk Mode + Allow Untagged Frames + Port VLAN ID
To configure the Ethernet interface of the device in Trunk mode, navigate to ADVANCED CONFIGURATION > VLAN >
Ethernet. The VLAN Ethernet Configuration screen appears:
Figure 5-56 Trunk Mode (BSU)
Figure 5-57 Trunk Mode (SU/End Point A/End Point B)
Tabulated below is the table which explains the method to configure the device in Trunk Mode:
Parameter Description
Interface Displays the name of the Ethernet interface.
VLAN Mode Select the VLAN Mode as Trunk.
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Parameter Description
Allow Untagged Select Enable or Disable. By default, it is disabled.
Frames
Disable: If this option is selected, the Ethernet interface forwards only tagged
frames whose VLAN Id matches with a VLAN ID present in trunk table.
Enable:
- In case of a BSU, when Allow Untagged Frames is enabled, the Ethernet
interface of the device forwards the data packets as-is.
- In case of a SU/End Point A/End Point B, when Allow Untagged Frames is
enabled, the device behaves as in Access mode. Click OK.
Port VLAN ID Enter the Port VLAN ID in the Port VLAN ID box. The untagged data frames received at
the Ethernet interface are tagged with this port VLAN Id and then forwarded to the
destination interface. By default, the Port VLAN Id is set to -1 which indicates no tag is
added to the data frame. To set Port VLAN tag to the data frame, enter a value ranging from
1 to 4094.
:
Applicable only on a SU, End Point A and End Point B.
When Double VLAN is enabled on the device, the Port VLAN ID should not be set
to -1.
The configured Port VLAN Id should not exist in the Trunk table.
Port VLAN Priority This parameter is used to set IEEE 802.1p priority for the data frames. By default, the
priority is set to 0. To set the Port VLAN priority, enter a value ranging from 0 to 7.
: Applicable only to SU and End Point devices.
After configuring the required parameters, click OK and then COMMIT. Add
VLAN IDs to Trunk Table
To add VLAN IDs to the trunk table,
1. Click Add in the VLAN Ethernet Configuration screen. The VLAN Trunk Table Add Row screen appears.
Figure 5-58 Add VLAN IDs to Trunk Table
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Tabulated below is the table which explains the method to add VLAN IDs to Trunk Table:
Parameter Description
Trunk Id Enter VLAN ID in the Trunk Id box.
Entry Status This parameter indicates the status of each VLAN Trunk Id entry. By default, the Trunk Id is
enabled. To disable, select Disable from the Entry Status box.
2. Click
Add
.
3. To save and apply the configured parameters on the device, click COMMIT.
: You can configure a maximum of 256 trunk VLAN Ids in a BSU and End Point A device, and 16 VLAN Ids in a SU and End
Point B device.
5.9 RADIUS Based SU VLAN Configuration
RADIUS based VLAN configuration enables you to configure VLAN parameters on a SU through RADIUS Server. This way of
configuring VLAN parameters,
Reduces the task of manually configuring VLAN parameters on each SU available on the network
Allows SU to remain on the same VLAN as it moves across the network
Explained below is the process followed to configure VLAN parameters on a SU from a RADIUS Server.
Figure 5-59 RADIUS Based VLAN Configuration
To establish a connection with the BSU, the SU sends a registration request to BSU. On receiving the registration request, the BSU
sends an Access request along with the SU MAC address, to the RADIUS Server. The RADIUS Server then checks the
authentication of the user. If it is an authenticated user, it sends an Access-Accept response along with Vendor assigned VLAN
parameter’s value to the BSU. On receiving the response, the BSU sends the response to the SU. The received VLAN
parameters are then applied on the SU.
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Advanced Configuration
Tabulated below are the vendor specific attributes:
Name of the attribute Vendor Attribute Attribute Value
Assigned Format
Attribute
Number
SU_VLAN_MAC 3 MacAddr SU Mac Address
VLAN_ETH1 Vlan Mode 4 Decimal 1 -Transparent Mode
2 - Trunk Mode / 3 - Access Mode
SU_VLAN_Name 5 String SU VLAN Name
VLAN_ETH1 Access VLAN ID 6 Decimal 1 - 4095
VLAN_ETH1 Access Vlan Priority 7 Decimal 0 - 7
Management VLAN ID attribute 8 Decimal 1 - 4095
Management VLAN Priority 9 Decimal 0 - 7
VLAN_ETH1 TrunkID 1 … 16 10 … 25 Decimal 1 - 4095
SU_VLAN_Table_Status 26 Decimal 1 - enable / 2 - disable / 3 - delete
Service Vlan Id (Q-inQ) 32 Decimal 1 - 4095
Service Vlan Priority (Q-inQ) 33 Decimal 0 - 7
QoS Class Index 34 Decimal 1 - 8
QoS Class SU Table Status 35 Decimal 1 - Enable / 2 - Disable
VLAN_ETH2 Vlan Mode 40 Decimal 1 - Transparent Mode
2 - Trunk Mode / 3 - Access Mode
VLAN_ETH2 Access Vlan Id 41 Decimal 1 - 4095
VLAN_ETH2 Access Vlan Priority 42 Decimal 0 - 7
VLAN_ETH2 TrunkID 1 … 16 43 … 58 Decimal 1 - 4095
Double Vlan (Q-in-Q) Status 59 Decimal 1 - Enable / 2 - Disable
Service Vlan TPID (Q-inQ) 60 Decimal 1 - InnerTag / 2 - Outer Tag
VLAN_ETH1_Port_Vlan_Id 61 Decimal 1 - 4095
VLAN_ETH1_Port_Vlan_Pri 62 Decimal 0 - 7
VLAN_ETH1_Allow_Untag_Frames 63 Decimal 1 - Enable / 2 - Disable
VLAN_ETH2_Port_Vlan_Id 64 Decimal 1 - 4095
VLAN_ETH2_Port_Vlan_Pri 65 Decimal 0 - 7
VLAN_ETH2_Allow_Untag_Frames 66 Decimal 1 - Enable / 2 - Disable
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:
• RADIUS Configuration is applicable only when the VLAN Status is disabled on the SU.
• Local VLAN configuration takes priority over RADIUS Based VLAN configuration.
• When the link is down, the configuration received from the RADIUS is lost.
5.10 Filtering (Bridge Only)
Filtering is useful in controlling the amount of traffic exchanged between the wired and wireless networks. By using filtering
methods, we can restrict any unauthorized packets from accessing the network. Filtering is available only in bridge mode.
The various filtering mechanisms supported by the device are as follows:
Protocol Filter
Static MAC Address Filter
Advanced Filtering
TCP/UDP Port Filter
Storm Threshold Filter
Filters get activated only when they are globally enabled on the device. To apply/configure global filters on the device, navigate
to ADVANCED CONFIGURATION > Filtering. The Filtering screen appears.
Figure 5-60 Filtering
Tabulated below is the table which explains Filtering parameters and the method to configure the configurable parameter(s):
Parameter Description
Global Filter Flag By default, Global Filtering is disabled meaning which no filters are applied on the device.
To apply filters on the device, enable the Global Filter Flag.
Please note that if Global Filter Flag is not enabled on the device, then none of the filters
can be applied on the device.
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Advanced Configuration
Parameter Description
STP/LACP Frames This parameter allows you to either Block or Passthru STP/LACP frames on the network.
Passthru: By allowing the STP/LACP frames, any loops that occurs within a network
can be avoided. If configured to Passthru, the STP/LACP frames in the system are
bridged.
Block: When blocked, the STP/LACP frames encountered on a network are
terminated at bridge.
By default, STP/LACP frames are allowed on the network.
: STP or LACP Frame Status will block or passthru the frames destined to IEEE
802.1D and 802.1Q reserved MAC address (01:80:C2:00:00:00 to
01:80:C2:00:00:0F).
After configuring the required parameters, click OK and then COMMIT.
5.10.1 Protocol Filter
The Protocol Filter blocks or forwards packets based on the protocols supported by the device.
To configure Protocol Filter on the device, navigate to ADVANCED CONFIGURATION > Filtering > Protocol Filter. The
Protocol Filter screen appears:
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Figure 5-61 Protocol Filter
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Tabulated below is the table which explains Protocol Filter parameters and the method to configure the configurable
parameter(s):
Parameter Description
Filtering Control This parameter is used to configure the interface on which filtering has to be applied. The
filtering can be applied on any of the following interfaces:
Ethernet: Packets are examined at the Ethernet interface.
Wireless: Packets are examined at the Wireless interface.
All Interfaces: Packets are examined at both Ethernet and Wireless interface. By
default, the Filtering Control is set to Disable, meaning which Protocol Filters are
disabled on all the interfaces.
: In addition to enabling Filtering Control, the Global Filter Flag should also be
enabled for the filter to take effect.
Filtering Type This parameter specifies the action to be performed on the data packets whose protocol
type is not defined in the protocol filter table (this table contains a list of default protocols
supported by the device and the protocols defined by the user), or whose Entry Status is in
Disable state. The available filtering types are:
Block: The protocols with entry status Disable or the protocols which do not exist in
the protocol filtering table are blocked.
Passthru: The protocols with entry status Disable or the protocols which do not exist
in the protocol filtering table are allowed through the configured interface.
After configuring the required parameters, click OK and then COMMIT.
5.10.1.1 Protocol Filter Table
The Protocol Filter table displays a list of default protocols supported by the device and the protocols created by the user. By default,
the system generates 19 protocols entries. Each of the Protocol contains the following information:
Parameter Description
Protocol Name Represents the Protocol name. The system throws an error when you try to edit the name
of a default protocol.
Protocol Number Represents the Protocol number. The value is of 4 digit hexadecimal format. The system
throws an error when you try to edit the Protocol number of a default protocol.
Filter Status The supported filter status are,
Passthru: When the filter status is set to Passthru and entry status is Enable, all
packets whose protocol matches with the given protocol number are forwarded on
the configured interface.
Block: When the filter status is set to Block and entry status is Enable, all packets
whose protocol matches with the given protocol number are dropped on the
configured interface.
By default, the status is set to Block.
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Entry Status Set the entry status as either Enable, Disable or Delete.
Enable: Enables filter status on a protocol.
Disable: Disables filter status on a protocol.
Delete: Deletes a protocol entry from the Protocol Filter Table.
: System-defined default protocols cannot be deleted.
5.10.1.2 Add User-defined Protocols to the Filter Table
To add user-defined protocols to the Protocol Filter Table, click Add in the Protocol Filter screen. The Protocol Filter Add Row
screen appears.
Figure 5-62 Add User-defined Protocols
Enter details for all the required parameters and click Add.
: The maximum number of Protocol Filters that can be added to the table are 64, out of which 19 are default entries.
5.10.2 Static MAC Address Filter
The Static MAC Address filter optimizes the performance of a wireless (and wired) network. With this feature configured, the device
can block traffic between wired devices and wireless devices based on the MAC address.
Each MAC Address or Mask is comprised of 12 hexadecimal digits (0-9, A-F) that correspond to a 48-bit identifier. (Each
hexadecimal digit represents 4 bits (0 or 1)).
Taken together, a MAC Address/Mask pair specifies an address or a range of MAC addresses that the device will look for when
examining packets. The device uses Boolean logic to perform an “AND” operation between the MAC Address and the Mask at the
bit level. A Mask of 00:00:00:00:00:00 corresponds to all MAC addresses, and a Mask of FF:FF:FF:FF:FF:FF applies only to the
specified MAC Address.
For example, if the MAC Address is 00:20:A6:12:54:C3 and the Mask is FF:FF:FF:00:00:00, the device will examine the source and
destination addresses of each packet looking for any MAC address starting with 00:20:A6. If the Mask is FF:FF:FF:FF:FF:FF, the
device will only look for the specific MAC address (in this case, 00:20:A6:12:54:C3).
You can configure the Static MAC Address Filter parameters depending on the following scenarios:
To prevent all traffic from a specific wired MAC address from being forwarded to the wireless network, configure only
the Wired MAC Address and Wired Mask (leave the Wireless MAC Address and Wireless Mask set to all zeros).
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To prevent all traffic from a specific wireless MAC address from being forwarded to the wired network, configure only
the Wireless MAC address and Wireless Mask (leave the Wired MAC Address and Wired Mask set to all zeros).
To prevent traffic between a specific wired MAC address and a specific wireless MAC address, configure all four
parameters. Configure the wired and wireless MAC address and set the wired and wireless mask to all Fs.
To prevent all traffic from a specific wired Group MAC address from being forwarded to the wireless network,
configure only the Wired MAC Address and Wired Mask (leave the Wireless MAC Address and Wireless Mask set to all
zeros).
To prevent all traffic from a specific wireless Group MAC address from being forwarded to the wired network,
configure only the Wireless MAC address and Wireless Mask (leave the Wired MAC Address and Wired Mask set to all
zeros).
To prevent traffic between a specific wired Group MAC address and a specific wireless Group MAC address, configure
all four parameters. Configure the wired and wireless MAC address and set the wired and wireless mask to all Fs.
Static MAC Filter Examples
Consider a network that contains a wired PC and three wireless PCs. The MAC addresses for each PCs are as follows:
MAC Address of the wired PC: 00:40:F4:1C:DB:6A
MAC Address of the wireless PC1: 00:02:2D:51:94:E4
MAC Address of the wireless PC2: 00:02:2D:51:32:12
MAC Address of the wireless PC3: 00:20:A6:12:4E:38
Prevent two specific PCs from communicating
Configure the following settings to prevent the wired PC and wireless PC1 from communicating:
Wired MAC Address: 00:40:F4:1C:DB:6A
Wired Mask: FF:FF:FF:FF:FF:FF
Wireless MAC Address: 00:02:2D:51:94:E4
Wireless Mask: FF:FF:FF:FF:FF:FF
Result: Traffic between the wired PC and wireless PC1 is blocked. wireless PC2 and PC3 can still communicate with the wired
PC.
Prevent multiple Wireless PCs from communicating with a single wired PC
Configure the following settings to prevent wireless PC1 and PC2 from communicating with the wired PC:
Wired MAC Address: 00:40:F4:1C:DB:6A
Wired Mask: FF:FF:FF:FF:FF:FF
Wireless MAC Address: 00:02:2D:51:94:E4
Wireless Mask: FF:FF:FF:00:00:00
Result: When a logical “AND” is performed on the Wireless MAC Address and Wireless Mask, the result corresponds to any MAC
address beginning with the 00:20:2D prefix. Since wireless PC1 and wireless PC2 share the same prefix (00:02:2D), traffic
between the wired Server and wireless PC1 and PC2 is blocked. Wireless PC3 can still communicate with the wired PC since it has
a different prefix (00:20:A6).
Prevent all wireless PCs from communicating with a single wired PC
Configure the following settings to prevent wired PC from communicating with all three wireless PCs:
Wired MAC Address: 00:40:F4:1C:DB:6A
Wired Mask: FF:FF:FF:FF:FF:FF
Wireless MAC Address: 00:00:00:00:00:00
Wireless Mask: 00:00:00:00:00:00
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Result: The device blocks all traffic between the wired PC and all wireless PCs.
Prevent a wireless PC from communicating with the wired network
Configure the following settings to prevent wireless PC 3 from communicating with any device on the Ethernet:
Wired MAC Address: 00:00:00:00:00:00
Wired Mask: 00:00:00:00:00:00
Wireless MAC Address: 00:20:A6:12:4E:38
Wireless Mask: FF:FF:FF:FF:FF:FF
Result: The device blocks all traffic between wireless PC 3 and the Ethernet network.
5.10.2.1 Static MAC Address Filter Configuration
To configure Static MAC Filter parameters, navigate to ADVANCED CONFIGURATION > Filtering > Static MAC Address
Filter. The Static MAC Address Filter screen appears:
Figure 5-63 Static MAC Address Filter
Click Add in the Static MAC Address Filter screen. The Static MAC Address Filter Add Row screen appears.
Figure 5-64 Static MAC Address Filter Add Row
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Advanced Configuration
Tabulated below is the table which explains Static MAC Address Filter parameters and the method to configure the
configurable parameter(s):
Parameter Description
Wired MAC Address Specifies the MAC address of the device on the wired network that is restricted from
communicating with a device in the wireless network.
Wired MAC Mask Specifies the range of MAC address to which this filter is to be applied.
Wireless MAC address Specifies the MAC address of the device on the wireless network that is restricted from
communicating with a device in the wired network.
Wireless MAC Mask Specifies the range of MAC address to which this filter is to be applied.
Comment Specifies the comment associated with Static MAC Filter table entry.
Status Specifies the status of the newly created filter.
Click Add and then COMMIT.
:
A maximum of 200 MAC address filters can be added.
The Wired MAC address and the Wireless MAC address should be a unicast MAC address.
The MAC Address or Mask includes 12 hexadecimal digits (each hexadecimal equals to 4 bits containing 0 or 1)
which is equivalent to 48 bit identifier.
5.10.3 Advanced Filtering
With Advanced Filtering, you can filter pre-defined IP Protocol traffic on the network.
By default, 5 IP protocols are pre-defined and based on the configuration they can be blocked or allowed to enter the
network.
To apply filters on the IP protocols, navigate to ADVANCED CONFIGURATION > Filtering > Advanced Filtering. The
Advanced Filtering screen appears:
Figure 5-65 Advanced Filtering
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Advanced Configuration
The Advanced Filtering table contains a list of 5 pre-defined protocols on which Advanced Filtering is applied. The following table
explains the Filtering table parameters:
Parameter Description
Protocol Name Represent the protocol name. By default, Advanced Filtering is supported on the following
5 default protocols:
• Deny IPX RIP
• Deny IPX SAP
• Deny IPX LSP
• Deny IP Broadcasts
• Deny IP Multicasts
Direction Represents the direction of an IP Protocol traffic that needs to be filtered. The directions
that can be filtered are,
• Ethernet to wireless
• Wireless to ethernet
• Both
Entry Status If enabled, then filtering is applied on the IP protocol else not applied.
:
• The Advanced Filtering table contains a maximum of 5 pre-defined IP protocols.
• User-defined IP protocols cannot be added to the Advanced Filtering table.
5.10.3.1 Edit Advanced Filtering Table Entries
To edit Advanced Filtering table protocols, click Edit in the Advanced Filtering screen. The Advanced Filtering - Edit Entries
screen appears.
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Advanced Configuration
Figure 5-66 Advance Filtering- Edit Entries
Modify the IP protocol traffic direction that needs to be filtered, and the filtering status for the desired IP Protocol. Next
click OK and then COMMIT.
5.10.4 TCP/UDP Port Filter
TCP/UDP Port Filtering allows you to enable or disable Transmission Control Protocol (TCP) ports and User Datagram Port (UDP)
ports on network devices. A user specifies a Protocol Name, Port Number, Port Type (TCP, UDP, or TCP/UDP), and filtering
interfaces (Only Wireless, Only Ethernet or Both) in order to block access to services such as Telnet and FTP, and traffic
such as
NETBIOS and HTTP.
To apply filters on TCP/UDP Port, navigate to ADVANCED CONFIGURATION > Filtering > TCP/UDP Port Filter. The
TCP/UDP Port Filter screen appears.
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Advanced Configuration
Figure 5-67 TCP/UDP Port Filter
The Filter Control parameters determines if filter has to be applied or not on a TCP/UDP Port. By default, it is disabled. To apply
filters, select Enable and click OK.
5.10.4.1 TCP/UDP Port Filter Table
The TCP/UDP Port Filter table displays a list of default TCP/UDP ports and user-defined ports which can be enabled or disabled as
desired. By default, the device support 7 default TCP/UDP port filter entries.
Parameter Description
Protocol Name The name of the service/protocol. Please note that the system throws an error when an
attempt is made to edit the default service/protocol name.
Port Number Represents the destination port number. Please note that the system throws an error when
an attempt is made to edit the port number.
Port Type Represents the port type (TCP, UDP, Both).
Filter Interface Represents the interface on which the filter is applied. The supported interfaces are,
• Only Ethernet
• Only Wireless
• All Interfaces
Entry Status Set the entry status as either Enable, Disable or Delete.
Enable: Filter is applied and filters the packet based on the Port number and port
type.
Disable: No filter is applied.
Delete: Allows to delete only user-defined TCP/UDP port filter entry. When you
attempt to delete default entries, the device throws an error.
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Advanced Configuration
If you have configured any user-defined protocols then click OK and then COMMIT.
For example, a device with the following configuration would discard frames received on its Ethernet interface with a UDP
destination port number of 137, effectively blocking NETBIOS Name Service packets. Please note that even the Filtering
Control should be enabled to apply the filter.
Protocol Name Port Number Port Type Filter Interface Entry Status (Enable/Disable)
NETBIOS Name Service
137 UDP Ethernet Enable
5.10.4.2 Adding User-defined TCP/UDP Port Filter Entries
To add user-defined TCP/UDP port filter entries to the table, click Add in the TCP / UDP Port Filter screen. The TCP/UDP Port
Filter Add Row screen appears:
Figure 5-68 Add User-defined TCP/UDP Protocols
Provide details for all the parameters and click Add.
To apply the configured parameters, click COMMIT.
:
• The TCP/UDP filtering operation is allowed only when the Global Flag and Filter Control options are enabled.
• A maximum of 64 TCP/UDP Port Filter entries can be added to the table, out of which 7 are default entries.
5.10.5 Storm Threshold Filter
The Storm Threshold Filter restricts the excessive inbound multicast or broadcast traffic on layer two interfaces. This protects
against broadcast storms resulting from spanning tree misconfiguration. A broadcast or multicast filtering mechanism needs to be
enabled so that a large percentage of the wireless link remains available to the connected mobile terminals.
To configure Storm Threshold Filter, navigate to ADVANCED CONFIGURATION > Filtering > Storm Threshold Filter. The
Storm Threshold Filter screen appears. This screen contains information about the threshold values per second of the
multicast and broadcast packets that can be processed for the interface(s) present in the device.
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Advanced Configuration
Figure 5-69 Storm Threshold Filter
Tabulated below is the table which explains Storm Threshold Filter parameters and the method to configure the configurable
parameter(s):
Parameter Description
Interface Allows to configure the type of interface on which filtering has to be applied. The Storm
Threshold filter can be used to filter the traffic on two types of interfaces: Ethernet or
Wireless. By default, Storm Threshold filtering is disabled on both Ethernet and Wireless
interfaces.
Multicast Threshold Allows to configure the threshold value of the multicast packets to be processed for the
Ethernet or Wireless interface. Packets more than threshold value are dropped. If threshold value
for multicast packets is set to '0', filtering is disabled. The default Multicast
Threshold value is 0 per second.
Broadcast Threshold Allows to configure the threshold value of the broadcast packets to be processed for the
Ethernet or Wireless interface. Packets more than threshold value are dropped. If threshold value
for broadcast packets is set to '0', filtering is disabled. The default Broadcast
Threshold value is 0 per second.
After configuring the required parameters, click OK and then COMMIT.
5.10.6 WORP Intra Cell Blocking
: Intra Cell Blocking is applicable only to a BSU in Bridge Mode only.
The WORP Intra Cell Blocking feature restricts traffic between SUs which are registered to the same BSU. The two potential
reasons to isolate traffic among the SUs are:
To provide better security by isolating the traffic from one SU to another in a public space.
To block unwanted traffic between SUs to prevent this traffic from using bandwidth.
The user can form groups of SUs at the BSU which define the filtering criteria. All data to/from SUs belonging to the same group
are bridged. If a SU does not belong to any group, the BSU discards the data.
The user can also configure a Security Gateway to block traffic between SUs connected to different BSUs. All packets destined
for SUs not connected to the same BSU are forwarded to the Security Gateway MAC address (configured under Security
Gateway).
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The following rules apply to Intra Cell Blocking Groups:
A SU can be assigned to more than one group.
A SU that has not been assigned to any group cannot communicate to any other SU connected to the same or
different BSU.
Example of Intra-Cell Blocking Groups
Assume that four Intra Cell Blocking Groups have been configured on a BSU. SUs 1 through 10 are registered to the BSU.
Group1 Group2 Group3 Group4
SU1 SU2 SU6 SU8
SU4 SU3 SU1 SU9
SU5 SU8 SU7 SU10
In this example, SU1 belongs to two groups, Group 1 and Group 3. Therefore, packets from SU1 destined to SU4, SU5, SU6
and SU7 are not blocked. However, SU9 belongs to group 4 only and packets from SU9 are blocked unless sent to SU8 or SU
10.
To configuring Intra-Cell Blocking parameters, navigate to ADVANCED CONFIGURATION > Filtering> WORP Intra Cell
Blocking. The following screen appears:
Figure 5-70 Intra Cell Blocking
This screen is classified into two categories:
Intra Cell Blocking
and
Security Gateway
. Tabulated below are the
configuration details.
Parameter Description
Intra Cell Blocking
Status By default, Intra Cell Blocking is disabled on a BSU. Select Enable to enable the feature
and then Click OK and then COMMIT.
Security Gateway
Status By default, Security Gateway is disabled on a BSU. Select Enable to enable the feature.
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Parameter Description
MAC Address Represents the MAC address of the security gateway. This gateway routes the packets
transmitted by the SU to the different BSUs to which it belongs.
After configuring the required parameters, click OK and then COMMIT.
: Intra Cell Blocking is configurable only in Bridge mode. When you change the device from Bridge to Routing mode or
vice-versa, Intra-Cell Blocking stops or starts working only after a Reboot.
5.10.6.1 WORP Intra Cell Blocking Group Table
The user can form groups of SUs at the BSU which define the filtering criteria. All data to/from SUs belonging to the same group
are bridged. If a SU does not belong to any group, the BSU discards the data.
By default, a BSU supports 16 groups and each group can contain a maximum of 240 SUs. Please note that a single SU can be a
member of all the existing groups.
To view and configure the Intra Cell Blocking Group table, navigate to ADVANCED CONFIGURATION > Filtering> WORP Intra
Cell Blocking > Group Table. The WORP Intra Cell Blocking Group Table screen appears:
Figure 5-71 WORP Intra Cell Blocking Group Table
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This table displays the list of groups. If the Entry Status for a group is set to Enable then BSU discards all the packets coming from
SUs which are not members of that group. If set to Disable, then allows all the packets coming from SUs which are not the
members of that group. If you have changed the Entry Status of a group, then click OK and then COMMIT.
5.10.6.2 WORP Intra Cell Blocking MAC Table
The WORP Intra Cell Blocking MAC table allows to add SU’s MAC address and assign them to the groups. A maximum of 250 SUs
can be added to the table.
To add SU to the table, navigate to ADVANCED CONFIGURATION > Filtering > WORP Intra Cell Blocking > MAC Table. The
WORP Intra Cell Blocking MAC Table screen appears:
Figure 5-72 WORP Intra Cell Blocking MAC Table
To add MAC addresses, click Add. The following screen appears.
Figure 5-73 WORP Intra Cell Blocking MAC Table Add Row
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Tabulated below is the table which explains the WORP Intra Cell Blocking MAC Table entries and the method to configure the
configurable parameter(s):
Parameter Description
MAC Address Represents the SU’s MAC address.
Group ID’s 1 to 16 By default, a Group ID is disabled meaning which the SU is not a part of that group. To
make it a part of that group, select Enable.
Entry Status If SU is part of a group and its Entry Status is enabled then it can communicate with all the
SUs belonging to that group. If Entry Status is disabled, then the communication is
blocked.
After adding the MAC address, click Add.
To edit the existing MAC addresses, click Edit icon in the WORP Intra Cell Blocking MAC Table screen. Modify the
parameters as desired in the WORP Intra Cell Blocking MAC Table Add Row screen and click OK and then COMMIT.
In the WORP Intra Cell Blocking MAC Table, you can change the Entry Status as either Enable/Disable/Delete. Once the status
is changed, click OK and then COMMIT.
5.11 DHCP
Dynamic Host Configuration Protocol (DHCP) is a network protocol that enables a server to assign an IP address to the DHCP client
from a defined range of IP addresses configured for a given network. Allocating IP addresses from a central location simplifies
the process of configuring IP addresses to individual DHCP clients, and also avoids IP conflicts.
5.11.1 DHCP Pool
DHCP Pool is a pool of defined IP addresses which enables a DHCP Server to dynamically pick IP address from the pool and assign
it to the DHCP client.
To configure a range of IP addresses in the DHCP Pool, navigate to ADVANCED CONFIGURATION > DHCP > DHCP Server >
Pool. The DHCP Pool screen appears:
Figure 5-74 DHCP Pool
Each pool entry comprises the following tabulated information:
Parameter Description
Interface Specifies the interface type, that is, Bridge or Routing (Ethernet and Wireless).
Start IP Address and Specifies the start and end IP address of the addresses to be added to the pool.
End IP Address
Delete Allows you to delete a pool entry.
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: A maximum of five pool entries can be added to the table. A pool entry can be deleted but cannot be edited.
5.11.1.1 Adding a New Pool Entry
To add a new entry to the DHCP Pool, click Add on the DHCP Pool screen. The following DHCP Pool Table Add Row screen
appears:
Figure 5-75 DHCP Pool Table Add Row
Enter the pool details and click Add. The entry will be updated in the DHCP pool table. To
apply the configured changes, click COMMIT.
5.11.2 DHCP Server
If DHCP Server is enabled, it picks automatically the IP addresses from the specific interface address pool and assigns them to the
respective DHCP clients.
DHCP Server feature is applicable to both Bridge and Routing Mode. In Routing mode, DHCP Server can be configured for each
interface (Ethernet and Wireless) separately. Unless the DHCP Server functionality is enabled for an interface, the DHCP Server
does not respond to the DHCP requests received on that interface.
To configure the DHCP server parameters, navigate to ADVANCED CONFIGURATION > DHCP > DHCP Server > Interface. The
DHCP Server screen appears:
Figure 5-76 DHCP Server
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Tabulated below is the table which explains DHCP Server parameters and the method to configure the configurable
parameter(s):
Parameter Description
DHCP Server Status By default, DHCP Server is disabled on a device. To enable DHCP Server, select Enable.
A DHCP Server can be enabled only when the following two conditions are satisfied:
1. Before enabling, atleast one interface should be enabled on which the DHCP Server
has to run.
2. The DHCP pool table should have atleast one pool configured for that interface.
Max Lease Time
Specifies the maximum lease time for which the DHCP client can use the IP address
provided by the DHCP Server. The value ranges from 3600 - 172800 seconds.
DHCP Interface Table
Interface Type Specifies the interface for which the DHCP Server functionality shall be configured.
That is Bridge or Ethernet/Wireless in case of Routing mode.
Net Mask Specifies the subnet mask to be sent to the DHCP client along with the assigned IP
address. The netmask configured here should be greater than or equal to the netmask
configured on the interface.
Default Gateway Specifies the default gateway to be sent to the DHCP client along with the assigned IP
Address. Default Gateway is a node that serves as an accessing point to another network.
Primary DNS Specifies the primary DNS (Domain Name Server) IP address to be sent to the DHCP client.
Secondary DNS Specifies the secondary DNS IP address to be sent to the DHCP client.
Default Lease Time DHCP Server uses this option to specify the lease time it is willing to offer to the DHCP
client over that interface. Once the lease time expires, the DHCP Server allocates a new IP
address to the device. The Default Lease Time should be less than or equal to the
configured Max Lease Time.
Comment Specifies a note for the device administrator.
Entry Status Used to Enable or Disable the DHCP Server functionality over the interface.
After configuring the required parameters, click OK and then COMMIT.
5.11.3 DHCP Relay (Routing Mode only)
The DHCP relay agent forwards DHCP requests to the configured DHCP Server. A maximum of 5 DHCP Servers can be
configured. There must be at least one DHCP Server configured in order to relay DHCP request.
: DHCP Relay Agent is configurable only in Routing mode. It cannot be enabled when NAT or DHCP Server are enabled.
To view and configure DHCP Relay Server parameters, navigate to ADVANCED CONFIGURATION > DHCP > DHCP Relay >
Relay Server. The DHCP Relay screen appears:
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Figure 5-77 DHCP Relay
By default, DHCP Relay is disabled on the device. To enable it, atleast one DHCP Server IP address should be configured.
To add a DHCP Server to the Relay Server Table, click Add in the DHCP Relay screen. The DHCP Relay Server Add Row
screen appears:
Figure 5-78 DHCP Relay Server Add Row
Enter the DHCP Server IP Address and then click Add.
After configuring the required parameters, click OK and then COMMIT.
: DHCP server is disabled automatically if DHCP Relay agent is enabled and vise-verse.
5.12 IGMP Snooping
: IGMP Snooping is applicable only in a Bridge Mode.
Proxim’s Tsunami® devices support Internet Group Management Protocol (IGMP) Snooping feature. With IGMP Snooping
enabled on the device, multicast traffic is only forwarded to ports that are members of the specific multicast group. By
forwarding the traffic only to the destined ports, reduces unnecessary load on devices to process packets.
Explained below is the IGMP Snooping process with the help of a diagram:
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Figure 5-79 IGMP Snooping Process
The router forwards the IP multicast data to the BSU/End Point A.
Lets say, with IGMP Snooping not enabled on the BSU/End Point A, the multicast data is transmitted over the wireless medium
irrespective of whether the multicast group address is a member of the multicast group table maintained in each BSU/End Point
A. With IGMP Snooping enabled, the BSU/End Point A transmits the data only when the multicast group address is a member of
the multicast group table, else drops the packet. The SU/End Point B will receive the multicast data.
Similarly, with IGMP Snooping not enabled on the SU/End Point B, the multicast data is transmitted irrespective of whether the
multicast group address is a member of the multicast group table maintained in each SU/End Point B. With IGMP Snooping
enabled, the SU/End Point B transmits the data to the host only when the multicast group address is a member of the multicast
group table, else drops the packet.
IGMP Snooping is of 2 kinds:
Active: Active IGMP Snooping listens to IGMP traffic and filters IGMP packets to reduce load on the multicast router.
Passive: Passive IGMP Snooping simply listens to IGMP traffic and does not filter or interfere with IGMP.
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:
• Tsunami® devices supports only passive IGMP Snooping.
• IGMP versions v1,v2 and v3 are supported.
• The device can add a maximum of 64 Multicast groups in the Snooping table.
To configure IGMP Snooping parameters, navigate to ADVANCED CONFIGURATION > IGMP Snooping. The following IGMP
Snooping screen appears:
Figure 5-80 IGMP Snooping
Tabulated below is the table which explains IGMP Snooping parameters and the method to configure the configurable
parameter(s):
Parameter Description
IGMP Snooping Status By default, IGMP Snooping Status is disabled on the device, meaning which, the device
transmits IP multicast traffic to all the ports. To forward the traffic only to the members of
the specific multicast group, enable IGMP Snooping Status.
IGMP Membership Represents the time after which the IGMP multicast group age-outs or elapses. It ranges
Aging Timer from 135 to 635 seconds. The default Aging Timer is 260 seconds.
IGMP Router Port Represents the time after which the IGMP Router port age-outs or elapses. It ranges from
Aging Timer 260 to 635 seconds. The default Aging Timer is 300 seconds.
IGMP Forced Flood If you select Yes, all the unregistered IPv4 multicast traffic (with destination address which
does not match any of the groups announced in earlier IGMP Membership reports) and
IGMP Membership Reports will be flooded to all the ports. By default, IGMP Forced Flood
is set to No.
After configuring the required parameters, click OK and then COMMIT.
5.13 Routing Mode Features
This section provides an overview of all the features applicable in routing mode only.
5.13.1 Static Route Table
The Static Route Table stores the route to various destinations in the network. When packets are to be routed, the routing table
is referred for the destination address.
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To configure the static routing table, navigate to ADVANCED CONFIGURATION > Network > Static Route Table. The Static
Route Table screen appears.
Figure 5-81 Static Route Table
Tabulated below is the table which explains Static Route Table entries and the method to configure the configurable
parameter(s):
Parameter Description
Static Route Status If Static Route Status is enabled, the packets are sent as per route configured in the static
routing table. If disabled, forwards the packet to the default gateway.
Destination Address Represents the destination IP address to which the data has to be routed.
Subnet Mask Represents the subnet mask of the destination IP address to which the data has to be
routed.
Route Next Hop Represents the IP address of the next hop to reach the destination IP address. Next hop IP
should belong to at least one of the subnets connected to the device.
Admin Metric It is a metric that specifies the distance to the destination IP address, usually counted in
hops. The lower the metric, the better. The metrics can range from 0 to 16.
Entry Status If enabled, considers the packets for routing. If disabled, forwards the packet to the
default gateway.
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5.13.1.1 Adding Static Route Entries
Click Add in the Static Route Table screen.The following Static Route Table Add Row screen appears:
Figure 5-82 Static Route Table Add Row
Add the route entries and click Add and then COMMIT.
:
A maximum of 256 routes can be added to the static route table.
The IP address of the Next Hop must be on the subnet of one of the device’s network interfaces.
5.13.2 Network Address Translation (NAT)
: NAT is applicable only to a SU and an End Point B.
The Network Address Translation (NAT) feature allows hosts on the Ethernet side of the SU or End Point B device to
transparently access the public network through the BSU/End Point A device. All the hosts in the private network can have
simultaneous access to the public network.
The SU/End Point B device supports Network Address Port Translation (NAPT) feature, where all the private IP addresses are
mapped to a single public IP address.
The SU/End Point B device supports both dynamic mapping (allowing private hosts to access hosts in the public network) and
static mapping (allowing public hosts to access hosts in the private network) are supported.
1. Static NAT: Static mapping is used to provide inbound access. The SU/End Point B maps the public IP address and its
transport identifiers to the private IP address (local host address) in the local network. This is used to provide inbound
access to a local server for hosts in the public network. Static port mapping allows only one server of a particular type.
A maximum of 100 entries are supported in the static port bind table.
2. Dynamic NAT: In dynamic mapping, the SU/End Point B maps the private IP addresses and its transport identifiers to
transport identifiers of a single Public IP address as they originate sessions to the public network. This is used only for
outbound access.
:
• When NAT is enabled, the network on the wireless side of the device is considered public and the network on the
Ethernet side is considered private.
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• When NAT functionality is enabled, the DHCP Relay and RIP features are not supported. The DHCP Relay Agent and
RIP must be disabled before enabling NAT.
To configure NAT parameters, navigate to ADVANCED CONFIGURATION > Network > NAT. The following NAT screen
appears:
Figure 5-83 NAT
Tabulated below is the table which explains NAT parameters and the method to configure the configurable parameter(s):
Parameter Description
Status This parameter is used to either enable or disable NAT on a SU or an End Point A.
Dynamic Start Port Represents the start and end port sessions originated from private to public host.
and Dynamic End Port
By default, the Dynamic Start Port is configured to 1 and Dynamic End Port is configured to
65535. Configure the start and end port as desired.
: Care should be taken to avoid overlap of Dynamic Port range and Static Port
range.
Port Forwarding This parameter is used to either enable or disable the Static NAT feature within different
Status networks. It allows public hosts to access hosts in a private network. By default, it is
disabled.
After configuring the required parameters, click OK and then COMMIT.
:
• To enable Dynamic NAT, set the NAT Status to Enable. To enable Static NAT, set the NAT Status to Enable and the
Port Forwarding Status to Enable.
• NAT uses the IP address of the wireless interface as the Public IP address.
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To add entries in the NAT Port Bind Table, navigate to ADVANCED CONFIGURATION > Network > NAT > Static Port Bind.
The NAT Port Bind Table screen appears. Click Add in the NAT Port Bind Table screen. The following NAT Port Bind Table Add
Row appears:
Figure 5-84 NAT Port Bind Table Add Row
Tabulated below is the table which explains the NAT Port Bind Table entries and the method to configure the configurable
parameter(s):
Parameter Description
Local Address Enter the local IP Address of the host on the Ethernet (private) side of the SU/End Point B.
Port Type Select the Port Type as: TCP, UDP, or Both.
Start and End Port Represents the start and end port for transferring the data from public to private host.
Number
: Care should be taken to avoid overlap of Dynamic Port range and Static Port
range.
Entry Status If enabled, the data is transferred from the public network to the private host, on the
specified ports.
After configuring the required parameters, click ADD and then COMMIT.
5.13.2.1 Supported Session Protocols
Certain applications require an Application Level Gateway (ALG) to provide the required transparency for an application
running on a host in a private network to connect to its counterpart running on a host in the public network. An ALG may interact
with NAT to set up state information, use NAT state information, modify application-specific payload, and perform the tasks
necessary to get the application running across address realms.
No more than one server of a particular type is supported within the private network behind the SU/End Point B. The
following table lists the supported protocols with their corresponding default ALG's:
S.No. Protocol Support Applications
1 H.323 H.323 ALG Multimedia Conferencing
2 HTTP Port Mapping for inbound connection Web Browser
3 TFTP Port Mapping for inbound connection Trivial file transfer
4 Telnet Port Mapping for inbound connection Remote login
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S.No. Protocol Support Applications
5 IRC Port Mapping for inbound connection Chat and file transfer
6 AMANDA Port Mapping for inbound connection Backup and archiving
7 FTP FTP ALG File Transfer
8 PPTP PPTP ALG VPN related
9 SNMP SNMP ALG Network Management
10 DNS Port Mapping for inbound connection Domain Name Service
5.13.3 RIP
Routing Information Protocol (RIP) is a dynamic routing protocol, which can be used to automatically propagate routing table
information between routers. The device can be configured in RIPv1, RIPv2, or both while operating in Routing mode.
When a router receives a routing update including changes to an entry, it updates its routing table to reflect the new route. RIP
maintains only the best route to a destination. Therefore, whenever new information provides a better route, the old route
information is replaced.
: RIP is configurable only when the devices are in Routing Mode and Network Address Translation (NAT) is disabled.
To configure RIP parameters, navigate to ADVANCED CONFIGURATION > Network > RIP. The following RIP screen
appears:
Figure 5-85 RIP
By default, RIP is not enabled on the device. To enabled, select Enable and click OK. The RIP screen is updated with the
following tabulated parameters:.
Parameter Description
Name Displays the interface type as either Ethernet 1, Ethernet 2, or Wireless.
Status Enables you to either enable or disable RIP for a particular network interface.
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Parameter Description
Authorization Type Enables you to select the appropriate Authorization Type. This parameter is not applicable
if RIP v1 is selected as the Version number.
Authorization Key Enter the authorization key. This parameter is not applicable if RIP v1 is selected as the
Version number. It is not applicable when the Authorization Type is set to None.
Version Number Select RIP Version number from the Version Number list. Available options are V1, V2
and both. The default is V2.
Direction You can enable RIP for both receiving and transmitting the data. To enable RIP only for
Receiving, select Rx Only. To enable RIP for both receiving and transmitting, select Rx and
Tx.
After configuring the required parameters, click OK and then COMMIT.
:
Authorization Type and Authorization Key are valid only for RIPV2 and both versions.
The maximum metric of a RIP network is 15 hops, that is, a maximum of 15 routers can be traversed between a source
and destination network before a network is considered unreachable.
By default, a RIP router will broadcast or multicast its complete routing table for every 30 seconds, regardless of
whether anything has changed.
RIP supports the split horizon, poison reverse and triggered update mechanisms to prevent incorrect routing updates
being propagated.
5.13.4 PPPoE End Point (SU Only)
Proxim’s SU devices support Point-to-Point Protocol over Ethernet (PPPoE) which is a network protocol for transmitting PPP
frames over Ethernet. This feature is commonly used by Internet Service Providers (ISPs) to establish a Digital Subscriber Line (DSL)
Internet service connection with clients.
The Proxim’s SU devices support PPPoE only when they are configured in Routing Mode with NAT enabled. Also, the BSU
should always operate in Bridge Mode.
Figure 5-86 PPPoE Architecture
Given below are the stages for a PPPoE client to establish link with the PPPoE server and then transfer PPP frames over
Ethernet:
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Discovery and Session Stage: In this stage, to initiate a PPPoE session, the PPPoE client discovers a PPPoE server
(called Access Concentrator). Once discovered, a session ID is assigned and a session is established.
Point-to-point Protocol (PPP) Stages: The PPP stage comprises the following sub-stages:
1. Physical Link: For sending and receiving PPP frames, the PPP driver calls the services of PPP Channels (used in
connection with serial links). A PPP channel encapsulates a mechanism for transporting PPP frames from one
machine to another and then the frames are forwarded on the physical Ethernet link.
2. Link Establishment: In this stage, Link Configuration Protocol (LCP) performs the basic setup of the link. As part
of this setup, the configuration process is undertaken whereby the PPPoE client and the server negotiate and
agree on the parameters on how data should be passed between them. Only when both the client and server
come to an agreement, the link is considered to be open and will proceed to the Authentication stage.
3. Authentication: In this stage, LCP invokes an authentication protocol (PAP/CHAP/MS CHAP v2/EAP-MD5) when
PPP is configured to use authentication.
4. Encryption: In this stage, both PPPoE client and server negotiate the encryption protocol configuration. Our
device support MPPE as encryption protocol. MPPE is negotiated within option 18 in the PPP Compression Control
Protocol (CCP).
5. Network Layer Protocol: After successful authentication, the link proceeds to the Network-Layer Protocol stage.
In this stage, the specific configuration of the appropriate network layer protocol is performed by invoking the
appropriate Network Control Protocol (NCP) such as IPCP. We support only IPCP Protocol as a part of NCP.
Given below are the features supported by PPPoE client:
Preferred Server Configuration by using Access Concentrator Name/Service Name
PAP/CHAP/MSCHAP v2/EAP-MD5 Authentication Protocols
IP Configuration: Static IP/ PPPoE-IPCP
Echo Interval and Echo Failure to detect server unavailability
MPPE with stateful and stateless mode aligned with 40/56/128 bit encryption
To configure PPPoE feature,
1. Navigate to ADVANCED CONFIGURATION > Network > PPPoE > PPPoE Client. The following PPPoE Client
screen appears:
Figure 5-87 PPPoE Client Status
2. By default, the PPPoE feature is disabled on the client. To enable, select Enable from Status drop-down box.
3. Next, click OK. Please note that a change in the PPPoE client status requires you to reboot the device.
4. On enabling the PPPoE client feature, the following screen appears:
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Figure 5-88 PPPoE Client Configuration
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5. Tabulated below is the table which explains PPPoE client parameters and the method to configure the configurable
parameter(s):
Parameter Description
Authentication PPPoE supports the following types of user authentication protocols that provide
Protocol varying levels of security:
None: Represents that no authentication is required for transferring PPP frames
over Ethernet between PPPoE client and server.
Password Authentication Protocol (PAP): PAP is an access control protocol
used to authenticate client’s password on the server. The server requests a
password from the client and sends the retrieved password to an authentication
server for verification. As an authentication protocol, PAP is considered the least
secure because the password is not encrypted in transmission.
Challenge Handshake Authentication Protocol (CHAP): CHAP is similar to
PAP with several unique characteristics. Instead of requesting a password, the
server sends a challenge message to the client. The challenge message is a
random value. The client encrypts the challenge message with user's password
and sends the combination back to the server. The server forwards the
challenge/password combination to the authentication server. The
authentication server encrypts the challenge with the user's password stored in
the authentication database. If the user's response is a match, the password is
considered authentic. CHAP uses the model of a shared secret (the user
password) to authenticate the user. The use of CHAP is considered a moderately
secure method of authentication.
Microsoft Challenge-Handshake Authentication Protocol version 2
(MSCHAP v2): MSCHAP V2 is a mutual authentication method that supports
password-based user or computer authentication. During the MSCHAP v2
authentication process, both the client and the server prove that they have
knowledge of the user's password for authentication to succeed. Mutual
authentication is provided by including an authenticator packet returned to the client
after a successful server authentication.This method is proprietary to the Microsoft
mostly used in windows servers and client.
EAP-MD5: EAP-MD5 enables a server to authenticate a connection request by
verifying an MD5 hash of a user's password. The server sends the client a
random challenge value, and the client proves its identity by hashing the
challenge and its password with MD5.
By default, the authentication protocol is set to CHAP. You can configure the
authentication protocol to the desired one and click OK.
LCP Echo Interval
To check the link connection, periodically the PPPoE client sends an LCP echo-request
frame to the PPPoE server. If the PPPoE server respond to the echo-request by sending an
echo-reply, then the connection is alive.
To configure LCP Echo Interval, enter a time ranging from 5 to 300 seconds. By
default, the echo interval is set to 30 seconds.
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Parameter Description
LCP Echo Failure This parameter indicates the maximum number of consecutive failures to receive the
LCP echo-reply to consider the connection to be down.
To configure LCP Echo Failure value, enter a a value ranging from 1 to 25. By default, the
echo failure is set to 5. On a noisy wireless link, it is recommended to set this
value to higher.
Preferred Service Specifies the service which the PPPoE server (Access Concentrators) provides to the
Name PPPoE client.
Leave this parameter blank, if PPPoE client accepts any service offered by the PPPoE
server. To specify the desired service name, enter the service name ranging from 1 to
32 characters.
Access Concentrator Specifies Access Concentrator (PPPoE server) name.
Name
Leave this parameter blank, when PPPoE client can connect to any PPPoE server on the
network. To connect to a desired PPPoE server, type the server name ranging from 1
to 32 characters.
User Name and Before establishing a link, the PPPoE server first authenticates the PPPoE client based
Password on the User Name and Password as shared by the service provider.
Type the user name and password in the User Name and Password box respectively. You
can type user name ranging from 4 to 32 characters and password ranging from 6 to 32
characters.
: User Name and Password parameters are not applicable when the
Authentication Protocol is configured as “None”.
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Parameter Description
MPPE Status
: MPPE Status parameter is applicable only when the Authentication Protocol is
configured as “MSCHAP v2”.
Microsoft Point-to-Point Encryption (MPPE) is a protocol for transferring encrypted
data over point-to-point links. The PPPoE client negotiates on the encryption
parameters based on the MPPE Status configured.
The MPPE Status can be configured as following:
Mandatory: When the MPPE status is configured as Mandatory, the PPPoE
client negotiates the configured MPPE parameters with the PPPoE server. If the
server does not agree to the parameters then the link will not be established.
Optional: When the MPPE status is configured as Optional, the link is
established with or without encryption depending on the PPPoE server
configuration. If the PPPoE server supports MPPE encryption then the PPPoE
client agrees with the PPPoE server’s MPPE parameters and link gets established with
encryption. If the PPPoE server does not support MPPE encryption then link gets
established without encryption.
Disable: When the MPPE status is configured as Disable, then the PPPoE client
does not agree to the MPPE parameters suggested by the PPPoE server.
Configure the desired status and click OK.
Stateless Encryption
Mode : This parameter is applicable only when Authentication Protocol is
configured as “MSCHAP v2” and MPPE Status is configured as
“Mandatory”.
When stateless encryption is negotiated, the session key changes for every packet
transferred. In stateless mode, the sender must change its key before encrypting and
transmitting each packet and the receiver must change its key after receiving, but before
decrypting, each packet.
When stateful encryption is negotiated, the PPPoE server and the client monitor the
synchronization of MPP encryption engine on both the sides. When one of the peer
detects that they are out of sync then the peer should transmit a packet with the
coherency count set to 0xFF(a flag packet); the sender must change its key before
encrypting and transmitting any packet and the receiver must change its key after
receiving a flag packet, but before decrypting.
To enable stateless encryption, select Enable. To enable stateful encryption, select
Disable.
: Enabling Stateless Encryption impacts throughput. It is useful to enable
Stateless encryption when packet drops are more in the wireless link.
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Parameter Description
MPPE Key Length
: This parameter is applicable only when Authentication Protocol is
configured as “MSCHAP v2” and MPPE Status is configured as
“Mandatory”.
MPPE supports 40-bit, 56-bit and 128-bit encryption key length. To configure the
desired key length, select a key length from the MPPE Key Length drop-down box.
Link Status Indicates the status of the PPPoE link between the PPPoE client and server.
The link can be in any of the following three stages:
Disconnected: No connection is established between PPPoE client and server.
Connecting: A connection attempt is in progress between PPPoE client and
server.
Connected: Connection is established between PPPoE client and server.
The Link Status can be viewed in Home Page.
6. After configuring the required parameters, click OK and then COMMIT. Reboot the device, if you have changed the
PPPoE Status configuration.
5.13.5 IP over IP Tunneling
Proxim’s point-to-multipoint and point-to-point devices support IP Tunnelling, which serves as a communication channel
between two disjoint IP networks that do not have a native routing path to communicate with each other.
To enable communication between two disjoint networks using IP Tunneling, the following steps are involved:
1. The tunnel entry point receives the IP packet (Sender Source IP + Recipient IP) sent by the original sender.
IP Packet
Sender Source IP Recipient IP
2. The tunnel entry point encapsulates the IP packet (Sender Source IP + Recipient IP) with the IP addresses of the tunnel
endpoints. The tunneled packet (Sender Source IP + Recipient IP + Tunnel Entry Point IP + Tunnel Exit Point IP) is then
forwarded to the tunnel exit point.
Tunneled IP Packet
(Inner IP Header) (Outer IP Header)
Sender Source IP Recipient IP Tunnel Entry Point IP Tunnel Exit Point IP
3. On receiving the tunneled packet, the tunnel exit point removes the tunnel IP addresses and forwards the packet to
the recipient. The inner IP header Source Address and Destination Address identify the original sender and recipient of
the packet, respectively. The outer IP header Source Address and Destination Address identify the endpoints of the
tunnel.
The following figure shows an IP tunnel configuration using two end points.
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Figure 5-89 An Example: Tunnel Configuration
Lets say that the Computer with an IP address: 10.0.0.1 wants to communicate with the Computer with an IP address:
192.168.9.101. Since there is no native routing path between these two computers, the communication can happen via the tunnel.
The SU1device with wireless IP address: 20.0.0.132 and SU2 device with wireless IP address: 30.0.0.132 are the end points of the
tunnel, respectively.
With IP tunneling, the tunnel entry point (SU1) encapsulates the tunnel end points IP addresses (20.0.0.132 + 30.0.0.132) with
the sender IP addresses (10.0.0.1 + 192.168.9.101) before sending the data through the tunnel. When the tunnel exit point (SU2)
receives traffic, it removes the outer IP header before forwarding the packet to the recipient.
IP Packet
Sender Source IP (10.0.0.1) Recipient IP (192.168.9.101)
Tunneled IP Packet
(Inner IP Header) (Outer IP Header)
Sender Source IP Recipient IP Tunnel Entry Point IP Tunnel Exit Point IP
(10.0.0.1) (192.168.9.101) (20.0.0.132) (30.0.0.132)
: IP tunnel establishment does not involve any protocol message exchange. To setup an IP tunnel, the device has to be
configured properly on both the ends.
By following the steps below, the tunnel is automatically established.
1. Create a tunnel (Refer to Create a Tunnel)
To create a tunnel as given in Figure 5-89, do the following: SU1
Configuration
— Virtual IP Address = 50.0.0.1
— Local IP Address = 20.0.0.132
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— Remote IP Address = 30.0.0.132
SU2 Configuration
— Virtual IP address = 50.0.0.2
— Local IP Address = 30.0.0.132
— Remote IP Address = 20.0.0.132
2. Add a Static Route for Remote IP Address of the tunnel (Refer to Static Route Table)
On SU1, add a static route for 30.0.0.xxx as next hop 20.0.0.1
On SU2, add a static route for 20.0.0.xxx as next hop 30.0.0.1
3. Add a route for the pass-through traffic through the tunnel (Next Hop IP Address should be that of the tunnel
interface).
On SU1, add a static route for 192.168.9.xxx as next hop 50.0.0.1
On SU2, add a static route for 10.0.0.xxx as next hop 50.0.0.2
5.13.5.1 Create a Tunnel
To create a Tunnel interface,
1. Navigate to ADVANCED CONFIGURATION > Network > IP Tunneling. The following IP Tunneling screen appears:
Figure 5-90 IP Tunneling Status
2. By default, the IP Tunneling feature is disabled on the device. To enable, select Enable from the Tunneling Status
drop-down box.
3. Next, click OK.
4. On enabling the IP Tunneling feature, the following screen appears:
Figure 5-91 IP Tunneling Interfaces
5. Click Add, to create a new tunnel interface. The following Tunneling Table Add Row screen appears:
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Figure 5-92 Adding a new Tunnel Interface
6. Tabulated below is the table which explains the parameters for creating a new tunnel:
Parameter Description
Name Represents the name of the tunnel interface. Type a name for the tunnel interface.
Encapsulation The device supports two types of network tunnels:
Method ipip: A tunnelling protocol that allow only IP traffic over the tunnel.
gre (Generic Routing Encapsulation): A tunneling protocol that allows
encapsulation of a wide variety of packet types in Internet Protocol (IP)
packets, thereby creating a virtual point-to-point link.
Select the tunnel type as either ipip or gre.
Virtual IP Address Represents the virtual IP address of the tunnel interface. Enter the virtual IP address of
the tunnel interface.
Local IP Address Represents the IP address of the tunnel entry point. Select the IP address of the tunnel
entry point from the available list of addresses.
Remote IP Address
Represents the IP address of the tunnel exit point. Type the IP address of the tunnel
exit point. Please note that the Remote IP address should be routable.
TTL TTL stands for Time to Live. This parameter enables to configure a fixed TTL value on
the tunneled packets. The TTL value can be configured in the range 0 to 255. By
default, the TTL value is set to 0 meaning that tunneled packets inherit the TTL value from
the IP packet originated by the sender.
Entry Status By using this parameter, a tunnel interface can be enabled or disabled. By default, it is
enabled. To disable, select Disable.
7. Next, click Add.
:
• A maximum of 16 tunnels can be created on a device.
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• The Maximum Transmission Unit (MTU) of the tunnel interface depends on the underlying interface.
• It is advised that both PPPoE and the IP Tunneling feature do not function simultaneously on the device.
• IP configuration of Ethernet and Wireless interface should NOT be in the same subnet of virtual IP addresses of
tunnels.
5.13.5.2 View Existing Tunnels
The IP Tunneling screen displays all the tunnels created on the device. The entries against each tunnel cannot be edited.
However, the status of each tunnel entry can be modified.
You can either enable, disable or delete a tunnel by selecting the desired one from Entry Status box in the IP Tunneling
screen.
Figure 5-93 IP Tunneling Interfaces
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6
Management
This chapter provides information on how to manage the device by using Web interface. It contains information on the
following:
System
File Management
Services
Simple Network Time Protocol (SNTP)
Access Control
Reset to Factory
Convert QB to MP
6.1 System
The System tab enables you to configure system specific information such as System Name, contact information of the
person managing the device, and view system inventory and license information.
6.1.1 System Information
The System Information tab enables you to view and configure system specific information such as System Name, System
Description, Contact Details of the person managing the device, and so on.
To view and configure system specific Information, navigate to MANAGEMENT > System > Information. The System
Information screen appears:
Figure 6-1 System Information
Tabulated below is the table which explains System parameters and the method to configure the configurable parameter(s):
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Parameter Description
System Up-Time This is a read-only parameter. It represents the operational time of the device since its last
reboot.
System Description This is a read-only parameter. It provides system description such as system name,
firmware version and the latest firmware build supported.
For example: Tsunami MP-8100-BSU-WD-v2.4.0
System Name Represents the name assigned to the device. You can enter a system name of maximum 64
characters.
Email Represents the email address of the person administering the device. You can enter an
email address of minimum 6 and maximum 32 characters.
Phone Number Represents the phone number of the person administering the device. You can enter a
phone number of minimum 6 and maximum 32 characters.
Location Represents the location where the device is installed. You can enter the location name of
minimum 0 and maximum 255 characters.
GPS Longitude Represents the longitude at which the device is installed. You can enter a longitude value
of minimum 0 and maximum 255 characters.
GPS Latitude Represents the latitude at which the device is installed. You can enter a latitude value of
minimum 0 and maximum 255 characters.
GPS Altitude Represents the altitude at which the device is installed. You can enter a altitude value of
minimum 0 and maximum 255 characters.
After configuring the required parameters, click OK and then COMMIT.
6.1.2 Inventory Management
The Inventory Management tab provides inventory information about the device.
To view inventory information, navigate to MANAGEMENT > System > Inventory Management. The System Inventory
Management Table appears.
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Figure 6-2 Inventory Management
By default, the components information is auto-generated by the device and is used only for reference purpose. Click
Refresh, to view the updated system inventory management information.
6.1.3 Licensed Features
Licensing is considered to be the most important component of an enterprise-class device which typically has a feature-based
pricing model. It is also required to prevent the misuse and tampering of the device by a wide-variety of audience whose
motives may be intentional or accidental.
Licensed Features are, by default, set by the company.
To view the licensed features set on the device, click MANAGEMENT > System > Licensed Features. The Licensed
Features screen appears.
Figure 6-3 Licensed Features
Tabulated below is the table which explains each of the parameters:
Parameter Description
Product Description Description about the device.
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Parameter Description
Number of Radios The number of radios that the device is licensed to operate.
Number of Ethernet The number of Ethernet interfaces supported by the device.
Interfaces
Radio 1 Allowed The operational frequency band supported by the device radio.
Frequency Band
Maximum Output The maximum output bandwidth limit of the device. It is represented in mbps.
Bandwidth
Maximum Input The maximum input bandwidth limit of the device. It is represented in mbps.
Bandwidth
: The Input and Output Bandwidth features are referred with respect to the
wireless interface. Input bandwidth refers to the data received on the wireless
interface and output bandwidth refers to the data sent out of the wireless
interface.
Maximum Aggregate The maximum cumulative bandwidth of the device, which is the sum of configured output
Bandwidth and input bandwidths.
Product Family Represents the product family of the device.
Product Class Represents the product class of the device, which is either indoor or outdoor.
Allowed Operational Represents the operational mode of the device, that is, BSU/SU/End Point A/End Point B.
Modes of Radio1
Maximum SUs The maximum number of SUs that a BSU supports.
Allowed
MAC address of the The MAC address of the device.
Device is
6.2 File Management
The
File Management
tab enables you to upgrade the firmware and configuration files onto the device, and retrieve
configuration and log files from the device through Hypertext Transfer Protocol (HTTP) and Trivial File Transfer Protocol (TFTP).
6.2.1 TFTP Server
A Trivial File Transfer Protocol (TFTP) server lets you transfer files across a network. By using TFTP, you can retrieve files from the
device for backup or copying, and you can upgrade the firmware or the configuration files onto the device. You can download
the SolarWinds TFTP server application from http://support.proxim.com. You can also download the latest TFTP software from
SolarWinds Web site at http://www.solarwinds.net.
While using TFTP server, ensure the following:
The upload or download directory is correctly set (the default directory is C:\TFTP-Root).
The required firmware file is present in the directory.
The TFTP server is running during file upload and download. You can check the connectivity between the device and
the TFTP server by pinging the device from the Personal Computer that hosts the TFTP server. The ping program
should show replies from the device.
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The TFTP server should be configured to transmit and receive files (on the Security tab under File > Configure), with
no automatic shutdown or time-out (on the Auto-Close tab).
: The instructions listed above are based on the assumption that you are using the SolarWinds TFTP server; otherwise the
configuration may vary.
6.2.2 Text Based Configuration (TBC) File Management
Text Based Configuration (TBC) file is a simple text file that holds device template configurations. The device supports the TBC file in
XML format which can be edited in any XML or text editors.
You can generate the TBC file from the CLI Session and manually edit the configurations and then load the edited TBC file to the
device so that the edited configurations are applied onto the device. It differs mainly from the binary configuration file in terms of
manual edition of configurations. The generated TBC file is a template which has only the default and modified configurations
on the live CLI session.
6.2.2.1 Generating TBC File
The TBC file is generated through CLI by executing generate command.
While generating the TBC file from CLI, there is an option to generate it with or without all Management and Security
Passwords. The management passwords include CLI/WEB/SNMP passwords. The security passwords include
Network-Secret/Encryption-Key(s)/RADIUS-Shared-Secret. If included, these passwords become a part of the generated TBC file
and are in a readable form. If excluded, all these passwords are not part of the generated TBC file.
The commands used for the generation of TBC file are:
T8000-00:00:01# generate tbc-with-pwds
T8000-00:00:01# generate tbc-without-pwds
The generated TBC file contains,
• Default configurations
Any user-added or edited configurations on current live CLI session
The generated Text Based Template Configuration file appears as shown below:
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Figure 6-4 TBC File in xml Format
6.2.2.2 Editing the TBC File
The TBC file can easily be opened and edited in any standard Text-Editors like Wordpad, MS-Word, Notepad++, Standard XML
Editors. Proxim recommends XML Notepad 7 editor for editing the TBC file.
You can modify any value between the double quotes(““) in the TBC file. It is recommended not to change the text
outside the double quotes (“”) or XML tags in the TBC file.
Remove unchanged configurations from the TBC file before loading onto the device.
6.2.2.3 Loading the TBC file
The TBC file can be loaded onto the device by using either SNMP, Web Interface or CLI. You can either use TFTP or HTTP to
load the TBC file.
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By using Web Interface, you can load the TBC file by navigating to
MANAGEMENT > File Management > Upgrade
Configuration. To load the TBC file, it should be generated or downloaded onto the device. While loading the TBC file onto the
device, any file name is accepted. Once loaded, the TBC file name is renamed to PXM-TBC.xml.
If the TBC file does not contain correct XML syntax, the file will be discarded with DOM error and no configurations will be loaded.
All duplicate values entered are considered as errors while loading and syslogs will be generated accordingly. Therefore, it is
recommended to delete all unchanged parameters from the TBC file during its edition. Commit is required to retain the
configurations across reboots after loading the TBC file.
: Both Commit and Reboot are required to accept the modifications done in the TBC File. Only reboot is required to reject
the modifications.
Loading the TBC file is allowed only once in an active device session (that is, if TBC file is loaded, reboot is required to apply all
configurations or to load another TBC file). All configurations in the TBC file are loaded to the device irrespective of their default
or modified or added configurations. Loading the TBC file takes approximately 10-20 seconds depending on the number of
configurations added.
:
• Remove any unmodified parameters from the TBC file, before loading it.
• If you get any timeout errors while loading TBC file from SNMP interface, increase the time-out value to more than 30
seconds in the MIB Browser.
6.2.3 Upgrade Firmware
You can update the device with the latest firmware either through HTTP or TFTP.
: Make sure the firmware being loaded is compatible to the device being upgraded.
6.2.3.1 Upgrade Firmware via HTTP
To upgrade the firmware via HTTP, do the following:
1. Navigate to MANAGEMENT > File Management > Upgrade Firmware > HTTP.
Figure 6-5 Upgrade Firmware - HTTP
2. In the HTTP screen, click Browse to select the latest firmware file from the desired location. Ensure that the file name
does not contain any space or special characters.
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3. Click
Update
.
4. Once the update successfully completes, reboot the device.
6.2.3.2 Upgrade Firmware via TFTP
To upgrade the firmware via TFTP Server, do the following:
1. Navigate to MANAGEMENT > File Management > Upgrade Firmware > TFTP.
Figure 6-6 Upgrade Firmware - TFTP
2. Enter the TFTP Server IP Address in the Server IP Address box.
3. Enter the name of the latest firmware file (including the file extension) that has to be loaded onto the device in the
File Name box.
4. To update the device with new firmware, click either Update, or Update & Reboot. If you click Update, then you
should reboot the device after loading the files. Whereas, if you click
Update and Reboot
, the system will
automatically reboot the device after loading the files.
:
After updating the device with the new firmware, reboot the device; Otherwise the device will continue to run
with the old firmware.
It is recommended not to navigate away from the upgrade screen, while the update is in progress.
6.2.4 Upgrade Configuration
You can update the device with the latest configuration files either through HTTP or TFTP.
: Make sure the configuration file being loaded into the device is compatible. That is, the configuration file being
loaded should have been retrieved from a device of the same SKU.
6.2.4.1 Upgrade Configuration via HTTP
To upgrade the configuration files by using HTTP, do the following:
1. Navigate to MANAGEMENT > File Management > Upgrade Configuration > HTTP.
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Figure 6-7 Upgrade Configuration - HTTP
2. In the HTTP screen, click Browse to locate the configuration file. Select Flashcfg.cfg for Binary Configuration file and
PXM-TBC.xml for Text Based Configuration file. Make sure that the file name does not contain any space or special
characters.
3. If you are updating the device with Binary Configuration file then click Update and then reboot the device.
4. If you are updating the device with Text Based Configuration file then,
a. Click Update to update the device with the config file and then click Load for loading the config file onto the
device. Alternatively, you can perform both update and load operation in one single step, by clicking Update
& Load.
b. For the changes to take effect, click COMMIT and then REBOOT.
6.2.4.2 Upgrade Configuration via TFTP
To upgrade the configuration files by using TFTP Server, do the following:
1. Navigate to MANAGEMENT > File Management > Update Configuration > TFTP.
Figure 6-8 Upgrade Binary Configuration via TFTP
2. You can update the device with two configuration files: Binary and Text Based. To update the device with Binary
Configuration file, select Binary Config.
Enter the TFTP server IP Address in the Server IP Address box.
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Enter the name of the Binary file (including the file extension) that has to be downloaded onto the device in the
File Name box.
3. To update the device with Text Based Configuration files, select Text Based Config.
Enter the TFTP server IP Address in the Server IP Address box.
Enter the name of the Text Based file (including the file extension) that has to be downloaded onto the device in
the File Name box.
Figure 6-9 Upgrade Text Based Configuration via TFTP
4. If you are updating the device with Binary Configuration file then click
Update
and then reboot the device or
alternatively click Update & Reboot.
5. If you are updating the device with Text Based Configuration file then
• Click Update to copy the text config file onto the device and then click Load for updating the device with text
config file.
Alternatively, you can perform both update and load operation in one single step, by clicking Update & Load.
For the changes to take effect, click COMMIT and then REBOOT.
: It is recommended not to navigate away from the upgrade screen, while the update is in progress.
6.2.5 Retrieve From Device
The Retrieve From Device tab allows you to retrieve logs and config files from the device either through HTTP or TFTP.
6.2.5.1 Retrieve from Device via HTTP
To retrieve files from the device by using HTTP, do the following:
1. Navigate to MANAGEMENT > File Management > Retrieve from Device > HTTP.
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Figure 6-10 Retrieve Files via HTTP
2. Select the type of file that you want to retrieve from the device from the File Type drop down box. The files may vary
depending on your device.
3. Click Retrieve. Based on the selected file, the following Download screen appears.
Figure 6-11 Download Screen
4. Right-click the Download link and select Save Target As or Save Link As to save the file to the desired location.
6.2.5.2 TFTP Retrieve
To retrieve files from the device by using TFTP, do the following:
1. Navigate to MANAGEMENT > File Management > Retrieve from Device > TFTP.
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Figure 6-12 Retrieve Files via TFTP
2. Enter the TFTP server IP Address in the Server IP Address box.
3. Enter the name of the file (including the file extension) that has to be retrieved from the device, in the File Name box.
4. Select the file type that you want to retrieve from the device, from the File Type drop down box.
5. Click Retrieve. The retrieved file can be found in the TFTP Server folder.
• When the device is running with default factory settings, there is no Binary Configuration file present and hence it cannot
be retrieved.
• Similarly, the Text Based Template Configuration file does not exist if it is not generated from the CLI.
• You can retrieve Event Logs only when they are generated by the device.
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6.3 Services
The Services tab lets you configure the HTTP/HTTPS, Telnet/SSH and SNMP interface parameters.
6.3.1 HTTP/HTTPS
To configure HTTP/HTTPS interface parameters, navigate to MANAGEMENT > Services > HTTP / HTTPS.
Figure 6-13 HTTP/HTTPS
Tabulated below is the table which explains HTTP/HTTPS parameters and the method to configure the configurable
parameter(s).
Parameter Description
Admin Password By default, the Administrator password to access HTTP/HTTPS interface is public. For
security reasons, it is recommended to change the default password. The password should be
alphanumeric with minimum of 6 and maximum of 32 characters.
: The following special characters are not allowed in the password:
- = \ “ ‘ ? / space
Monitor Password The Administrator user has the privilege to change the Monitor user password. By default,
the Monitor user password to access HTTP/HTTPS interface is
public
. For security reasons it
is
recommended to change the default password. The password should be alphanumeric with
minimum of 6 and maximum of 32 characters.
: The following special characters are not allowed in the password:
- = \ “ ‘ ? / space
HTTP By default, a user can manage the device through Web Interface. To prevent access to the
device through Web Interface, select Disable.
HTTP Port Represents the HTTP port to manage the device using Web Interface. By default, the HTTP
port is 80.
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Parameter Description
HTTPS By default, a user can manage the device through Web Interface over secure socket Layer
(HTTPS). To prevent access to the device through HTTPS, select
Disable
.
: The password configuration for HTTPS is same as configured for HTTP.
After configuring the required parameters, click OK, COMMIT and then REBOOT.
6.3.2 Telnet/SSH
To configure Telnet/SSH interface parameters, navigate to MANAGEMENT > Services > Telnet / SSH.
Figure 6-14 Telnet/SSH
Tabulated below is the table which explains Telnet/SSH parameters and the method to configure the configurable
parameter(s):
Parameter Description
Admin Password By default, the Administrator password to access Telnet/SSH interface is public. For
security reasons, it is recommended to change the default password. The password should be
alphanumeric with minimum of 6 and maximum of 32 characters.
: The following special characters are not allowed in the password:
- = \ “ ‘ ? / space
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Monitor Password The Administrator user has the privilege to change the Monitor user password. By default,
the Monitor user password to access Telnet/SSH interface is public. For security reasons it is
recommended to change the default password. The password should be alphanumeric with
minimum of 6 and maximum of 32 characters.
: The following special characters are not allowed in the password:
- = \ “ ‘ ? / space
Telnet By default, a user can manage the device through Telnet. To prevent access to the device
through Telnet, select Disable.
Telnet Port Represents the port to manage the device using Telnet. By default, the Telnet port is 23.
Telnet Sessions The number of Telnet sessions which controls the number of active Telnet connections. A
user is restricted to configure a maximum of 3 Telnet sessions. By default, the number of
Telnet sessions allowed is 2.
SSH By default, a user can manage the device through SSH. To prevent access to the device
through SSH, select Disable.
SSH Port Represents the port to manage the device using Secure Shell. By default, the Secure Shell
port is 22.
SSH Sessions The number of SSH sessions which controls the number of active SSH connections. A user
is restricted to configure a maximum of 3 SSH sessions. By default, the number of SSH
sessions allowed is 1.
: The total number of CLI sessions allowed is 3, so the sum of Telnet and SSH
sessions cannot be more than 3. For example, if you configure the number of
Telnet sessions as 2, then the number of SSH sessions can only be a value 0 or 1.
After configuring the required parameters, click OK, COMMIT and then REBOOT.
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6.3.3 SNMP
To configure SNMP interface parameters, navigate to MANAGEMENT > Services > SNMP.
Figure 6-15 SNMPv1-v2c
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Figure 6-16 SNMPv3
Tabulated below is the table which explains SNMP parameters and the method to configure the configurable parameter(s):
Parameter Description
SNMP By default, the user has the access to manage the device through SNMP Interface. To
prevent access to the device through SNMP, select Disable.
: Any change in the SNMP status will affect the Network Management System
access.
Version Allows you to configure the SNMP version. The supported SNMP versions are v1-v2c and
v3. By default, the SNMP version is v1-v2c.
SNMP v1-v2c Specific Parameters
Read Password
Represents the read only community string used in SNMP Protocol. It is sent along with
each SNMP GET / WALK / GETNEXT / GETBULK request to allow or deny access to the
device. This password should be same as read password set at the NMS or MIB browser.
The default password is “public”. The password should be of minimum 6 and maximum
32 characters.
: The following special characters are not allowed in the password:
- = \ “ ‘ ? / space
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Read/Write Password Represents the read-write community string used in SNMP Protocol. It is sent along with
each SNMP GET / WALK / GETNEXT / SET request to allow or deny access to the device.
This password should be same as read-write password set at the NMS or MIB browser. The
default password is “public”. The password should be of minimum 6 and maximum 32
characters.
: The following special characters are not allowed in the password:
- = \ “ ‘ ? / space
SNMP v3 Specific Parameters
Security level The supported security levels for the device are AuthNoPriv and AuthPriv. Select
AuthNoPriv for Extensible Authentication or AuthPriv for both Authentication and
Privacy (Encryption).
Priv Protocol Applicable only when the Security Level is set to AuthPriv.
Represents the type of privacy (or encryption) protocol. Select the encryption standard as
either AES-128 (Advanced Encryption Standard) or DES (Data Encryption Standard). The
default Priv Protocol is AES-128.
: The following special characters are not allowed in the password:
- = \ “ ‘ ? / space
Priv Password Applicable only when the Security Level is set to AuthPriv.
Represents the pass key for the selected Privacy protocol. The default password is
public123. The password should be of minimum 8 and maximum 32 characters.
: The following special characters are not allowed in the password:
- = \ “ ‘ ? / space
Auth Protocol Represents the type of Authentication protocol. Select the encryption standard as either
SHA (Secure Hash Algorithm) or MD5 (Message-Digest algorithm). The default Auth
Protocol is SHA.
Auth Password Represents the pass key for the selected Authentication protocol. The default password is
public123. The password should be of minimum 8 and maximum 32 characters.
After configuring the required parameters, click OK, COMMIT and then REBOOT.
6.3.3.1 SNMP Trap Host Table
The SNMP Trap Host table allows you to add a maximum of 5 Trap server’s IP address to which the SNMP traps will be
delivered. By default, the SNMP traps are delivered to 169.254.128.133.
: The default SNMP Trap Host Table entry cannot be deleted.
To add entries to the Trap Host Table, click Add in the Services screen. The SNMP Trap Host Table Add Row screen
appears:
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Figure 6-17 Add Entries to SNMP Host Table
Configure the following parameters:
IP Address: Type the IP address of the Trap server to which SNMP traps will be delivered.
Password: Type the password to authenticate the Trap Server. The following special characters are not allowed in the
password: - = \ “ ‘ ? / space
: Applicable only to SNMP v1-v2c.
Comment: Type comments, if any.
Entry Status: Select the entry status as either Enable or Disable. If enabled, the device will send SNMP traps to the
authenticated Trap Server.
After configuring the required parameters, click Add and then COMMIT.
6.3.3.2 Edit SNMP Trap Host Table
Edit the desired SNMP Trap Host Table entries and click OK, COMMIT and then REBOOT.
6.3.4 Logs
The device supports two types of log mechanisms:
1. Event Log: Based on the configured event log priority, all the log messages are logged and used for any analysis. This
log messages remain until they are cleared by the user.
2. Syslog: They are similar to Event logs except that they are cleared on device reboot.
To configure Event log and Syslog priority, navigate to MANAGEMENT > Services > Logs. The following screen appears:
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Figure 6-18 Logs
Event Log Priority: By default, the priority is set to Notice. You can configure the event log priority as one of the
following:
- Emergency
- Alert
- Critical
- Error
- Warning
- Notice
- Info
- Debug
Please note that the priorities are listed in the order of their severity, where Emergency takes the highest severity and
Debug the lowest. When the log priority is configured as high, all the logs with low priority are also logged. For example,
if Event Log Priority is set to Notice, then the device will log all logs with priorities Notice, Warning, Error, Critical, Alert
and Emergency.
Syslog Status: By default, Syslog Status is enabled and default priority is Critical. If desired, you can choose to
disable.
Syslog Priority: Configuration is same as Event Log Priority.
After configuring the required parameters, click OK and then COMMIT.
6.3.4.1 Configure a Remote Syslog host
To forward the syslog messages to a remote syslog host, do the following:
1. Click Add in the Syslog Host Table screen. The Syslog Host Table Add Row screen appears:
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Figure 6-19 Syslog Host Table Add Row
2. IP Address: Enter the IP address of the Syslog host.
3. Host Port: Represents the port on which the Syslog host listens to the log messages sent by the device. The default
port is 514.
: The user must configure the correct port number on which the Syslog host is running. Choice of port number must
be in line with the standards for port number assignments defined by Internet Assigned Numbers
Authority (IANA).
4. Comments: Types comments, if any.
5. Entry Status: By default, the configured Syslog host is enabled on the device. To delete the configured Syslog host,
click Delete. To disable an entry in the Syslog Host Table, click Disable.
6. Click
Add
.
7. Click OK and then COMMIT.
6.4 Simple Network Time Protocol (SNTP)
Proxim’s point-to-multipoint and point-to-point devices are furnished with Simple Network Time Protocol (SNTP) Client
software that enables to synchronize device’s time with the network time servers.
The SNTP Client when enabled on the device(s), sends an NTP (Network Time Protocol) request to the configured time servers.
Upon receiving the NTP response, it decodes the response and sets the received date and time on the device after adjusting the
time zone and day light saving.
In case, the time servers are not available, then users also have the option to manually set the date and time on the device.
To synchronize device’s time with time servers or manually set the time, navigate to MANAGEMENT > SNTP. The SNTP
screen
appears:
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Figure 6-20 Time Synchronization
Tabulated below is the table which explains SNTP parameters and the method to configure the configurable parameter(s):
Parameter Description
Enable SNTP Status Select this parameter to enable SNTP Client on the device. If enabled, the SNTP Client tries
to synchronize the device’s time with the configured time servers.
By default, the SNTP status is disabled.
Primary Server IP Enter the host name or the IP address of the primary SNTP time server. The SNTP Client
Address/Domain tries to synchronize device’s time with the configured primary server time.
Name
: If host name is configured, instead of IP address then make sure that DNS server
IP is configured on the device.
Secondary Server IP Enter the host name or the IP address of the secondary SNTP time server. If the primary
Address/Domain server is not reachable, then SNTP client tries to synchronize device’s time with the
Name secondary server time.
: If the SNTP Client is not able to sychronize the time with both the servers
(primary and secondary), then it tries to synchronize again after every one
minute.
Time Zone Configure the time zone from the available list. This configured time zone is considered
before setting the time, received from the time servers, on the device.
Day Light Saving Time Configure the Day Light Saving time from the available list. This configured Day Light
Saving time is considered before setting the time, received from the time servers, on the
device.
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Parameter Description
ReSync Interval Set ReSync time interval ranging from 0 to 1440 minutes. Once the time is synchronized,
the SNTP Client tries to resynchronize with the time servers after every set time interval.
Sync Status Specifies the SNTP Client sync status when it tries to ReSync again with the time servers.
The status is as follows:
Disabled: The SNTP client will not synchronize the time with the time servers and
displays the status as Disabled.
Synchronizing: The SNTP client is in the process of synchronzing time with the time
servers.
Synchronized: The SNTP client has synchronized time with the time servers.
Current Date/Time Displays the current date and time.
If SNTP is enabled, it displays the time the device received from the SNTP server. If SNTP is
not enabled, then it displays the time manually set by the user.
Manual Time If SNTP Client is disabled on the device or the time servers are not available on the
Configuration network, then the user can manually set the time. Enter the time manually in the format:
MM-DD-YYYY HH:MM:SS.
:
• Manual time configuration is not retained across reboots. After every reboot the
user has to set the time again.
• With manual time configuration, the device may lag behind the actual time
over a period of time. So, it is recommended to periodically check and adjust
the time.
To save the configured parameters, click Ok and then COMMIT.
6.5 Access Control
The Access Control tab enables you to control the device management access through specified host(s). You can specify a
maximum of 5 hosts to control device management access.
To configure management access control parameters, navigate to MANAGEMENT > Access Control. The Management
Access Control screen appears:
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Figure 6-21 Management Access Control
By default, the Management Access Control feature is disabled on the device. To enable, select Enable from the Access Table
Status box and click OK. Reboot the device, for the changes to take effect.
: Only when the Access Table Status is enabled, you can add host(s) to the Management Access Control Table.
6.5.0.1 Add Host(s) to Management Access Control Table
To add a host to the Management Access Control Table, do the following:
1. Click Add in the Management Access Control screen. The Management Access Table Add Row screen appears:
Figure 6-22 Management Access Table Add Row
2. IP Address: Type the IP address of the host that controls the device management access.
3. Entry Status
: By default, the entry status is enabled meaning which the specified host can control the device
management access. Edit the status to Disable, if you do not want the host to control the device management
access.
4. Click
Add
.
6.5.0.2 Edit Management Access Control Table Entries
Edit the desired host entries and click OK, COMMIT and then REBOOT.
6.6 Reset to Factory
The Reset to Factory tab allows you to reset the device to its factory default state. When this operation is performed, the device
will reboot automatically and comes up with default configurations.
To reset the device to its factory defaults, navigate to MANAGEMENT > Reset To Factory. The Factory Reset screen appears:
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Figure 6-23 Reset to Factory Defaults
Click OK, if you wish to proceed with factory reset, else click Cancel.
6.7 Convert QB to MP
The Convert QB to MP tab lets you convert a QB to SU so that the converted device can connect to a BSU and operate as a
regular SU.
This feature is applicable only to,
Tsunami® QB-8100-EPA which converts to a Tsunami® MP-8100-SUA, and
Tsunami® QB-8150-EPR which converts to a Tsunami® MP-8150-SUR
You can convert a QB to SU mode by using two methods:
Method 1: Web Interface
Method 2: Load a SU config file (retrieved from another SU) onto the QB device and then reboot.
: Even after conversion from QB to MP, the device description still shows as QB.
To convert a QB to SU using Web Interface, do the following:
1. Navigate to MANAGEMENT > Convert QB to MP. The Convert QB to MP screen appears:
Figure 6-24 Convert QB to MP
2. Click OK.
3. Reboot the device for the changes to take effect.
:
• A QB after converting to SU will function in SU mode only. It will accept only MP firmware for upgrade.
• The version of the firmware being upgraded to should be 2.4.0 or later. If earlier version of the firmware is loaded, the
device will reset to factory default upon initialization and operate in QB mode.
• When upgrading a converted device from Bootloader, it must be done using a QB image, as the device is licensed as
QB.
• The conversion of the device from QB to SU requires a reboot.
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• In case of Method 1 conversion, QB mode configuration will be deleted.
• Reset to factory defaults, always results in the device initializing in QB mode.
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Monitor
This chapter contains information on how to monitor the device by using Web interface. It contains information on the
following:
Interface Statistics
WORP Statistics
Active VLAN
Bridge
Network Layer
RADIUS (BSU or End Point A only)
IGMP
DHCP
Logs
Tools
SNMP v3 Statistics
7.1 Interface Statistics
Interface Statistics allows you to monitor the status and performance of the Ethernet and Wireless interfaces of the device.
7.1.1 Ethernet Statistics
To view the Ethernet interface statistics, click MONITOR > Interface Statistics. The Interface Statistics screen appears:
Figure 7-1 Ethernet Interface Statistics
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To view Ethernet statistics, click Ethernet 1 or Ethernet 2 depending on the Ethernet interfaces supported by your device.
Tabulated below is the table which explains the parameters displayed in the Ethernet Statistics screen:
Parameter Description
MTU Specifies the largest size of the data packet received or sent on the Ethernet interface.
MAC Address Specifies the MAC address at the Ethernet protocol layer.
Operational Status Specifies the current operational state of the Ethernet interface.
In Octets Specifies the total number of octets received on the Ethernet interface.
In Unicast Packets Specifies the number of subnetwork- unicast packets delivered to the higher level
protocol.
In Non-unicast Packets Specifies the number of non-unicast subnetwork packets delivered to the higher level
protocol.
In Errors Specifies the number of inbound packets that contained errors and are restricted from
being delivered.
Out Octets Specifies the total number of octets transmitted out of the Ethernet interface.
Out Unicast Packets Specifies the total number of packets requested by the higher level protocol and then,
transmitted to the non-unicast address.
Out Discards Specifies the number of error-free outbound packets chosen to be discarded to prevent
them from being transmitted. One possible reason for discarding such a packet could be
to free up buffer space.
Out Errors Specifies the number of outbound packets that could not be transmitted because of
errors.
To view the updated Ethernet statistics, click Refresh.
To delete the Ethernet statistics, click Clear.
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7.1.2 Wireless Statistics
To view the Wireless interface statistics, click MONITOR > Interface Statistics > Wireless1.
Figure 7-2 Wireless Interface Statistics
In addition to the parameters displayed for the Ethernet interface(s), the following parameters are displayed for the wireless
interface.
Parameter Description
Retunes Specifies the number of times the radio is retuned for better performance of the device.
SNR Statistics
SNR Statistics represents the signal strength with regard to the noise at the antenna ports.
Antenna Specifies the antenna ports available for the product. Please note that the antenna ports
vary depending on the product.
Status Specifies the configuration status of the antenna ports. ON indicates that antenna port is
enabled and OFF indicates that antenna port is disabled.
Control Specifies the SNR value of the packet received at the selected channel frequency.
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Parameter Description
Extension This parameter is applicable only to the 40 MHz modes, that is, 40 PLUS and 40 Minus.
It specifies the SNR value of the packet received on the extension channel (20MHz).
Rx Error Details
Decrypt Errors This parameter is applicable only if security is enabled. It indicates the number of received
packets that failed to decrypt.
CRC Errors Specifies the number of received packets with invalid CRC.
PHY Errors Specifies the total Rx PHY Errors. It generally indicates the interference in the wireless
medium.
To view the updated Wireless statistics, click Refresh.
To delete the Wireless statistics, click Clear.
7.1.3 PPPoE Statistics
: Applicable only to a SU in Routing mode.
To view PPPoE interface statistics, navigate to MONITOR > Interface Statistics > PPPoE > PPP Interface Stats.
Figure 7-3 PPPoE Interface Statistics
The PPPoE interface parameters are same as the Ethernet interface parameters. Please note that if a link is not established
between a PPPoE client and server, then the device displays the following message.
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Figure 7-4 PPPoE Server - No Link Established
To view the updated PPPoE interface statistics, click Refresh. Please note that for every 4 seconds, the interface statistics gets
refreshed.
To view the PPPoE connection status such as the number of attempts made to start a session between PPPoE client and server, and
the number of attempts failed to establish a connection, click PPPoE Connection Stats.
Figure 7-5 PPPoE Connection Statistics
To view updated connection statistics, click Refresh.
To restart the session between the PPPoE client and server, click Restart PPPoE Session. On successfully re-establishing a
session, the IP address of the wireless interface will be assigned again by the PPPoE server, if Address Type is set to PPPoE-ipcp.
To clear the existing connection statistics, click Clear.
7.1.4 IP Tunnels
: Applicable only in Routing Mode.
To view IP Tunnels interface statistics, click MONITOR > Interface Statistics > IP Tunnels. The following IP Tunnel
Interface Statistics screen appears:
Figure 7-6 IP Tunnels Interface Statistics
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Tabulated below is an explanation to each of these parameters:
Parameter Description
Name Specifies the tunnel interface name.
Alias Specifies a supplementary tunnel interface name.
Maximum Specifies the largest size packet or frame that can be sent over the tunnel interface.
Transmission Unit
(MTU) The MTU of the tunnel interface is derived from the underlying interface:
For IP-IP tunnel interface: MTU = Underlying interface MTU - 20 bytes (IP header)
For IP-GRE interface: MTU = Underlying interface MTU - 24 bytes (IP header + gre
protocol)
Operational Status The Operational Status indicates only the tunnel interface status. The status can be either
UP or DOWN.
: For the tunnel to function correctly both ends should be configured correctly.
Details Provides a more detailed statistics about the tunnel interface. To view the detailed
statistics, click
Figure 7-7 Detailed IP Tunnels Interface Statistics
The detailed tunnel interface parameters are similar to the Ethernet Interface Statistics.
Please refer to Ethernet Statistics.
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7.2 WORP Statistics
7.2.1 General Statistics
WORP General Statistics provides general statistics about the WORP.
To view General Statistics, navigate to MONITOR > WORP Statistics > Interface 1 > General Statistics. The following
WORP General Statistics screen appears:
Figure 7-8 WORP General Statistics
Tabulated below is an explanation to each of these parameters:
Parameter Description
Interface Type Specifies the type of radio interface.
WORP Protocol Specifies the version of the WORP Protocol used. This information is useful to the customer
Version support team for debugging purpose only.
WORP Data Messages
Specifies the sent or received data frames through wireless interface.
Poll Data Refers to the number of polls with data messages sent or received.
Poll No Data Refers to the number of polls with no data messages sent or received.
Reply Data Refers to the number of poll replies with data messages sent or received.
Reply More Data Refers to the number of poll replies with more data messages sent or received.
Reply No Data Refers to the number of poll replies with no data messages sent or received.
Poll No Replies Refers to the number of times poll messages were sent by a BSU/End Point A but no reply
was received by SU/End Point B. This parameter is valid only on BSU.
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Parameter Description
Data Transmission Statistics
Specifies the number of transmissions occurred through the interface.
Send Success Refers to the number of data messages sent and acknowledged by the peer successfully.
Send Retries Refers to the number of data messages that are re-transmitted and acknowledged by the
peer successfully.
Send Failures Refers to the number of data messages that are not acknowledged by the peer even after
the specified number of retransmissions.
Receive Success Refers to the number of data messages received and acknowledged successfully.
Receive Retries Refers to the number of successfully received re-transmitted data messages.
Receive Failures Refers to the number of data messages that were not received successfully.
Registration Details
Specifies the status of the entire registration process.
Remote Partners Refers to the number of remote partners. For a SU/End Point A/End Point B, the number of
remote partners is always zero or one.
Announcements Refers to the number of Announcement messages sent or received on WORP interface.
Request For Service Refers to the number of requests for service messages sent or received.
Registration Requests Refers to the number of registration request messages sent or received on WORP interface.
Registration Rejects Refers to the number of registration reject messages sent or received on WORP interface.
Authentication Refers to the number of authentication request messages sent or received on WORP
Requests interface.
Authentication Refers to the number of authentication confirm messages sent or received on WORP
Confirms interface.
Registration Attempts Refers to the number of times a registration attempt has been initiated.
Registration Refers to the number of registration attempts that are not yet completed.
Incompletes
Registration Timeouts Refers to the number of times the registration procedure timed out.
Registration Last Refers to the reason for the last registration getting aborted or failed.
Reason
: For better results, the Send Failure or Send Retrieve must be low in comparison to Send Success. The same applies for
Receive Retries or Receive Failure.
Click Clear to delete existing general statistics.
Click Refresh to view updated WORP general statistics.
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7.2.2 SU / End Point B Link Statistics
: SU Link Statistics is applicable only to a BSU, and End Point B Link Statistics is applicable only to a End Point A device.
SU Link statistics provides information about the SUs connected to a BSU. Similarly, End Point B Link Statistics provides
information about an End Point B currently connected to an End Point A device.
To view link statistics, navigate to MONITOR > WORP Statistics > Interface 1 > SU / End Point B Link Statistics.
Figure 7-9 An Example - SU Link Statistics
Tabulated below is an explanation to each of these parameters:
Parameter Description
SU Name/ Represents the name of the SU/End Point B connected to a BSU/End Point A respectively.
End Point B Name
MAC Address Represents the MAC address of the SU/End Point B connected to a BSU/End Point A
respectively.
Local Tx Rate (Mbps) Represents the data transmission rate at the local (current device) end.
Remote Tx Rate Represents the data transmission rate at the remote (peer) end.
(Mbps)
Local Antenna Port Indicates the status of the antenna ports at the local end. The following symbols indicate
Info the status of the antenna ports.
Indicates the antenna port is disabled.
Indicates the antenna port is enabled and signal is present.
Local Signal (dBm) Represents the signal level with which the device at the local end receives frames from the
device at the remote end, through wireless medium.
Local Noise (dBm) Represents the noise measured at the local end antenna ports.
Local SNR (dB) Represents the SNR measured by the receiver at the local end and is based on the Local
Signal and Local Noise.
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Parameter Description
Remote Antenna Port Indicates the status of the remote end antenna ports. The antenna ports status is same as
Info explained in Local Antenna Port Info.
Remote Signal (dBm) Represents the signal level with which the device at the remote end receives frames,
through wireless medium.
Remote Noise (dBm) Represents the noise measured at the remote end antenna ports.
Remote SNR (dB) Represents the SNR measured by the receiver at the remote end and is based on the
Remote Signal and Remote Noise.
Current Tx Power Applicable only when ATPC is enabled on the device.
(dBm) TPC: Displays the TPC value currently applied by the device to adjust the transmit
power radiated by the radio antenna.
EIRP: Displays the current EIRP that a radio antenna radiates (after applying the TPC).
Power: Displays the current transmit power radiated by the radio (after applying the
TPC).
Click Refresh to view updated link statistics.
To view detailed SU/End Point B Link statistics, click Details icon in the SU/End Point B Link Statistics screen. The
following screen appears depending on your device:
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Figure 7-10 SU Detailed Statistics
The detailed page displays Remote SNR information, that is, the Minimum Required SNR and the Maximum Optimal SNR value
for a given data rate or modulation, to achieve optimal throughput.
To disconnect a SU/End Point B from BSU/End Point A respectively, click Disconnect. To
view updated detailed statistics, click Refresh.
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To view local SNR table, click Click here for Local SNR-Table on the upper-right of SU/End Point B Link Statistics screen
(Refer An Example - SU Link Statistics). The following screen appears depending on your device:
Figure 7-11 Local SNR Information
These configured values are used by ATPC and DDRS to derive TPC and data rate for optimal throughput.
7.2.3 BSU/End Point A Link Statistics
: BSU Link Statistics is applicable only to a SU, and End Point A Link Statistics is applicable only to an End Point B device.
BSU Link statistics provides information about the BSU to which SUs are connected. Similarly, End Point A Link Statistics
provides information about an End Point A currently linked to an End Point B device.
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Figure 7-12 An Example - BSU Link Statistics
The link statistics are similar to SU / End Point B Link Statistics.
7.2.4 QoS Statistics (BSU or End Point A Only)
: This parameter is applicable only to BSU or End Point A radio modes.
To view QoS Statistics, navigate to MONITOR > WORP Statistics > Interface 1 > QoS Statistics. The following QoS
Summary screen appears.
Figure 7-13 QoS Summary
This screen shows the total, minimum and maximum bandwidth allocated per BSU/End Point A, and the minimum and
maximum bandwidth allocated for each SU/End Point B registered with the BSU/End Point A respectively.
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7.3 Active VLAN
: This parameter is applicable only to a device in SU mode.
The Active VLAN page enables you to identify the VLAN Configuration mode applied on a device in SU mode.
To view active VLAN applied on the device in SU mode, navigate to MONITOR > Active VLAN. The Active VLAN page
appears:
Figure 7-14 Active VLAN
The Active VLAN Config parameter helps you to identify the current VLAN configuration applied on the device in SU mode.
Local: VLAN configuration is done locally from the device.
Remote: VLAN configuration is done through RADIUS Server.
This page also displays the VLAN parameters and their values that are configured either locally or remotely.
To view active VLAN Ethernet Configuration, navigate to
MONITOR
>
Active VLAN > Ethernet
. The
Active VLAN
Ethernet Configuration page appears:
Figure 7-15 Active VLAN Ethernet Configuration
This page displays the VLAN Ethernet parameters and their values that are configured either locally or remotely.
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: Please note that the number of Ethernets vary depending on the device.
7.4 Bridge
7.4.1 Bridge Statistics
The Bridge Statistics allows you to monitor the statistics of the Bridge.
To view the Bridge Statistics, navigate to MONITOR > Bridge > Bridge Statistics. The following Bridge Statistics screen
appears:
Figure 7-16 Bridge Statistics
The following table lists the parameters and their description:
Parameter Description
Description This parameter provides a description about the bridge.
MTU Represents the largest size of the data packet sent on the bridge.
MAC Address Represents the MAC address at the bridge protocol layer.
Operational Status Represents the current operational status of the bridge: UP (ready to pass packets) or
DOWN (not ready to pass packets).
In Octets Represents the total number of octets received on the bridge interface, including the
framing characters.
In Unicast Packets Represents the number of unicast subnetwork packets delivered to the higher level
protocol.
In Non-unicast Packets Represents the number of non-unicast subnetwork packets delivered to the higher level
protocol.
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Parameter Description
In Errors Represents the number of inbound packets with errors and that are restricted from being
delivered.
Out Octets Represents the total number of octets transmitted out of the bridge, including the framing
characters.
Out Unicast Packets Represents the total number of packets requested by higher-level protocols to be
transmitted out of the bridge interface to a subnetwork-unicast address, including those
that were discarded or not sent.
Out Discards Represents the number of error-free outbound packets which are discarded to prevent
them from being transmitted. One possible reason for discarding such a packet could be to free
up buffer space.
Out Errors Represents the number of outbound packets that could not be transmitted because of
errors.
To view updated Bridge statistics, click Refresh.
To clear the Bridge statistics, click Clear.
7.4.2 Learn Table
Learn Table allows you to view all the MAC addresses that the device has learnt on all of its interfaces.
To view Learn Table statistics, navigate to MONITOR > Bridge > Learn Table. The Learn Table screen appears.
Figure 7-17 Learn Table
The Learn Table displays the MAC address of the learnt device, the bridge port number, aging timer for each device learnt on an
interface, and the local (DUT's local interfaces)/remote (learned entries through bridging) status of the learnt device.
To view updated learn table statistics, click Refresh.
To clear learn table statistics, click Clear.
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7.5 Network Layer
7.5.1 Routing Table
Routing table displays all the active routes of the network. These can be either static or dynamic (obtained through RIP). For every
route created in the network, the details of that particular link or route will get updated in this table.
To view the Routing Table, navigate to MONITOR > Network Layer > Routing Table. The Routing Table screen appears:
Figure 7-18 Routing Table
7.5.2 IP ARP
Address Resolution Protocol (ARP) is a protocol for mapping an Internet Protocol address (IP address) to a physical address on the
network. The IP ARP table is used to maintain a correlation between each IP address and its corresponding MAC address. ARP
provides the protocol rules for making this correlation and providing address conversion in both directions.
To view IP Address Resolution Protocol (ARP) statistics, navigate to MONITOR > Network Layer > IP ARP. The IP ARP Table
screen appears.
Figure 7-19 IP ARP Table
The IP ARP Table contains the following information:
Index: Represents the interface type.
MAC Address: Represents the MAC address of a node on the network.
Net Address: This parameter represents the corresponding IP address of a node on the network.
Type: This parameter represents the type of mapping, that is, Dynamic or Static.
To view updated IP ARP entries, click Refresh.
To clear the IP ARP entries, click Clear.
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7.5.3 ICMP Statistics
The ICMP Statistics attributes enable you to monitor the message traffic that is received and transmitted by the device.
To view ICMP statistics, navigate to MONITOR > Network Layer > ICMP Statistics. The ICMP Statistics screen appears.
Figure 7-20 ICMP Statistics
The following table lists the ICMP Statistics parameters and their description:
Parameter Description
In Msgs or Out Msgs Represents the number of ICMP messages that are received/transmitted by the device.
In Errors or Out Errors Represents the number of ICMP messages that are received/transmitted by the device but
determined as having ICMP-specific errors such as Bad ICMP checksums, bad length and
so on.
In Dest Unreachs or Represents the number of ICMP destination unreachable messages that are
Out Dest Unreachs received/transmitted by the device.
In Time Excds or Out Represents the number of ICMP time exceeded messages that are received/transmitted by
Time Excds the device.
In Parm Probs or Out Represents the number of ICMP parameter problem messages that are
Parm Probs received/transmitted by the device.
In Srec Quenchs or Represents the number of ICMP source quench messages that are received/transmitted by
Out Srec Quenchs the device.
In Redirects or Out Represents the rate at which the ICMP redirect messages are received/transmitted by the
Redirects device.
In Echos Represents the rate at which the ICMP echo messages are received.
In EchoReps or Out Represents the rate at which the ICMP echo reply messages are received/transmitted by
EchoReps the device.
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Parameter Description
In Timestamps or Out Represents the rate at which the ICMP timestamp (request) messages are
Timestamps received/transmitted by the device.
In Timestamps Reps or Represents the rate at which the ICMP timestamp reply messages are received/transmitted
Out Timestamps Reps by the device.
In Addr Masks or Out Represents the number of ICMP address mask request messages that are
Addr Masks received/transmitted by the device.
In Addr Mask Reps or Represents the number of ICMP address mask reply messages that are
Out Addr Mask Reps received/transmitted by the device.
To view updated ICMP Statistics, click Refresh.
7.5.4 RIP Database
The RIP Database screen contains routes (Routing Information Protocol updates) learnt from other routers.
Figure 7-21 RIP Database
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7.6 RADIUS (BSU or End Point A only)
: RADIUS is applicable only to a BSU or an End Point A device.
7.6.1 Authentication Statistics
Authentication Statistics provides information on RADIUS Authentication for both the primary and backup servers for each
RADIUS server profile.
To view Authentication statistics, navigate to MONITOR > RADIUS > Authentication Statistics. The RADIUS Client
Authentication Statistics screen appears:
Figure 7-22 Radius Client Authentication Statistics
The following table lists the Authentication Statistics parameters and their description:
Parameter Description
Round Trip Time Represents the round trip time for messages exchanged between RADIUS client and
authentication server since the client startup.
Reqs Represents the number of RADIUS access request messages transmitted from the RADIUS
client to the authentication server since client startup.
RTMS This parameter represents the number of times the RADIUS access requests are being
transmitted to the server from the device since the client startup.
Accepts Represents the number of RADIUS access accept messages received by the device since
client startup.
Rejects Represents the number of RADIUS access reject messages received by the device since
client startup.
Resp Represents the number of RADIUS response packets received by the device since client
startup.
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Parameter Description
Mal Resp Represents the number of malformed RADIUS access response messages received by the
device since client startup.
Bad Auths Represents the number of malformed RADIUS access response messages containing invalid
authenticators received by the device since client startup.
Time Outs Represents the total number of timeouts for RADIUS access request messages since client
startup.
UnKnown Types This parameter specifies the number of messages with unknown RADIUS message code
since client startup.
Packets Dropped Represents the number of RADIUS packets dropped by the device.
To view updated RADIUS Client Authentication statistics, click Refresh.
7.7 IGMP
: Applicable in Bridge mode only.
To view IGMP statistics, navigate to MONITOR > IGMP > IGMP Snooping Stats. The Ethernet or Wireless Multicast List
screen appears:
Figure 7-23 Ethernet1 Multicast List
7.7.1 Ethernet or Wireless Multicast List
The Multicast List table contains the IGMP Multicast IP and Multicast MAC address details for the Ethernet or Wireless
interfaces. The following table lists the parameters and their description.
Parameter Description
Group IP Represents the IP address of the multicast group for Ethernet or Wireless interface learned
by IGMP snooping.
MAC Address Represents the MAC address of the multicast group for Ethernet or Wireless interface
learned by IGMP snooping.
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Parameter Description
Time Elapsed Represents the time elapsed since the multicast entry has been created for the Ethernet or
Wireless interface.
To view updated IGMP statistics, click Refresh.
7.7.2 Router Port List
The Router Port List displays the list of ports on which multicast routers are attached.
To view Router Port List, navigate to MONITOR > IGMP > Router Port List. The Router Port List screen appears:
Figure 7-24 Router Port List
The following table lists the parameters and their description.
Parameter Description
Port Number Represents the port number on which multicast router is attached (on which IGMP Query
has been received).
Time Elapsed Represents the time elapsed since the port is marked as the router port.
To view updated Router Port list, click Refresh.
7.8 DHCP
DHCP Leases file stores the DHCP client database that the DHCP Server has served. The information stored includes the
duration of the lease, for which the IP address has been assigned, the start and end dates for the lease, and the MAC address of the
network interface card of the DHCP client.
To view DHCP Leases, navigate to MONITOR > DHCP > Leases.
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Figure 7-25 DHCP Leases
7.9 Logs
7.9.1 Event Log
The Event Log keeps track of events that occur during the operation of the device. It displays the event occurring time, event type,
and the name of the error or the error message. Based on the priority (the log priority is set under MANAGEMENT > Services >
Logs), the event details are logged and can be used for any future reference or troubleshooting.
To view the Event Log, navigate to MONITOR > Logs > Event Log. The following Event Log screen appears:
Figure 7-26 Event Logs
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To hide the event logs, click Hide Event Log.
To clear the event logs, click Clear Event Log.
To view updated event logs, click Refresh.
: The recent event logs are stored in the flash memory.
7.9.2 Syslog
System log messages are generated by the system by sending requests at various instances to the system log server. To
view System Logs, navigate to MONITOR > Logs > Syslog. The Syslog screen appears.
Figure 7-27 System Log
To clear Syslog information, click Clear Syslog.
To hide Syslog information, click Hide Syslog.
To refresh Syslog messages, click
Refresh
.
7.9.3 Debug Log
Debug Log helps you to debug issues related to important features of the device. Currently, this feature supports only DDRS and
DFS. This feature helps the engineering team to get valuable information from the field to analyze the issues and provide faster
solution. This feature should be used only in consultation with the Proxim Customer Support team. Once logging is enabled, the
Debug Log file can be retrieved via HTTP or TFTP.
To enable Debug Log, navigate to MONITOR > Logs > Debug Log. The Debug Log screen appears:
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Figure 7-28 Debug Log
Features: Select the appropriate features to be logged. The available features are Select All, DDRS Level 1, DDRS Level 2,
DDRS
Level 3 and DFS.
File Status: This parameter displays the current size of the Debug Log file.
After selecting the DDRS level, click OK.
To delete the Debug Log, click Clear Log.
To get the updated status of the Debug Log File, Click Refresh.
7.9.4 Temperature Log
: Temperature Log are not applicable to Tsunami® MP-8150-CPE, Tsunami® MP-8160-CPE and Tsunami®
QB-8150-EPR-12/50 devices.
Temperature Log feature reports and logs the internal temperature of the device. When the internal temperature value
reaches the minimum threshold value of -40ºC or the maximum threshold temperature of 60ºC, the internal temperature is
logged and an SNMP trap is sent (At 5 Degrees before each limit, the device issues a warning trap). These threshold
temperature values may be reconfigured but the values cannot exceed beyond the default values.
: A recording interval from one to sixty minutes with 5-minute increments can be selected. If we configure the logging
interval as “0”, temperature logs will be disabled.
To view and configure threshold values, and the logging interval, navigate to MONITOR > Logs > Temperature Log.
The threshold values of temperature are configured in Centigrade (Celsius) scale. The Temperature Log screen displays the
Current Device Temperature in Celsius, along with High Temperature and Low Temperature Threshold values and
Temperature Logging Interval. The temperature log can have a maximum size of 65 Kb; and once the limit is reached, only the
last 576 logs are available. (Log storage is up to six days with the refresh time of 5 minutes).
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Figure 7-29 Temperature Log
After configuring the parameters, click OK.
To view the Temperature Log, click Show Temp Log.
To delete all the Temperature Logs, click Clear Temp Log.
Click Refresh, to get the updated Temperature Log.
7.10 Tools
7.10.1 Wireless Site Survey
: Applicable only to a device in SU or End Point B mode.
Wireless Site Survey is done by the SU or End Point B only. This feature scans all the available channels according to the
current Channel Bandwidth, and collects information about all BSUs or Endpoint A configured with the same network name
as
SUs or End Point B.
Figure 7-30 Wireless Site Survey - SU Mode
To initialize the survey process, click Start. This process list the details of all the available BSUs or End Point A. To stop the site survey
process, click Stop. Click Refresh, to get the updated Wireless Site Survey.
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7.10.2 Scan Tool
With Scan Tool, you can scan all the devices available in your network.
To scan the devices, navigate to MONITOR > Tools > Scan Tool. The Scan Tool screen appears.
Figure 7-31 Scanned Devices
Click Scan to scan and refresh the devices on the network.
7.10.3 sFlow®
Proxim’s point-to-multipoint and point-to-point devices support sFlow® technology, developed by InMon Corporation. The
sFlow® technology provides the ability to measure network traffic on all interfaces simultaneously by collecting, storing, and
analyzing traffic data.
Depicted below is the sFlow architecture that consists of a sFlow Agent and a sFlow Receiver.
Figure 7-32 sFlow Architecture - An Example with a BSU and SUs
The sFlow Agent, which is running on devices, captures traffic information received on all the Ethernet interfaces, and sends
sampled packets to the sFlow Receiver for analysis.
The sampling mechanism used to sample data are as follows:
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Packet Flow Sampling: In this sampling, the data packets received on the ethernet interface of the device are
sampled based on a counter. With each packet received, the counter is decremented. When the counter reaches zero,
the packet is packaged and sent to the sFlow Receiver for analysis. These packets are referred to as Packet Flow
Samples.
Counter Polling Sampling: In this sampling, the sFlow Agent sends counters periodically to the sFlow Receiver based
on the set polling interval. If polling interval is set to 5 seconds then the sFlow Agent sends counters to sFlow Receiver
every 5 seconds. These packets are referred to as Counter Polling Samples.
The Packet Flow Samples and Counter Polling Samples are collectively sent to the sFlow Receiver as sFlow Datagrams. It is
possible to enable either or both types of sampling.
sFlow Sampling effects the system performance and hence care must be taken in configuring the sFlow parameters. To
configure sFlow, navigate to MONITOR > Tools > sFlow. The following sFlow® screen appears:
Figure 7-33 sFLOW
This screen displays the following information about the sFlow Agent:
Version: The version displayed is 1.3;Proxim Wireless Corp.; v6.4. The version comprises the following information:
1. sFlow MIB Version: Indicates the agent’s MIB version. The MIB specifies how the agent extracts and bundles
sampled data, and the sFlow receiver must support the agent’s MIB. The sFlow MIB version is 1.3. so the sFlow
Receiver’s version must also be at least 1.3.
2. Organization: Specifies the organization implementing sFlow Agent functionality on the device, that is, Proxim
Wireless Corp.
3. Revision: Specifies the sFlow Agent version, that is, v6.4.
Address Type: Specifies the protocol version for IP addresses.
Agent Address: Specifies the sFlow Agent’s IP address.
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7.10.3.1 sFlow Receiver Configuration
The Receiver Configuration page allows you to configure sFlow Receiver(s), which receives samples from all agents on the
network, combines and analyzes the samples to produce a report of network activity.
To configure sFlow Receiver, navigate to MONITOR > Tools > sFlow and select Receiver Configuration tab.
Tabulated below is the table which explains sFlow parameters and the method to configure the configurable parameter(s):
Parameter Description
S.No. Represents the Receiver index number. Please note that the number of indexes depends
on the ethernet interfaces your device supports.
Owner Enter a string, which uniquely identifies the sFlow Receiver.
Time Out Enter a value ranging from 30 to 31536000 seconds (365 days) in the Time Out box.
The sFlow Agent sends sampled packets to the specified sFlow Receiver till it reaches zero. At
zero, all the Receiver parameters are set to default values.
Max Datagram Size Enter the maximum size of a sFlow datagram (in bytes), which the Receiver can receive, in
the Max Datagram Size box. By default, the maximum datagram size is set to 1400
bytes. It can range from 200 to 1400 bytes.
Address Type The address type supported by sFlow Receiver is ipv4, which is by default selected.
: Only IPv4 is currently supported.
Receiver Address Enter the sFlow Receiver’s IP address in the Receiver Address box.
Receiver Port By default, the sFlow Receiver listens to the sFlow datagrams on 6343 port. To change the
port, enter a valid port ranging from 0 to 65535 in the Receiver Port box.
Datagram Version The sFlow datagram version used is 5.
Click Apply, to save the sFlow Receiver configuration parameters.
Once the Receiver configurations are done, either Packet Flow sampling or Counter Polling Sampling or both can be started.
:
• Enabling sampling effects the system performance and hence care should be taken in setting the right values for
Timeout and Max Datagram Size.
• When the Owner string is cleared, the Flow Sampling and Counter Polling stops.
7.10.3.2 Sampling Configuration
To configure and start packet flow sampling, do the following:
1. Navigate to MONITOR > Tools > sFlow and select Sampling Configuration tab.
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Figure 7-34 sFlow Sampling Configuration
2. From the Receiver Index drop-down box, select the receiver index number associated with the sFlow Receiver to
which the sFlow Agent should send the sFlow Datagrams.
: If device has two ethernet interfaces, then configure different Receiver indexes for each of the interface.
3. Type a value in the Packet Sampling Rate box. This value determines the number of packets the sFlow Agent
samples from the total number of packets passing through the ethernet interface of the device.
4. Type a value in the Maximum Header Size box, to set the amount of data (in bytes) to be included in the sFlow
datagram. The sFlow Agent samples the specified number of bytes. For example, if you set the Maximum Header Size
to 100, the sFlow Agent places the first 100 bytes of every sampled frame in the datagram. The value should match
the size of the frame and packet header so that the entire header is forwarded. The default size is 128 bytes. The
header size can range from 20 to 256 bytes.
5. Next, click
Apply
to start packet flow sampling. Once it starts, the
Time Out
parameter (see sFlow Receiver
Configuration) keeps decrementing till it reaches a zero value. On reaching zero, the corresponding Receiver and
Sampling values are set to default values.
:
• Enabling sFlow packet sampling effects the system performance, and hence care must be taken when choosing the right
value for Packet Sampling Rate and Maximum Header Size.
• Receiver Index for packet Sampling table and Counter Polling table should be same for each Ethernet interface.
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7.10.3.3 Counter Polling Configuration
To configure and start Counter Polling sampling, do the following:
1. Navigate to MONITOR > Tools > sFlow and select Counter Polling Configuration tab.
Figure 7-35 Counter Polling Configuration
2. From the Receiver Index drop-down box, choose the receiver index number associated with the sFlow Receiver to
which the sFlow Agent sends the counters.
: If Packet Flow Sampling is already configured and running, then you should configure the Receiver index same as
configured in the Packet Flow Sampling for each ethernet interface.
3. Set the polling interval by typing a value in the Interval box. Lets say, the polling interval is set to 30 seconds. So for
every 30 seconds, the counters are collected and send to the sFlow Receiver. The valid range for polling interval is 0 to
2
31 - 1 seconds.
4. Next, click Apply to start Counter Polling Sampling. Once it starts, the Time Out parameter (see sFlow Receiver
Configuration) keeps decrementing till it reaches a zero value. On reaching zero, the corresponding Receiver and
Counter Polling values are set to default values.
• Enabling sFlow counter sampling effects the system performance, and hence care must be taken when choosing the right
value sampling interval.
• Receiver Index for packet Sampling table and Counter Polling table should be same for each Ethernet interface.
• If a sampling starts and there is already another sampling running then we consider the time out value of the
current/already running sampling.
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7.10.4 Console Commands
The Console Commands feature helps Proxim’s Technical Support team to debug field issues.
7.11 SNMP v3 Statistics
SNMP v3 statistics can be viewed only when SNMPv3 feature is enabled on the device. See SNMP.
To view the SNMPv3 Statistics, navigate to MONITOR > SNMPV3 Statistics. The following SNMP v3 Statistics screen
appears:
Figure 7-36 SNMP v3 Statistics
The following table lists the SNMP v3 parameters and their description:
Parameter Description
Unsupported Sec This parameter specifies the total number of packets received by the SNMP engine, which
Levels were dropped because they requested a security level that was unknown to the SNMP
engine or otherwise unavailable.
Not In Time Windows This parameter specifies the total number of packets received by the SNMP engine which
were dropped because they appeared outside of the authoritative SNMP engine's window.
Unknown User Names This parameter specifies the total number of packets received by the SNMP engine which
were dropped because they correspond to an unknown user to the SNMP engine.
Unknown Engine IDs This parameter specifies the total number of packets received by the SNMP engine which
were dropped because they correspond an SNMP Engine ID that was unknown to the
SNMP engine.
Wrong Digests This parameter specifies the total number of packets received by the SNMP engine which
were dropped because they did not contain the expected digest value.
Decryption Errors This parameter specifies the total number of packets received by the SNMP engine which
were dropped because they could not be decrypted.
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8
Troubleshooting
This chapter helps you to address the problems that might arise while using our device. If the procedures discussed in this
chapter does not provide a solution, or the solution does not solve your problem, check our support site at
http://support.proxim.com which stores all resolved problems in its solution database. Alternatively, you can post a question
on the support site, to a technical person who will reply to your email.
Before you start troubleshooting, check the details in the product documentation available on the support site. For details about
RADIUS, TFTP, Terminal and Telnet programs, and Web Browsers, refer to their appropriate documentation.
In some cases, rebooting the device solves the problem. If nothing else helps, consider a Soft Reset to Factory Defaults or a
Forced Reload. The Forced Reload option requires you to download a new firmware onto the device.
This chapter provides information on the following:
PoE Injector
Connectivity Issues
Surge or Lightning Issues (For Connectorized devices)
Setup and Configuration Issues
Application Specific Troubleshooting
Wireless Link Issues
Wired (Ethernet) Interface Validation
Wireless Interface Validation
Recovery Procedures
Spectrum Analyzer
Miscellaneous
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8.1 PoE Injector
Problem Solution
The Device Does Not Make sure that you are using a standard UTP
Work - Category 5e/6 cable in case of MP-8100-BSU, MP-8100-SUA, MP-8150-SUR,
MP-8160-BSU, MP-8160-SUA, QB-8100-EPA and QB-8150-EPR devices
- Category 5 cable in case of MP-8150-CPE, MP-8160-CPE,
QB-8150-EPR-12/50
Try a different port on the same PoE Injector hub (remember to move the input port
accordingly) - if it works then there is a problem in the previous RJ45 port or a bad
RJ45 port connection.
Try to connect the device to a different PoE Injector hub.
Try using a different Ethernet cable - if it works, there is probably a fault in the cable
or its connection.
Check the power plug and hub.
If the ethernet link goes down, check the cable, cable type, switch and hub.
There is No Data Link Verify that the indicator on the device port is “ON.”
Verify that the Ethernet cable from PoE Injector hub to the Ethernet port of the
device is properly connected.
Make sure that you are using a standard UTP
- Category 5e/6 cable in case of MP-8100-BSU, MP-8100-SUA, MP-8150-SUR,
MP-8160-BSU, MP-8160-SUA, QB-8100-EPA and QB-8150-EPR devices
- Category 5 cable in case of MP-8150-CPE, MP-8160-CPE,
QB-8150-EPR-12/50 devices
The length of the cable from the Ethernet port of the device to the PoE should be
less than 100 meters (approximately 325 feet).
Try to connect a different device to the same port on the PoE Injector hub - if it
works and a link is established then there is probably a fault in the data link of the
device.
Try to re-connect the cable to a different output port (remember to move the input
port accordingly) - if it works then there is a fault probably in the output or input
port of the PoE Injector hub or a bad RJ45 connection.
Overload Indications Connect the device to a PoE Injector.
Ensure that there is no short over on any of the connected cables.
Move the device into a different output port (remember to move the input port
accordingly) - if it works then there is a fault probably in the previous RJ45 port or bad
RJ45 port connection.
8.2 Connectivity Issues
Connectivity issues include any problem that prevents from powering or connecting to the device.
Problem Solution
Does Not Boot - No • Make sure your power source is ON.
LED Activity • Make sure all the cables to the device are connected properly.
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Problem Solution
Ethernet Link Does Check the Ethernet LED
Not Work Solid Green: The Ethernet link is up.
Blinking Green: The Ethernet link is down.
Serial Link Does Not • Double-check the physical network connections.
Work • Make sure your PC terminal program (such as HyperTerminal) is active and
configured to the following values:
- Com Port: (COM1, COM2 and so on depending on your computer);
- Baud rate: 115200; Data bits: 8; Stop bits: 1; Flow Control: None; Parity:
None;
- Line Feeds with Carriage Returns
• (In HyperTerminal select: File > Properties > Settings > ASCII Setup > Send Line
Ends with Line Feeds)
: Not applicable to Tsunami® MP-8160-CPE as it does not support serial interface.
Cannot Access the • Open a command prompt window and type the Ping command along with the IP
Web Interface address of the device. For example, ping 10.0.0.1. If the device does not respond,
check if you have the correct IP address. If the device responds then it means the
Ethernet connection is working properly.
• Ensure that you are using Microsoft Internet Explorer 7.0 (or later) or Mozilla Firefox
3.0 (or later).
• Ensure that you are not using a proxy server for the network connection with your
Web browser.
• Ensure that you have not exceeded the maximum number of Web Interfaces or CLI
sessions.
• Double-check the physical network connections. Use a well-known device to ensure
the network connection is functioning properly.
• Troubleshoot the network infrastructure (check switches, routers, and so on).
: At any point of time, if the device is unable to connect to your network, reset the
device by unplugging and plugging the cables from the PoE.
8.3 Surge or Lightning Issues (For Connectorized devices)
Problem Solution
Surge or Lighting In case of any lightning or surge occurrence, check for the conditions specified below:
Problem • Check the RF signals by referring to RSSI statistics and if the signal strength has been
lowered considerably, replace the Surge Arrestor.
• Unscrew the N-Type connector at the top and visually inspect the Surge Arrestor for
electrical burns. If any, replace it.
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8.4 Setup and Configuration Issues
Problem Solution
Device Reboots One of the reason for the device to reboot continuously is that the radio card is not
Continuously properly placed in the mini-PCI slot. When you power on the device and you do not see
the “WIRELESS NETWORK1 PASSED” in the POST message in the Serial Console,
please contact Proxim’s support site at http://support.proxim.com.
Lost Telnet or SNMP Perform Soft Reset to Factory Defaults procedure. This procedure resets system and
Password network parameters, but does not affect the image of the device. The default HTTP, Telnet,
and SNMP username is admin and password is public.
Device Responds If the device takes a long time to respond, it could mean that:
Slowly No DHCP server is available.
The IP address of the device is already in use. Verify that the IP address is assigned
only to the device you are using. Do this by switching off the device and then
pinging the IP address. If there is a response to the ping, another device in the
network is using the same IP address. If the device uses a static IP address, switching to
DHCP mode could solve this problem.
The network traffic is more.
Incorrect Device IP The default IP address assignment mode is Static and the default IP address of the
Address device is 169.254.128.132.
If the IP address assignment mode is set to Dynamic, then the DHCP Server will
assign an IP address automatically to the device. If the DHCP server is not available
on your network, then the fall back IP address (169.254.128.132) of the device is
used.
Use ScanTool, to find the current IP address of the device. Once you have the current
IP address, use Web Interface or CLI Interface to change the device IP settings, if
necessary.
If you are using static IP address assignment, and cannot access the device over
Ethernet, refer to Initializing the IP Address using CLI.
• Perform Soft Reset to Factory Defaults procedure. This will reset the device to static
mode.
HTTP Interface or Make sure you are using a compatible browser:
Telnet Does Not Work - Microsoft Internet Explorer 7.0 or later
- Mozilla Firefox 3.0 or later
Make sure you have the correct IP address of the device. Enter the device IP address
in the address bar of the browser, for example http://169.254.128.132.
• When the Enter Network Password window appears, enter the User Name and
and Password. The default HTTP username is admin and password is public.
Use CLI, to check the IP Access Table which can restrict access to Telnet and HTTP.
Telnet CLI Does Not Make sure you have the correct IP address. Enter the device IP address in the Telnet
Work connection dialog, from a DOS prompt: C:\> telnet <Device IP Address>
Use HTTP, to check the IP Access Table which can restrict access to Telnet and HTTP.
Enable Telnet in Vista or Windows 7 as it is by default disabled.
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Problem Solution
TFTP Server Does Not • The TFTP server is not properly configured and running
Work • The IP address of the TFTP server is invalid
• The upload or download directory is not correctly set
• The file name is not correct
Changes in Web
Interface Do Not Take
Effect
1. Restart your Web browser.
2. Log on to the device again and make changes.
3. Reboot the device.
4. Click Commit for the changes to take effect.
5. Wait until the device reboots before accessing the device again.
8.5 Application Specific Troubleshooting
Problem Solution
RADIUS If RADIUS Authentication is enabled on the device, then make sure that your network’s
Authentication Server RADIUS servers are operational. Otherwise, clients will not be able to log onto the device.
Services unavailable
There are several reasons for the authentication server‘s services to be unavailable. To
make it available,
• Make sure you have the proper RADIUS authentication server information setup
configured on the device. Check the RADIUS Authentication Server’s Shared Secret
and Destination Port number (default is 1812; for RADIUS Accounting, the default is
1813).
• Make sure the RADIUS authentication server RAS setup matches the device.
TFTP Server If a TFTP server is not configured and running, you will not be able to download and
upload images and configuration files to or from the device. Remember that the TFTP
server need not be local, as long as you have a valid TFTP IP address. Note that you do not need
a TFTP server running unless you want to transfer files to or from the device.
After the TFTP server is installed:
Check to see that TFTP is configured to point to the directory containing the
device Image.
Make sure you have the proper TFTP server IP Address, the proper device image
file name, and that the TFTP server is connected.
Make sure the TFTP server is configured to both Transmit and Receive files (on
the TFTP server’s Security tab), with no automatic shutdown or time-out (on
the Auto Close tab).
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8.6 Wireless Link Issues
Tabulated below are the possible reasons for a wireless link not getting established and the relevant observations.
Reason(s) Observation
Mismatch in network The Wireless Interface Statistics (In Octets, In Non-Unicast Packets) are incremented
name in BSU/End Point A and SU/End Point B.
The WORP counters are not affected.
The remote device is not listed in the Site Survey.
Incorrect or invalid The Wireless Interface Statistics (In Octets, In Non-Unicast Packets) are incremented
configured BSU/End in SU/End Point B.
Point A name The WORP counters are not affected.
The remote device is not listed in the Site Survey.
Mismatch in network The Wireless Interface Statistics (In Octets, In Non-Unicast Packets) are incremented
secret in BSU/End Point A and SU/End Point B.
The WORP counters are incremented (Req for Serv, Reg Req, Auth Req, Reg
Attempts, Reg LastReason: Incorrect Parameter) on both ends.
Encryption set to No The Wireless Interface Statistics (In Octets, In Non-Unicast Packets) are incremented
Encryption in in BSU/End Point A; No decrypt errors are observed in SU/End Point B.
BSU/End Point A and In SU/End Point B, the WORP counters (Announcements, Req for Serv, Reg Attempts,
AES Encryption in Reg incomplete, Reg timeout, Reg Last Reason: Timeout) are incremented. In
SU/End Point B BSU/End Point A, no WORP counters are incremented except announcements.
The remote device is not listed in the Site Survey.
Encryption set to AES The Wireless Statistics counters and WORP counters are not incremented in SU/End
Encryption in Point B.
BSU/End Point A and The remote device is not listed in the Site Survey.
No Encryption in
SU/End Point B
Encryption set to AES The Wireless Interface Statistics (In Octets, In Non-Unicast Packets) are incremented
Encryption in both only in SU/End Point B.
BSU/End Point A and The remote device is not listed in the Site Survey.
SU/End Point B. A
mismatch in
Encryption key
BSU exceeds the The Wireless Interface Statistics (In Octets, In Non-Unicast Packets) are incremented
maximum SU limit in SU/End Point B but fails to authenticate.
The WORP counters (Announcements, Req for Serv, Reg Attempts, Reg Incompletes,
Reg Timeouts, Reg Last Reason: Timeout) are incremented in SU/End Point B.
The remote device is listed in the Site Survey.
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Troubleshooting
8.7 Wired (Ethernet) Interface Validation
Problem Solution
Wired (Ethernet) Run iperf commands
Interface Validation Use iperf commands with -w option as 202k. The throughput is expected to be
equal in both directions and should be comparable from laptop to laptop or desktop to
desktop performance
If the above throughput value is not in the expected range,
• Check speed and duplex settings between the device and Personal Computer or
switch or router connected
• Make sure the connection established is of same speed and full duplex is as expected
(10 or 100 or 1000)
• With auto negotiation, if you notice this issue, then try manually setting the speed
and duplex
• Update the Ethernet driver in the Personal Computer to the latest one
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Troubleshooting
8.8 Wireless Interface Validation
Problem Solution
Wireless Interface Run iperf commands (You can run Embedded iperf commands only through Telnet.)
Validation • iperf -s -w 202k (command for iperf server)
• Iperf -c ipaddress -w 202k -t time Period -I <intermediateResultInterval> -P <4 or
6> (command to run iperf client)
- Ipaddress -> of the SU/End Point B or BSU/End Point A device where the iperf
server is running
- P -> No of pairs (Streams)
• Use -d option to run bidirectional throughput
• Use -r option to run unidirectional throughput one after another without changing
the server and SU ends
If the expected throughput is not achieved, then check the following:
Antenna Alignment
- Note whether the antenna ports are balanced - SNR/RSSI provided for Local
and Remote in the BSU/SU Link Statistics page or by using “aad” command
- Signal difference of <=5 dBm is considered as balanced and recommended
- If the chains are not balanced, then look at the alignment and connectors of
RF cables, used between antenna and device
- If in RMA (Returned from Customer), check the RF cable to radio port
connectivity
- Avoid nearby metal surfaces, if you are using Omni antenna
Data Streams
- Select “Single” stream instead of “Dual” stream mode
- DDRS - with single stream data rate or with Auto mode
Dual stream data rates can be used only when the signal in both antenna ports is
balanced
Antenna Port Selection
- For MP81x0-BSU/SU or QB81x0 devices, make sure you are either enabling all
antenna ports for 3*3 MIMO or using A1 and A3 antenna ports for 2*2
MIMO mode
- For MP8160-BSU/SU use A1 and A2 antenna ports for 2*2 MIMO
- For using single stream, it is mandatory to select antenna port A1
- Enabling all antenna port will not cause any issue even if it is not in use.
Bad Channel
- Check for CRC errors, PHY errors, WORP Retries and WORP Failures in
Monitor Interface Statistics page. If this count increments steadily (Refreshing the
web page is required) then
• Either change the channel and check for a better channel
• Use Wi-Spy or similar tool and check the environment for better channel
Data Rate Issues
- Ensure same data rates are selected if you are using fixed data rate between
BSU/SU and End Point A/End Point B to have predictable throughput and link
- Alternative, use DDRS with Auto mode enabled
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Troubleshooting
Problem Solution
Wireless Interface Performance and Stability Issues
Validation - Check the distance between two co-locating devices. The distance between
two co-locating devices should be minimum 3 meters, in order to achieve good
throughput and maintain link stability. The operating channels should maintain
5MHz spacing if managed by a single administrator.
- When DDRS is disabled, check the Minimum Required SNR for the current
data rate by navigating to MONITOR --> WORP Statistics --> Interface 1
--> Link Statistics Page --> Click here for Local SNR-Table. If the current
SNR is not meeting the minimum required SNR criteria for the current data rate,
then accordingly reduce the data rate.
- If SNR is more than the maximum optimal SNR limit (MONITOR --> WORP
Statistics --> Interface 1 --> Link Statistics Page --> Click here for Local
SNR-Table) then it causes radio receiver saturation thus impacting the
performance of the link. To overcome this situation, set the TPC appropriately
or enable ATPC to adjust the signal level automatically. Also, enabling DDRS
can help in choosing right data rate automatically.
8.9 Recovery Procedures
8.9.1 Soft Reset to Factory Defaults
Use this procedure to reset the network configuration values, including the Password, IP Address, and Subnet Mask. This
procedure resets configuration settings, but does not change the current device Image.
To use this procedure, in the web interface navigate to MANAGEMENT > Reset to Factory.
The device gets the default IP address (169.254.128.132). You can change the IP address using Web Interface or CLI. If you do not
have access to the HTTP or CLI interfaces, use Hard Reset to Factory Defaults procedure.
8.9.2 Hard Reset to Factory Defaults
If you cannot access the device or you have lost its password, you can reset the device to its factory default settings by using the
Reload button available on the PoE injector. With Reload, the configuration settings are deleted from the device and the device
reboots, using a factory default configuration.
:
• Please note that if the PoE supplied with the Product Package is not equipped with the Reload functionality then
you will have to use a PoE which is equipped with the Reload functionality to reset the device to its factory defaults.
• You need to use a pin or the end of a paperclip to press the Reload button.
: If you hold the Reload button for longer than 10 seconds, the device may go into Forced Reload mode, which erases the
device embedded software. This software must be reloaded through an ethernet connection with access to a TFTP
Server. See Forced Reload for instructions.
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Troubleshooting
8.9.3 Forced Reload
With Forced Reload, you bring the device into bootloader mode which erases the embedded software. Use this procedure only
as a last option if the device does not boot, and the Soft and Hard to Factory Defaults procedure does not help.
: With Forced Reload, the embedded software in the device will be erased. You will need to reload the software before the
device is operational.
The device will try to load the image using the default factory configuration parameters. If this fails, then it will enter either CLI
mode or ScanTool mode as per the user’s choice, with a message on the serial console “Starting ScanTool interface, press any key to
enter CLI 5”. Follow one of the procedures below to load a new image to the device:
Download a New Image Using Proxim’s ScanTool
Download a New Image Using the Bootloader CLI
As the CLI requires a physical connection to the device serial port, Proxim recommends you to use the ScanTool option.
: You cannot download a new image using Bootloader CLI onto Tsunami® MP-8160-CPE as it does not provide serial
interface support to the user.
8.9.3.1 Download a New Image Using Proxim’s ScanTool
To download the device image, you will need an Ethernet connection to the computer on which the TFTP server resides and to a
computer that is running ScanTool (this is either two separate computers connected to the same network or a single computer
running both programs).
ScanTool automatically detects the device that does not have a valid software image. The TFTP Server and Image File Name
parameters are enabled in the ScanTool’s Change screen so that you can download a new image to the device. (These fields are
disabled, if ScanTool does not detect a software image problem). See Initialization.
Preparing to Download the Device Image
Before starting the download process, you need to know the device IP Address, Subnet Mask, the TFTP Server IP Address, and the
Image file name. Make sure the TFTP server is running and properly configured to point to the folder containing the image to
be downloaded.
Download Procedure
Follow these steps to download a software image to the device by using ScanTool:
1. Download the latest software from http://support.proxim.com.
2. Copy the latest software updates to your TFTP server.
3. Launch Proxim’s ScanTool.
4. Highlight the entry for the device that you want to update and click Change.
5. Set IP Address Type to Static.
: You need to assign static IP information temporarily to the device since its DHCP client functionality is not
available when no image is installed on the device.
6. Enter an unused IP address that is valid on your network in the IP Address field. You may need to contact your
Network Administrator to get this address.
7. Enter the network’s Subnet Mask.
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Troubleshooting
8. Enter the network’s Gateway IP Address, if necessary. You may need to contact your Network Administrator to get
this address. You need to enter the default gateway address (169.254.128.133) only if the device and the TFTP server
are separated by a router.
9. By default, the IP address of the TFTP server is provided.
10. By default, the image file name is provided.
11. Click OK. The device will reboot and the download starts automatically.
12. Click OK when prompted to return to the Scan List screen after the device has been updated successfully.
13. Click Cancel to close the ScanTool.
When the download process is complete, start configuring the device.
8.9.3.2 Download a New Image Using the Bootloader CLI
To download the new device image, you will need an Ethernet connection to the computer on which the TFTP server resides. This
can be any computer on the LAN or connected to the device with an Ethernet cable.
You must also connect the device to a computer with a standard serial cable and use a terminal client. From the terminal, enter
the CLI commands to set the IP address of the device and to download the device image.
Preparing to Download the device image
Before starting, you need to know the device IP Address, Subnet Mask, the TFTP Server IP Address, and the device image file
name. Make sure the TFTP server is running and configured to point to the default directory containing the image to be
downloaded.
Download Procedure
1. Download the latest software from http://support.proxim.com.
2. Copy the latest software updates to your TFTP server’s default directory.
3. Connect the device serial port to your computer’s serial port.
4. Open your terminal emulator program and set the following connection properties:
Com Port: COM1, COM2 and so on, depending on your computer
Baud Rate: 115200
Data Bits: 8
Stop Bits: 1
Flow Control: None
Parity: None
5. Under File > Properties > Settings > ASCII Setup, enable the Send line ends with line feeds option.
Terminal Emulator program sends a line return at the end of each line of code.
The terminal display shows Power On Self Tests (POST) activity. After approximately 30 seconds, a message indicates:
Starting ScanTool interface, press any key to enter CLI 5”. After this message appears, press any key. Now the
bootloader prompt appears as below:
Bootloader=>
6. Enter the following commands:
Bootloader=> show (to view configuration parameters and values)
Bootloader=> set ipaddr <Access Point IP Address>
Bootloader=> set serverip <TFTP Server IP Address>
Bootloader=> set filename <Device Image File Name, including file extension>
Bootloader=> set gatewayip <Gateway Ip Address>
Bootloader=> set netmask <Network Mask>
Bootloader=> set ipaddrtype static
Bootloader=> show (to confirm your new settings)
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Troubleshooting
Bootloader=> reboot
Example:
Bootloader=> show
Bootloader=> set ipaddr 169.254.128.132
Bootloader=> set serverip 169.254.128.133
Bootloader=> set filename image_proxim.sei
Bootloader=> set gatewayip 169.254.128.133
Bootloader=> set netmask 255.255.255.0
Bootloader=> set ipaddrtype static
Bootloader=> show
Bootloader=> reboot
The device will reboot and then download the image file. When the download process is complete, configure the
device.
8.9.4 Setting IP Address using Serial Port
If the ScanTool fails to scan the device and users knows the login credentials then you can set the IP address for the device using
serial port.
8.9.4.1 Hardware and Software Requirements
Standard serial (RS-232) cable
• ASCII Terminal software
8.9.4.2 Attach the Serial Port Cable
1. Connect one end of the serial cable to the device and the other end to a serial port on your computer.
2. Power on the computer and the device.
8.9.4.3 Initializing the IP Address using CLI
After connecting the cable to the serial port, you can use the CLI to communicate with the device. CLI supports the
most-generic terminal emulation programs. In addition, many web sites offer shareware or commercial terminal programs
that you can download. Once the IP address has been assigned, you can use the HTTP interface or the Telnet to complete the
configuration.
Follow these steps to assign an IP address to the device:
1. Open your terminal emulation program and set the following connection properties:
Com Port: COM1, COM2, and so on depending on your computer
Baud Rate: 115200
Data Bits: 8
Stop Bits: 1
Flow Control: None
Parity: None
The terminal display shows Power On Self Tests (POST) activity, and then displays the software version. It prompts you to
enter the CLI username and password. The commands to enter the username and password are as follows:
#################################################|
# +-++-++-++-++-++-+
# |p||r||o||x||i||m|
# +-++-++-++-++-++-+
# Version: 1.0.0 B208100
Tsunami® 8100 Series - Software Management Guide 216
Troubleshooting
# Architecture: MIPS 7660
# Creation: 10-Aug-2009 (IST) 08:16:14 PM
#################################################|
Username: admin
Password:
This process may take up to 90 seconds.
2. Enter the CLI Username and password. By default username is admin and password is public. The terminal displays a
welcome message and then the CLI Prompt. Enter ‘show ip’ as shown below:
System Name> show ip
The following Ethernet IP information is displayed:
// Ethernet IP CONFIGURATION //
INDEX 1
IP Address : 10.0.0.1
Mask : 255.255.255.0
Address Type : static
// IP Gateway Configuration //
Gateway IP Address : 169.254.128.1
3. Change the IP address and other network values using the following CLI commands (use your own IP address and
Subnet mask).
System Name> enable
System Name# configure
System Name(config)#network
System Name(config-net)# ip
System Name(config-net-ip)# ethernet-ip-table
System Name(config-net-ip-etherip)# rowedit 1 ipaddress <ipaddress>
System Name(config-net-ip-etherip)# rowedit 1 mask <subnet mask>
System Name(config-net-ip-etherip)# rowedit 1 address-type <Address Type>
System Name(config-net-ip)# default-gateway <IP Gateway>
System Name(config-net-ip-etherip)#exit
System Name(config-net-ip)#exit
System Name(config-net)#exit
System Name(config)# commit 1
System Name(config)# reboot 1
4. After the device reboots, verify the new IP address by reconnecting to the CLI. Alternatively, you can ping the device
from a network computer to confirm that the new IP address has taken effect.
When a proper IP address is set, use HTTP interface or Telnet to configure the rest of the operating parameters of the
device.
8.10 Spectrum Analyzer
The ultimate way to discover whether there is a source of interference is to use a Spectrum Analyzer. Usually, the antenna is
connected to the analyzer when measuring. By turning the antenna 360°, one can check the direction of the interference. The
analyzer will also display the frequencies and the level of signal is detected. Proxim recommends performing the test at various
locations to find the most ideal location for the equipment.
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Troubleshooting
8.10.1 Avoiding Interference
When a source of interference is identified and when the level and frequencies are known, the next step is to avoid the
interference. Some of the following actions can be tried:
Change the channel to a frequency that has no or least interference.
Try changing the antenna polarization.
A small beam antenna looks only in one particular direction. Because of the higher gain of such an antenna, lowering
the output power or adding extra attenuation might be required to stay legal. This solution cannot help when the
source of interference is right behind the remote site.
Adjusting the antenna angle/height can help to reduce the interference.
Move the antennas to a different location on the premises. This causes the devices to look from a different angle, causing a
different pattern in the reception of the signals. Use obstructions such as buildings, when possible, to shield from the
interference.
8.10.2 Conclusion
A spectrum analyzer can be a great help to identify whether interference might be causing link problems on the device.
Before checking for interference, the link should be verified by testing in an isolated environment, to make sure that the
hardware works and your configurations are correct. The path analysis, cabling and antennas should be checked as well.
Statistics in the web interface under Monitor indicates if there is a link, if the link is healthy, and a continuous test can be done
using the Link Test.
Base Announces should increase continuously.
Registration Requests and Authentication Requests should be divisible by 3. WORP is designed in a way that each
registration sequence starts with 3 identical requests. It is not a problem if, once in a while, one of those requests is
missing. Missing requests frequently is to be avoided.
Monitor / Per Station (Information per connected remote partner): Check that the received signal level (RSL) is the
same on both sides. This should be the case if output power is the same. Two different RSLs indicate a broken
transmitter or receiver. A significant difference between Local Noise and Remote Noise could indicate a source of
interference near the site with the highest noise. Normally, noise is about -80 dBm at 36 Mbps. This number can vary
from situation to situation, of course, also in a healthy environment.
Monitor / Link Test (Information used by Administrators for on-the-spot checking): Check the received signal level (RSL)
and noise level. Compare the RSL with the values from path analysis. If the figures differ significantly from the values
recorded at the Per Station window, check for environment conditions that change over time.
8.11 Miscellaneous
8.11.1 Unable to Retrieve Event Logs through HTTPS
If using Internet Explorer 7 and are not able to retrieve event logs through HTTPS, do the following:
1. Open Internet Explorer
2. Navigate to Tool > Internet Options > Advanced
3. Go to Security and uncheck/unselect Do not save encrypted pages to disk
Alternatively, use Mozilla Firefox 3.5 or later.
Tsunami® 8100 Series - Software Management Guide 218
A
Feature Applicability
Tabulated below are the feature(s) applicable to the respective devices:
Tsunami® 8100 Series - Software Management Guide 219
B
Parameters Requiring Reboot
Tabulated below are the device parameters that require reboot for the changes to take effect:
Parameter(s) Web Page(s) Applicable Device Mode*
System Configuration
Radio Mode BASIC CONFIGURATION All
ADVANCED CONFIGURATION -> System
Frequency Domain BASIC CONFIGURATION All
ADVANCED CONFIGURATION -> System
Network Mode ADVANCED CONFIGURATION -> System All
Frequency Filter ADVANCED CONFIGURATION -> System All
Lower Edge
Frequency Filter ADVANCED CONFIGURATION -> System All
Upper Edge
IP Configuration (Bridge Mode)
Ethernet
Default Gateway IP
Address
DNS
BASIC CONFIGURATION
ADVANCED CONFIGURATION -> Network -> IP Configuration
All
All
All
IP Configuration (Routing Mode)
Ethernet
Wireless
Wireless (With
PPPoE)
Default Gateway IP
Address
DNS (Primary and
Secondary Address)
All
All
SU Mode
BASIC CONFIGURATION
ADVANCED CONFIGURATION -> Network -> IP Configuration All
All
NAT
Status ADVANCED CONFIGURATION -> Network -> NAT SU Mode / End Mode B mode
Dynamic Start Port ADVANCED CONFIGURATION -> Network -> NAT SU Mode / End Mode B mode
Dynamic End Port ADVANCED CONFIGURATION -> Network -> NAT SU Mode / End Mode B mode
PPPoE
Status ADVANCED CONFIGURATION -> Network -> PPPoE Client SU Mode
Tsunami® 8100 Series - Software Management Guide 220
Parameters Requiring Reboot
Parameter(s) Web Page(s) Applicable Device Mode*
Ethernet Interface Properties
Admin Status ADVANCED CONFIGURATION -> Network -> Ethernet
Wireless Properties
Channel Bandwidth BASIC CONFIGURATION
ADVANCED CONFIGURATION -> Wireless -> Properties
Channel Offset
ADVANCED CONFIGURATION -> Wireless -> Properties
Applicable only to,
Tsunami® MP-8160-BSU
Tsunami® MP-8160-SUA
Tsunami® MP-8160-CPE
Tsunami® MP-8150-CPE
Tsunami®
QB-8150-EPR-12/50
Frequency Extension ADVANCED CONFIGURATION -> Wireless -> MIMO Properties All
Upgrade Firmware and Configuration
Upgrade Firmware MANAGEMENT -> File Management -> Upgrade Firmware All
Upgrade MANAGEMENT -> File Management -> Upgrade Configuration All
Configuration
HTTP / HTTPS
Admin Password All
Monitor Password All
HTTP MANAGEMENT -> Services -> HTTP / HTTPS All
HTTP Port All
HTTPS All
Telnet / SSH
Admin Password
Monitor Password
Telnet
Telnet Port
Telnet Sessions
SSH
SSH Port
SSH Sessions
MANAGEMENT -> Services -> Telnet / SSH
All
All
All
All
All
All
All
All
SNMP (If SNMP v1-v2c is enabled)
Tsunami® 8100 Series - Software Management Guide 221
Parameters Requiring Reboot
Parameter(s) Web Page(s) Applicable Device Mode*
SNMP All
Version All
Read Password All
MANAGEMENT -> Services -> SNMP
Read / Write All
Password
SNMP Trap Host All
Table
SNMP (If SNMP v3 is enabled)
SNMP
Version
Security Level
Priv Protocol
Priv Password
Auth Protocol
Auth Password
SNMP Trap Host
Table
MANAGEMENT -> Services -> SNMP
All
All
All
All
All
All
All
All
Management Access Control
Access Table Status
Management
Access Control
Table
All
MANAGEMENT -> Access Control All
Reset to Factory MANAGEMENT -> Reset to Factory All
Convert QB to MP MANAGEMENT -> Convert QB to MP Applicable only to
• Tsunami® QB-8100-EPA
• Tsunami® QB-8150-EPR
* BSU: Refers to a Base Station
SU Mode: Refers to both SU and CPE
End Point A Mode: Refers to a device in End Point A mode
End Point B Mode: Refers to a device in End Point B mode
Tsunami® 8100 Series - Software Management Guide 222
C
Frequency Domains and Channels
Introduction
The Tsunami® Point-to-point and Point-to-multipoint products are available in two SKUs: United States (US) and rest of the
World
(WD) markets. Depending on the SKU, the device is hard programmed at factory to that Regulatory domain.
Regulatory
domain controls the list of frequency domains that are available in that SKU. Further each frequency domain will define the country
specific regulatory rules and frequency bands. This is a configurable option. The following table lists all the Tsunami® products with
their respective Frequency domains and SKUs supported.
Product Supported Frequency Band Supported SKUs
Tsunami® MP-8100-BSU 2.3 - 2.5 GHz and 4.9 - 6.0 GHz US, World
Tsunami® MP-8100-SUA 2.3 - 2.5 GHz and 4.9 - 6.0 GHz US, World
Tsunami® MP-8150-SUR 4.9 - 6.0 GHz US, World
Tsunami® MP-8150-CPE 5.3 - 6.1 GHz US, World
Tsunami® MP-8160-BSU 5.9 - 6.4 GHz World
Tsunami® MP-8160-SUA 5.9 - 6.4 GHz World
Tsunami® MP-8160-CPE 5.9 - 6.4 GHz World
Tsunami® QB-8100-EPA 2.3 - 2.5 GHz and 4.9 - 6.0 GHz US, World
Tsunami® QB-8150-EPR 4.9 - 6.0 GHz US, World
Tsunami® QB-8150-LNK-12/50 5.3 - 6.1 GHz US, World
The frequency domains can be easily configured using the Web Interface as it is a drop down list with all the available
domains. When the device is configured with CLI or SNMP, care has to be taken to set the domains using a predefined ENUM
value. Below is the list of all available frequency domains in each SKU with their corresponding ENUM value in the braces:
Frequency Domain ENUM Value
US SKU
United States 5.8 GHz 2
United States 2.4 GHz 3
United States2 (5.3 to 5.8 GHz) 22
World SKU
United States 5 GHz 1
World 5 GHz 4
World 4.9 GHz 5
World 2.4 GHz 6
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Frequency Domains and Channels
World 2.3 GHz 7
World 2.5 GHz 8
Canada 5 GHz 9
Europe 5.8 GHz 10
Europe 5.4 GHz 11
Europe 2.4 GHz 12
Russia 5 GHz 13
Taiwan 5 GHz 14
United States 5 GHz 15
Canada 5.8 GHz 16
World 6.4 GHz 17
UK 5.8 GHz 20
World 5.9 GHz 21
India 5.8 GHz 23
Brazil 5.4 GHz 24
Brazil 5.8 GHz 25
Australia 5.4 GHz 26
Australia 5.8 GHz 27
Example: To set WORLD 5 GHz as Frequency Domain using CLI
T8000-C1:65:7E(config)# system-configure
T8000-C1:65:7E(config-sysconfig)# network-mode bridge
Changes in Network mode requires Reboot.
T8000-C1:65:7E(config-sysconfig)# frequency-domain ?
Possible completions:
<Use 'show supported-frequency-domains' to get supported frequency domains
list>
Frequency Domain Configuration
T8000-C1:65:7E(config-sysconfig)# frequency-domain 4
Changes in Frequency Domain requires Reboot.
T8000-C1:65:7E(config-sysconfig)#exit
T8000-C1:65:7E(config)#exit
Tsunami® 8100 Series - Software Management Guide 224
Frequency Domains and Channels
2.4 GHz Channels
2.4 GHz frequency band is supported by the following devices:
• Tsunami® MP-8100-BSU
• Tsunami® MP-8100-SUA
• Tsunami® QB-8100-EPA
Frequency Frequency
Domain Band
(Start
Frequency ~
End
Frequency
in MHz)
Allowed Channels (Center Frequency in GHz)
5 MHz 10 MHz 20 MHz
40 PLUS
40 MINUS
MHz MHz
US SKU
United States 2412 ~ 2462 1 (2412), 1 (2412), 1 (2412), 1 (2412), 5 (2432),
2.4 GHz 2 (2417), 2 (2417), 2 (2417), 2 (2417), 6 (2437),
3 (2422)... 3 (2422)... 3 (2422)... 3 (2422)... 7 (2442)...
11 (2462). 11 (2462). 11 (2462). 7 (2442). 11 (2462).
World SKU
World 2.3 GHz 2277 ~ 2397 100 (2277), 100 (2277), 101 (2282), 101 (2282), 105 (2302),
101 (2282), 101 (2282), 102 (2287), 102 (2287), 106(2307),
102 (2287), 102 (2287), 103(2292)... 103 (2292)... 107(2312)...
103 (2292)... 103 (2292)... 122 (2387). 118 (2367). 122 (2387).
124 (2397). 123 (2392).
World 2.4 GHz 2412 ~ 2472 1 (2412), 1 (2412), 1 (2412), 1 (2412), 5 (2432),
2 (2417), 2 (2417), 2 (2417), 2 (2417), 6 (2437),
3 (2422)... 3 (2422)... 3 (2422)... 3 (2422)... 7 (2442)...
13 (2472). 13 (2472). 13 (2472). 9 (2452). 13 (2472).
World 2.5 GHz 2477 ~ 2507 200(2477), 200(2477), 201(2482), 201(2482) 205(2502)
201(2482), 201(2482), 202 (2487),
202 (2487), 202 (2487), 203(2492),
203(2492), 203(2492), 204(2497),
204(2497), 204(2497), 205 (2502).
205 (2502), 205 (2502),
206(2507). 206 (2507).
Europe 2.4 2412 ~ 2472 1 (2412), 1 (2412), 1 (2412), 1 (2412), 5 (2432),
GHz 2 (2417), 2 (2417), 2 (2417), 2 (2417), 6 (2437),
3 (2422)... 3 (2422)... 3 (2422)... 3 (2422)... 7 (2442)...
13 (2472). 13 (2472). 13 (2472). 9 (2452). 13 (2472).
Tsunami® 8100 Series - Software Management Guide 225
Frequency Domains and Channels
5 GHz Channels
5 GHz frequency band is supported by the following devices:
• Tsunami® MP-8100-BSU
• Tsunami® MP-8100-SUA
• Tsunami® MP-8150-SUR
• Tsunami® QB-8100-EPA
• Tsunami® QB-8150-EPR
• Tsunami® MP-8150-CPE
• Tsunami® QB-8150-EPR-12/50
Frequency Frequency Band
Domain (Start Frequency ~
End Frequency in
MHz)
Allowed Channels (Center Frequency in GHz)
5 MHz 10 MHz 20 MHz
40 PLUS
40 MINUS
MHz MHz
US SKU
United 5740 ~ 5830 (Non-DFS) 148(5740), 149(5745), 149(5745), 149(5745), 153(5765),
States 5.8 149(5745)... 150(5750)... 150(5750)... 150(5750)... 154(5770)...
GHz 165(5825), 164(5820), 164(5820), 160(5800), 164(5820),
166(5830). 165(5825). 165(5825). 161(5805). 165(5825).
United 5255 ~ 5325 (DFS) 51(5255), 52(5260), 52(5260), 52(5260), 56(5280),
States2 (5.3, 5740 ~ 5830 (Non-DFS) 52(5260)... 53(5265)... 53(5265)... 53(5265)... 57(5285)...
5.8 GHz) 64(5320), 63(5315), 63(5315), 59(5295), 63(5315),
65(5325). 64(5320). 64(5320). 60(5300). 64(5320).
148(5740), 149(5745), 149(5745), 149(5745), 153(5765),
149(5745)... 150(5750)... 150(5750)... 150(5750)... 154(5770)...
165(5825), 164(5820), 164(5820), 160(5800), 164(5820),
166(5830). 165(5825). 165(5825). 161(5805). 165(5825).
World SKU
United 5255 ~ 5325 (DFS) 51(5255), 52(5260), 52(5260), 52(5260), 56(5280),
States 5 5495 ~ 5585 (DFS) 52(5260)... 53(5265)... 53(5265)... 53(5265)... 57(5285)...
GHz 5655 ~ 5830 (Non-DFS) 64(5320), 63(5315), 63(5315), 59(5295), 63(5315),
65(5325). 64(5320). 64(5320). 60(5300). 64(5320).
99(5495), 100(5500), 100(5500), 100(5500), 104(5520),
100(5500)... 101(5505)... 101(5505)... 101(5505)... 105(5525)...
116(5580), 115(5575), 115(5575), 111(5555), 115(5575),
117(5585). 116(5580). 116(5580). 112(5560). 116(5580).
131(5655), 132(5660), 132(5660), 132(5660), 136(5680),
132(5660)... 133(5665)... 133(5665)... 133(5665)... 137(5685)...
140(5700), 139(5695), 139(5695), 135(5675), 139(5695),
141(5705). 140(5700). 140(5700). 136(5680). 140(5700).
148(5740), 149(5745), 149(5745), 149(5745), 153(5765),
149(5745)... 150(5750)... 150(5750)... 150(5750)... 154()5770)...
165(5825), 164(5820), 164(5820), 160(5800), 164(5820),
166(5830). 165(5825). 165(5825). 161(5805). 165(5825).
Tsunami® 8100 Series - Software Management Guide 226
Frequency Domains and Channels
Frequency Frequency Band
Domain (Start Frequency ~
End Frequency in
MHz)
Allowed Channels (Center Frequency in GHz)
5 MHz 10 MHz 20 MHz
40 PLUS
40 MINUS
MHz MHz
World 5 5155 ~ 6075 (Non-DFS) 31(5155), 31(5155), 32(5160), 32(5160), 36(5180),
GHz 32(5160)... 32(5160)... 33(5165)... 33(5165)... 37(5185)...
214(6070), 214(6070), 213(6065), 209(6045), 213(6065),
215(6075). 215(6075). 214(6070). 210(6050). 214(6070).
WORLD 4.9 4905 ~ 4995 (Non-DFS) 181(4905), 181(4905), 182(4910), 182(4910), 186(4930),
GHz* 182(4910)… 182(4910)… 183(4915)… 183(4915)… 187(4935),
188(4940). 188(4940). 188(4940). 188(4940). 188(4940),
10(4945), 10(4945), 10(4945), 10(4945), 10(4945),
20(4950)… 20(4950)… 20(4950)… 20(4950)… 20(4950)…
110(4995) 110(4995) 100(4990) 60(4970) 100(4990)
WORLD 5.9 5880 ~ 5920 (Non-DFS) 176(5880), 176(5880), 177(5885), 177(5885), 181(5905),
GHz* 177(5885)... 177(5885)... 178(5890)... 178(5890), 182(5910),
183(5915), 183(5915), 182(5910), 179(5895). 183(5915).
184(5920). 184(5920). 183(5915).
CANADA 5 5255 ~ 5325 (DFS) 51(5255), 52(5260), 52(5260), 52(5260), 56(5280),
GHz 5495 ~ 5585 (DFS) 52(5260)... 53(5265)... 53(5265)... 53(5265)... 57(5285)...
5655 ~ 5705 (DFS) 64(5320), 63(5315), 63(5315), 59(5295), 63(5315),
65(5325). 64(5320). 64(5320). 60(5300). 64(5320).
99(5495), 100(5500), 100(5500), 100(5500), 104(5520),
100(5500)... 101(5505)... 101(5505)... 101(5505)... 105(5525)...
116(5580) 115(5575), 115(5575), 111(5555), 115(5575),
117(5585). 116(5580). 116(5580). 112(5560). 116(5580).
131(5655), 132(5660), 132(5660), 132(5660), 136(5680),
132(5660)... 133(5665)... 133(5665)... 133(5665)... 137(5685)...
140(5700), 139(5695), 139(5695), 135(5675), 139(5695),
141(5705). 140(5700). 140(5700). 136(5680). 140(5700).
EUROPE 5495 ~ 5585 (DFS) 99(5495), 100(5500), 100(5500), 100(5500), 104(5520),
5.4 GHz 5655 ~ 5705 (DFS) 100(5500)... 101(5505)... 101(5505)... 101(5505)... 105(5525)...
116(5580), 115(5575), 115(5575), 111(5555), 115(5575),
117(5585). 116(5580). 116(5580). 112(5560). 116(5580).
131(5655), 132(5660), 132(5660), 132(5660), 136(5680),
132(5660)... 133(5665)... 133(5665)... 133(5665)... 137(5685)...
140(5700), 139(5695), 139(5695), 135(5675), 139(5695),
141(5705). 140(5700). 140(5700). 136(5680). 140(5700).
EUROPE 5735 ~ 5870 (DFS) 147(5735), 147(5735), 149(5745), 149(5745), 153(5765),
5.8 GHz 148(5740)... 148(5740)... 150(5750)... 150(5750)… 154(5770)...
173(5865), 173(5865), 172(5860), 168(5840), 172(5860),
174(5870). 174(5870). 173(5865). 169(5845). 173(5865).
Tsunami® 8100 Series - Software Management Guide 227
Frequency Domains and Channels
Frequency Frequency Band
Domain (Start Frequency ~
End Frequency in
MHz)
Allowed Channels (Center Frequency in GHz)
5 MHz 10 MHz 20 MHz
40 PLUS
40 MINUS
MHz MHz
RUSSIA 5155 ~ 6075 (Non-DFS) 31(5155), 31(5155), 32(5160), 32(5160), 36(5180),
5 GHz 32(5160)... 32(5160)... 33(5165)... 33(5165)... 37(5185)...
214(6070), 214(6070), 213(6065), 219(6045), 213(6065),
215(6075). 215(6075). 214(6070). 210(6050). 214(6070).
Taiwan 5 5495 ~ 5705 (DFS) 99(5495), 100(5500), 100(5500), 100(5500), 104(5520),
GHz 5740 ~ 5810 (Non-DFS) 100(5500)... 101(5505)... 101(5505)... 101(5505)... 105(5525)...
140(5700), 139(5695), 139(5695), 135(5675), 139(5695),
141(5705). 140(5700). 140(5700). 136(5680). 140(5700).
148(5740), 149(5745), 149(5745), 149(5745), 153(5765),
149(5745)... 150(5750)... 150(5750)... 150(5750)... 154(5770)...
161(5805), 160(5800), 160(5800), 156(5780), 160(5800),
162(5810). 161(5805). 161(5805). 157(5785). 161(5805).
India 5.8 5830 ~ 5870 (Non-DFS) 166(5830), 166(5830), 167(5835), 167(5835), 171(5855),
GHz 167(5835)... 167(5835)... 168(5840)... 168(5840), 172(5860),
173(5865), 173(5865), 172(5860), 169(5845). 173(5865).
174(5870). 174(5870). 173(5865).
CANADA 5735 ~ 5855 (Non-DFS) 147(5735), 147(5735), 148(5740), 148(5740), 152(5760),
5.8 GHz 148(5740)... 148(5740)... 149(5745)... 149(5745)... 153(5765)...
170(5850), 170(5850), 169(5845), 165(5825), 169(5845),
171(5855). 171(5855). 170(5850). 166(5830). 170(5850).
U.K 5730 ~ 5790 (DFS) 146(5730), 147(5735), 147(5735), 147(5735), 151(5755),
5.8 GHz 5820 ~ 5845 (DFS) 147(5735)... 148(5740)... 148(5740)... 148(5740)... 152(5760)...
157(5785), 156(5780), 156(5780), 152(5760), 156(5780),
158(5790), 157(5785), 157(5785), 153(5765). 157(5785).
164(5820)... 167(5835). 167(5835).
169(5845).
Australia 5475 ~ 5595 (DFS) 95(5475), 95(5475), 96(5480), 96(5480), 100(5500),
5.4 GHz 5655 ~ 5720 (DFS) 96(5480) 96(5480)… 97(5485)… 97(5485)… 101(5505)…
97(5485)… 118(5590), 117(5585), 114(5570), 118(5590),
119(5595). 119(5595). 118(5590). 132(5660), 136(5680),
131(5655) 131(5655) 132(5660), 133(5665)… 137(5685)…
132(5660) 132(5660) 133(5665)… 139(5695) 143(5715).
133(5665)… 133(5665)… 143(5715).
144(5720). 144(5720).
Australia 5730 ~ 5845 (Non-DFS) 146(5730), 146(5730), 147(5735), 147(5735), 151(5755),
5.8 GHz 147(5735)… 147(5735), 148(5740)… 148(5740)... 152(5760)…
169(5845). 148(5740)… 168(5840). 164(5820). 168(5840).
169(5845).
Tsunami® 8100 Series - Software Management Guide 228
Frequency Domains and Channels
Frequency Frequency Band
Domain (Start Frequency ~
End Frequency in
MHz)
Allowed Channels (Center Frequency in GHz)
5 MHz 10 MHz 20 MHz
40 PLUS
40 MINUS
MHz MHz
Brazil 5475 ~ 5720 (DFS) 95(5475), 95(5475), 96(5480), 96(5480), 100(5500),
5.4 GHz 96(5480), 96(5480), 97(5485)… 97(5485)… 101(5505)…
97(5485)… 97(5485)… 142(5710), 138(5690)... 142(5710),
144(5720). 144(5720). 143(5715). 139(5695). 143(5715).
Brazil 5730-5845 (Non-DFS) 146(5730), 146(5730), 147(5735), 147(5735), 151(5755),
5.8 GHz 147(5735)… 147(5735), 148(5740)… 148(5740)... 152(5760)…
169(5845). 148(5740)… 168(5840). 164(5820). 168(5840).
169(5845).
* Not applicable for MP-8150-CPE and QB-8150-EPR-12/50 products.
Tsunami® 8100 Series - Software Management Guide 229
Frequency Domains and Channels
6.4 GHz Channels
6.4 GHz frequency band is supported by the following devices:
• Tsunami® MP-8160-BSU
• Tsunami® MP-8160-SUA
• Tsunami® MP-8160-CPE
Frequency Frequency
Domain Band
(Start
Frequency ~
End
Frequency
in MHz)
Allowed Channels (Center Frequency)
5 MHz 10 MHz 20 MHz
40 PLUS
40 MINUS
MHz MHz
World 6.4 GHz 5905 ~ 6420 181 (5905), 181 (5905), 182 (5910), 182 (5910), 186 (5930)
182 (5910), 182 (5910), 183 (5915), 183 (5915), 187 (5935),
183 (5915)... 183 (5915)... 184 (5920)... 184 (5920)... 188 (5940)...
284 (6420). 284 (6420). 283 (6415). 279 (6395). 283 (6415).
: The center frequency listed in the above tables are based on channel offset set to ‘0’. If channel offset is set to any
value other than ‘0’ then the center frequency will be shifted accordingly. You can set the channel offset ranging from
-2 to
+2 MHz in the following devices: Tsunami® MP-8150-CPE; Tsunami® QB-8150-EPR-12/50; Tsunami®
MP-8160-BSU; Tsunami® MP-8160-SUA and Tsunami® MP-8160-CPE.
Details for 40MHz Bandwidth
While choosing 40MHz bandwidth, you can select 40 PLUS or 40 MINUS. 40 PLUS means the center frequency calculation is done
for 20MHz and add another 20MHz to the top edge of 20MHz. 40 MINUS means the center frequency calculation is done for
20MHz and add another 20MHz to the bottom edge of 20MHz.
For 40 PLUS
• 2.4GHz ->
- Channel 1 = 2412 MHz
- Bandwidth starts from 2403 MHz and ends at 2442 MHz
• 5GHz ->
- Channel 52 = 5260 MHz
- Bandwidth starts from 5251 MHz and ends at 5290 MHz
For 40 MINUS
• 2.4GHz ->
- Channel 5 = 2432 MHz
- Bandwidth starts from 2403 MHz and ends at 2442 MHz
• 5GHz ->
- Channel 56 = 5280 MHz
- Bandwidth starts from 5251 MHz and ends at 5290 MHz
Tsunami® 8100 Series - Software Management Guide 230
D
SNR Information
Tabulated below are the SNR values for the following devices:
Tsunami® MP-8100-BSU
Tsunami® MP-8100-SUA
Tsunami® MP-8150-SUR
Tsunami® QB-8100-EPA
Tsunami® QB-8150-EPR
2.4 GHz
MCS No
Index Modulation
of
Streams
5 MHz
Data
Min Max
Data
Rate
SNR
SNR
Rate
10 MHz 20 MHz
Min Max
Data
Min
SNR SNR
Rate
SNR
40 MHz
Max
Data
Min Max
SNR
Rate
SNR
SNR
MCS0 BPSK 1/2 Single 1.6 10 86 3.3 10 86 6.5 12 86 13.5 26 80
MCS1 QPSK 1/2 Single 3.3 15 86 6.5 16 86 13 21 86 27 26 80
MCS2 QPSK 3/4 Single 4.9 21 84 9.7 21 84 19.5 21 84 40.5 26 79
MCS3 16 QAM 1/2 Single 6.5 23 82 13 23 82 26 23 82 54 30 77
MCS4 16 QAM 3/4 Single 9.7 26 80 19.5 26 80 39 25 80 81 33 77
MCS5 64 QAM 2/3 Single 13 29 79 26 29 79 52 27 78 108 37 76
MCS6 64 QAM 3/4 Single 14.6 30 79 29.3 31 78 58.5 30 77 121.5 40 75
MCS7 64 QAM 5/6 Single 16.2 32 78 32.5 32 78 65 32 77 135 42 75
MCS8 BPSK 1/2 Dual 3.3 12 86 6.5 14 86 13 14 86 27 16 80
MCS9 QPSK 1/2 Dual 6.5 20 84 13 21 84 26 21 84 54 26 80
MCS10 QPSK 3/4 Dual 9.7 22 82 19.5 23 82 39 22 82 81 28 79
MCS11 16 QAM 1/2 Dual 13 23 80 26 23 80 52 24 80 108 32 77
MCS12 16 QAM 3/4 Dual 19.5 27 80 39 27 80 78 30 78 162 35 77
MCS13 64 QAM 2/3 Dual 26 30 79 52 30 79 104 34 78 216 37 76
MCS14 64 QAM 3/4 Dual 29.3 36 78 58.5 35 77 117 37 77 243 43 75
MCS15 64 QAM 5/6 Dual 32.5 39 78 65 38 77 130 39 76 270 45 75
5 GHz
MCS No
Index Modulation
of
Streams
5 MHz
Data
Min
Max
Data
Rate
SNR SNR
Rate
10 MHz 20 MHz
Min Max
Data
Min
SNR
SNR
Rate
SNR
40 MHz
Max
Data
Min Max
SNR
Rate
SNR SNR
MCS0 BPSK 1/2 Single 1.6 6 86 3.3 7 86 6.5 6 86 13.5 9 80
Tsunami® 8100 Series - Software Management Guide 231
SNR Information
5 GHz
MCS No
Index Modulation
of
Streams
5 MHz
Data
Min
Max
Data
Rate
SNR SNR
Rate
10 MHz 20 MHz
Min Max
Data
Min
SNR
SNR
Rate
SNR
40 MHz
Max
Data
Min Max
SNR
Rate
SNR SNR
MCS1 QPSK 1/2 Single 3.3 8 86 6.5 8 86 13 9 86 27 11 80
MCS2 QPSK 3/4 Single 4.9 10 84 9.7 13 84 19.5 11 84 40.5 15 79
MCS3 16 QAM 1/2 Single 6.5 14 82 13 16 82 26 14 82 54 16 77
MCS4 16 QAM 3/4 Single 9.7 17 80 19.5 20 80 39 18 80 81 20 77
MCS5 64 QAM 2/3 Single 13 22 79 26 24 79 52 22 78 108 24 76
MCS6 64 QAM 3/4 Single 14.6 25 79 29.3 26 78 58.5 25 77 121.5 27 75
MCS7 64 QAM 5/6 Single 16.2 28 78 32.5 29 78 65 28 77 135 30 75
MCS8 BPSK 1/2 Dual 3.3 8 86 6.5 9 86 13 9 86 27 9 80
MCS9 QPSK 1/2 Dual 6.5 12 84 13 12 84 26 12 84 54 13 80
MCS10 QPSK 3/4 Dual 9.7 14 82 19.5 15 82 39 14 82 81 17 79
MCS11 16 QAM 1/2 Dual 13 16 80 26 16 80 52 16 80 108 22 77
MCS12 16 QAM 3/4 Dual 19.5 20 80 39 21 80 78 20 78 162 25 77
MCS13 64 QAM 2/3 Dual 26 25 79 52 26 79 104 26 78 216 27 76
MCS14 64 QAM 3/4 Dual 29.3 29 78 58.5 29 77 117 29 77 243 30 75
MCS15 64 QAM 5/6 Dual 32.5 30 78 65 30 77 130 30 76 270 33 75
Tabulated below are the SNR values for the following device(s) in legacy mode:
• Tsunami® MP-8100-BSU
2.4 GHz 5 GHz
Modulation 5 MHz 10 MHz 20 MHz 5 MHz 10 MHz 20 MHz
Data Min Max Data Min Max Data Min Max Min Max Min Max Min Max
Rate SNR SNR Rate SNR SNR Rate SNR SNR SNR SNR SNR SNR SNR SNR
BPSK 1/2 1.5 10 84 3 10 84 6 13 84 8 84 8 84 7 81
BPSK 3/4 2.25 10 84 4.5 11 84 9 13 84 9 84 9 84 8 81
QPSK 1/2 3 12 84 6 11 84 12 15 84 10 82 10 82 9 81
QPSK 3/4 4.5 14 84 9 13 84 18 15 84 12 82 11 82 12 81
16QAM 1/2 6 17 82 12 17 80 24 22 80 16 82 16 82 15 80
16QAM 3/4 9 20 82 18 23 78 36 25 73 18 82 18 80 18 80
64QAM 2/3 12 27 81 24 29 76 48 28 73 24 80 24 80 24 78
64QAM 3/4 13.5 29 80 27 30 74 54 29 72 27 80 27 80 27 76
Tsunami® 8100 Series - Software Management Guide 232
SNR Information
Tabulated below are the SNR values for the following devices:
• Tsunami® MP-8150-CPE
• Tsunami® QB-8150-EPR-12/50
5 GHz
MCS No
Index Modulation
of
Streams
5 MHz
Data
Min Max
Data
Rate
SNR SNR
Rate
10 MHz 20 MHz
Min
Max
Data
Min
SNR SNR
Rate
SNR
40 MHz
Max
Data
Min Max
SNR
Rate
SNR SNR
MCS0 BPSK 1/2 Single 1.6 8 82 3.3 8 82 6.5 8 82 13.5 8 82
MCS1 QPSK 1/2 Single 3.3 8 82 6.5 9 82 13 9 82 27 9 82
MCS2 QPSK 3/4 Single 4.9 10 82 9.7 11 82 19.5 11 82 40.5 11 80
MCS3 16 QAM 1/2 Single 6.5 13 82 13 15 82 26 17 82 54 16 80
MCS4 16 QAM 3/4 Single 9.7 16 82 19.5 19 82 39 19 82 81 18 80
MCS5 64 QAM 2/3 Single 13 20 81 26 22 81 52 23 81 108 23 79
MCS6 64 QAM 3/4 Single 14.6 22 80 29.3 24 80 58.5 25 80 121.5 24 79
MCS7 64 QAM 5/6 Single 16.2 24 80 32.5 26 80 65 26 80 135 26 79
MCS8 BPSK 1/2 Dual 3.3 9 82 6.5 8 82 13 9 82 27 9 82
MCS9 QPSK 1/2 Dual 6.5 10 82 13 10 82 26 12 82 54 11 80
MCS10 QPSK 3/4 Dual 9.7 12 82 19.5 12 82 39 13 82 81 13 80
MCS11 16 QAM 1/2 Dual 13 16 82 26 16 82 52 18 82 108 15 78
MCS12 16 QAM 3/4 Dual 19.5 19 80 39 20 82 78 19 82 162 20 68
MCS13 64 QAM 2/3 Dual 26 24 80 52 24 80 104 24 80 216 24 60
MCS14 64 QAM 3/4 Dual 29.3 29 80 58.5 30 78 117 27 78 243 29 58
MCS15 64 QAM 5/6 Dual 32.5 33 80 65 33 78 130 32 78 270 32 56
Tabulated below are the SNR values for the following devices:
• Tsunami® MP-8160-BSU
• Tsunami® MP-8160-SUA
• Tsunami® MP-8160-CPE
6.4 GHz
MCS No
Index Modulation
of
Streams
5 MHz
Data
Min Max
Data
Rate
SNR SNR
Rate
10 MHz 20 MHz
Min
Max
Data
Min
SNR SNR
Rate
SNR
40 MHz
Max
Data
Min Max
SNR
Rate
SNR SNR
MCS0 BPSK 1/2 Single 1.6 6 87 3.3 6 87 6.5 6 87 13.5 7 87
MCS1 QPSK 1/2 Single 3.3 8 87 6.5 8 87 13 7 87 27 8 86
Tsunami® 8100 Series - Software Management Guide 233
SNR Information
6.4 GHz
MCS No
Index Modulation
of
Streams
5 MHz
Data
Min Max
Data
Rate
SNR SNR
Rate
10 MHz 20 MHz
Min
Max
Data
Min
SNR SNR
Rate
SNR
40 MHz
Max
Data
Min Max
SNR
Rate
SNR SNR
MCS2 QPSK 3/4 Single 4.9 10 86 9.7 10 84 19.5 10 86 40.5 12 82
MCS3 16 QAM 1/2 Single 6.5 13 84 13 14 84 26 13 82 54 13 74
MCS4 16 QAM 3/4 Single 9.7 16 80 19.5 16 78 39 16 76 81 19 70
MCS5 64 QAM 2/3 Single 13 21 74 26 21 70 52 20 70 108 21 62
MCS6 64 QAM 3/4 Single 14.6 22 70 29.3 23 67 58.5 22 67 121.5 24 56
MCS7 64 QAM 5/6 Single 16.2 24 67 32.5 24 65 65 24 65 135 27 55
MCS8 BPSK 1/2 Dual 3.3 8 87 6.5 8 87 13 7 86 27 10 86
MCS9 QPSK 1/2 Dual 6.5 10 87 13 10 87 26 11 84 54 12 82
MCS10 QPSK 3/4 Dual 9.7 15 84 19.5 13 84 39 13 82 81 15 75
MCS11 16 QAM 1/2 Dual 13 16 80 26 17 80 52 17 78 108 18 74
MCS12 16 QAM 3/4 Dual 19.5 20 74 39 23 74 78 20 71 162 22 56
MCS13 64 QAM 2/3 Dual 26 25 70 52 24 66 104 24 65 216 25 55
MCS14 64 QAM 3/4 Dual 29.3 27 66 58.5 27 62 117 27 62 243 27 53
MCS15 64 QAM 5/6 Dual 32.5 28 64 65 29 62 130 29 62 270 30 52
Tsunami® 8100 Series - Software Management Guide 234
E
Bootloader CLI and ScanTool
Bootloader CLI
The Bootloader CLI is a minimal subset of the normal CLI used to perform initial configuration of the device. The Bootloader CLI is
available when the device embedded software is not running.
This interface is only accessible through the serial interface, if:
The device does not contain a software image
An existing image is corrupted
An automatic (default) download of image over TFTP has failed
The Bootloader CLI provides the ability to configure the initial setup parameters; and depending on this configuration, a
software file is downloaded to the device during startup.
The Bootloader CLI supports the following commands:
factory_reset: Restore the factory settings
help: Print Online Help
reboot: Reboot the device
set: Set the parameters
show: Show the parameters
The Bootloader CLI supports the following parameters (for viewing and modifying):
ipaddr: IP Address
systemname: System Name
gatewayip: Gateway IP Address
serverip: Server IP Address
ipaddrtype: IP Address Type
netmask: Net Mask
filename: Image file name (including the file extension)
If the Bootloader fails to load the firmware from flash, it tries to get the firmware from the network. While trying to get
firmware from the network, the device should be powered on using Ethernet 1 interface of the device. The default
configuration of the Bootloader parameters are as follows:
Parameter Value
ipaddr 169.254.128.132
netmask 255.255.255.0
gatewayip 169.254.128.132
systemname systemname
serverip 169.254.128.133
filename imagename
ipaddrtype dynamic
Tsunami® 8100 Series - Software Management Guide 235
Bootloader CLI and ScanTool
To Load the Firmware from the Network
• Use the show command to view the parameters and their values, and use the set command to set the parameter
value.
To Get the IP Parameters Dynamically for Loading the Firmware
1. Set the ipaddrtype to dynamic
2. Run the BOOTP and TFTP Servers followed by reboot of the device
When the device reboots, the device gets the IP Address and Boot filename from the BOOTP server. You need not change any
of the default Bootloader parameters. After BOOTP succeeds, the device initiates a TFTP request with the filename it gets
from BOOTP.
To Load the Firmware by Using Static IP Parameters
1. Use the set command to set the IP parameters like ‘ipaddr’, ‘serverip’, ‘filename’ and also set the parameter
‘ipaddrtype’ to static.
2. Run the TFTP Server followed by reboot of the device
When the device reboots, the TFTP request is initiated with the value taken from the parameter “filename”. This request is sent to
the IP address set as "serverip”. In this case, the TFTP Server should be reachable to the device.
ScanTool
If you want to access the device with Scantool, then the host running the ScanTool should also be in the same network as the device.
The ScanTool broadcast requests are discarded by the routers if the device and the host running the ScanTool are in different
network. This means that the ScanTool cannot discover the device.
A device in Bootloader can be recognized by looking at the system description. If the system description does not contain any build
number in braces, conclude that the device is in Bootloader mode.
For example:
Tsunami MP-8100-BSU-WD - Description of the device
v2.4.0 - Firmware Version
SN-11Pl15010031 - Serial Number
BL-v1.3.1 - Bootloader version
Figure E-1 Scan Tool View of a Device in Bootloader Mode (An Example)
Tsunami® 8100 Series - Software Management Guide 236
F
Lightning Protection
Lightning protection is used to maximize the reliability of the communications equipment by safely re-directing current from a
lightning strike or a power surge traveling along the Cat 5/Cat5e/Cat 6 Ethernet cabling to the ground using the shortest path
possible. Designing a proper grounding system prior to installing any communications equipment is critical to minimize the
possibility of equipment damage, void warranties, and cause serious injury.
The surge arrestor (sometimes referred to as a lightning protector) can protect your sensitive electronic equipment from
high-voltage surges caused by discharges and transients at the PoE.
Proxim Wireless offers superior lightning and surge protection for Tsunami® series products. Contact your reseller or
distributor for more information.
Tsunami® 8100 Series - Software Management Guide 237
G
Abbreviations
A
ACL Access Control List
ACS Automatic Channel Selection
AES Advanced Encryption Standard
ALG Application Level Gateway
ARP Address Resolution Protocol
ATPC Adaptive Transmit Power Control
B
BSU Base Station Unit
C
CCP Compression Control Protocol
CHAP Challenge Handshake Authentication Protocol
CLI Command Line Interface
CIR Committed Information Rate
CPE Customer Premises Equipment
CRC Cyclic Redundancy Check
D
DDRS Dynamic Data Rate Selection
DES Data Encryption Standard
DFS Dynamic Frequency Selection
DHCP Dynamic Host Configuration Protocol
DNS Domain Name System
DSL Digital Subscriber Line
E
EIRP Equivalent Isotropically Radiated Power
ETSI European Telecommunications Standards Institute
F
Tsunami® 8100 Series - Software Management Guide 238
Abbreviations
FCC Federal Communications Commission
FCS Frame Check Sequence
G
Gbps Gigabit Per Second
GPL General Public License
GRE Generic Routing Encapsulation
H
HTTP HyperText Transfer Protocol
HTTPS HyperText Transfer Protocol Secure
I
IANA Internet Assigned Numbers Authority (IANA)
IC Industry Canada
ICMP Internet Control Message Protocol
IGMP Internet Group Management Protocol
ISP Internet Service Provider
ITS Intelligent Transportation System
L
LACP Link Aggregation Control Protocol
LAN Local Area Network
LCP Link Configuration Protocol
LED Light Emitting Diode
LGPL Lesser General Public License
M
MAN Metropolitan Area Networks
Mbps Megabits Per Second
MD5 Message-Digest algorithm
MIB Management Information Base
MIMO Multiple-input and multiple-output
MIR Maximum Information Rate
MP Multipoint
MPPE Microsoft Point-to-Point Encryption
Tsunami® 8100 Series - Software Management Guide 239
Abbreviations
MSCHAP v2 Microsoft Challenge-Handshake Authentication Protocol
MTU Maximum Transmission Unit
N
NAPT Network Address Port Translation
NAT Network Address Translation
NCP Network Control Protocol
NMS Network Management System
NOP Non Occupancy Period
P
PAP Password Authentication Protocol
PC Personal Computer
PoE Power Over Ethernet
PPPoE Point-to-point Protocol over Ethernet
PTMP Point-to-multipoint
PTP Point-to-point
PVES ProximVision ES
Q
QB Quick Bridge
QoS Quality of Service
R
RADIUS Remote Authentication Dial In User Service
RAS Remote Access Services
RF Radio Frequency
RIP Routing Information Protocol
RMA Return Material Authorization
RSSI Received Signal Strength Indicator
S
SHA Secure Hash Algorithm
SKU Stock Keeping Unit
SNMP Simple Network Management Protocol
SNR Signal-to-noise Ratio
Tsunami® 8100 Series - Software Management Guide 240
Abbreviations
SNTP Simple Network Time Protocol
SSH Secure Shell
SSL Secure Socket Layer
STP Spanning Tree Protocol
SU Subscriber Unit
T
TBC Text Based Configuration
TCP Transmission Control Protocol
TFTP Trivial File Transfer Protocol
TKIP Temporal Key Integrity Protocol
TPC Transmit Power Control
TPID Tag Protocol Identifier
TTL Time to Live
U
UDP User Datagram Protocol
UTP Unshielded Twisted Pair
V
VLAN Virtual Local Area Network
W
WEP Wired Equivalent Privacy
WORP Wireless Outdoor Router Protocol
Tsunami® 8100 Series - Software Management Guide 241
H
Statement of Warranty
Warranty Coverage
Proxim Wireless Corporation warrants that its products are manufactured solely from new parts, conform substantially to
specifications, and will be free of defects in material and workmanship for a Warranty Period of 1 year from the date of
purchase.
Repair or Replacement
In the event where the product fails to perform in accordance with its specification during the Warranty Period, Proxim offers
return-to-factory repair or replacement, with a thirty (30) business-day turnaround from the date of receipt of the defective
product at a Proxim Wireless Corporation Repair Center. When Proxim Wireless has reasonably determined that a returned
product is defective and is still under Warranty, Proxim Wireless shall, at its option, either: (a) repair the defective product; (b)
replace the defective product with a refurbished product that is equivalent to the original; or (c) where repair or replacement cannot
be accomplished, refund the price paid for the defective product. The Warranty Period for repaired or replacement products
shall be ninety (90) days or the remainder of the original Warranty Period, whichever is longer. This constitutes Buyers sole and
exclusive remedy and Proxim Wireless’s sole and exclusive liability under this Warranty.
Limitations of Warranty
The express warranties set forth in this Agreement will not apply to defects in a product caused; (i) through no fault of
Proxim Wireless during shipment to or from Buyer, (ii) by the use of software other than that provided with or installed in the
product, (iii) by the use or operation of the product in an application or environment other than that intended or
recommended by Proxim Wireless, (iv) by modifications, alterations, or repairs made to the product by any party other than
Proxim Wireless or Proxim Wireless’s authorized repair partners, (v) by the product being subjected to unusual physical or
electrical stress, or (vii) by failure of Buyer to comply with any of the return procedures specified in this Statement of
Warranty.
Buyers should return defective products within the first 30 days to the merchant from which the products were purchased.
Buyers can contact a Proxim Wireless Customer Service Center either by telephone or via web. Calls for support for products that
are near the end of their warranty period should be made not longer than seven (7) days after expiration of warranty. Support
and repair of products that are out of warranty will be subject to a repair fee. Contact information is shown below. Additional
support information can be found at Proxim Wireless’s web site at http://support.proxim.com.
USA and Canada Customers
Call Technical Support: Phone: 408-383-7700
Toll Free: 866-674-6626
Hours: 6:00 AM to 6:00 P.M. Monday - Friday, Pacific Time
APAC Customers
Call Technical Support: Phone: +91 40 23115490
Hours: 9:00 AM to 6:00 P.M. Monday - Friday, IST (UTC/GMT +5:30 hrs)
International Customers
Call Technical Support: Phone: 408-383-7700
Hours: 6:00 AM to 6:00 P.M. Monday - Friday, Pacific Time
Tsunami® 8100 Series - Software Management Guide 242
Statement of Warranty
Hours of Operation
When contacting the Customer Service for support, Buyer should be prepared to provide the product description and serial
number and a description of the problem. The serial number should be on the product.
In the event the Customer Service Center determines that the problem can be corrected with a software update, Buyer might be
instructed to download the update from Proxim Wireless’s web site or, if that’s not possible, the update will be sent to Buyer. In
the event the Customer Service Center instructs Buyer to return the product to Proxim Wireless for repair or replacement, the
Customer Service Center will provide Buyer a Return Material Authorization (“RMA”) number and shipping instructions. Buyer
must return the defective product to Proxim Wireless, properly packaged to prevent damage, shipping prepaid, with the RMA
number prominently displayed on the outside of the container.
Calls to the Customer Service Center for reasons other than product failure will not be accepted unless Buyer has purchased a
Proxim Wireless Service Contract or the call is made within the first thirty (30) days of the product’s invoice date. Calls that are
outside of the 30-day free support time will be charged a fee of $250.00 (US Dollars) per Support Call.
If Proxim Wireless reasonably determines that a returned product is not defective or is not covered by the terms of this
Warranty, Buyer shall be charged a service charge and return shipping charges.
Other Information
Search Knowledgebase
Proxim Wireless stores all resolved problems in a solution database at the following URL: http://support.proxim.com.
Ask a Question or Open an Issue
Submit a question or open an issue to Proxim Wireless technical support staff at the following URL:
http://support.proxim.com/cgi-bin/proxim.cfg/php/enduser/ask.php.
Tsunami® 8100 Series - Software Management Guide 243
I
Technical Services and Support
Obtaining Technical Service and Support
If you are having trouble using the Proxim product, please read this manual and the additional documentation provided with your
product. If you require additional support to resolve your issue, please be ready to provide the following information before you
contact Proxim’s Technical Services team:
• Product information
- Part number and serial number of the suspected faulty device
• Trouble/error information
- Trouble/symptom being experienced
- Activities completed to confirm fault
- Network information (what kind of network are you using?)
- Circumstances that preceded or led up to the error
- Message or alarms viewed
- Steps taken to reproduce the problem
ServPak information (if a Servpak customer):
- ServPak account number
• Registration information
- If the product is not registered, date and location where you purchased the product
: Technical Support is free for the first 90 days from the date of purchase.
Support Options
Proxim eService Web Site Support
The Proxim eService Web site is available 7x24x365 at http://support.proxim.com. On
the Proxim eService Web Site, you can access the following services:
New Product Registration: Register your product to gain access to technical updates, software downloads, and free
technical support for the first 90 days from receipt of hardware purchase.
Open a Ticket or RMA: Open a ticket or RMA
Search Knowledgebase: Locate white papers, software upgrades, and technical information.
ServPak Support: Learn more about Proxim’s ServPak global support service options.
Your Stuff: Track status of your tickets or RMAs and receive product update notifications.
Provide Feedback: Submit suggestions or other types of feedback.
Customer Survey: Submit an online Customer Survey response.
Tsunami® 8100 Series - Software Management Guide 244
Technical Services and Support
Telephone Support
Contact technical support via telephone as follows:
USA & Canada Customers
Call Technical Support: Phone: 408-383-7700
Toll Free: 866-674-6626
Hours: 6:00 AM to 6:00 P.M. Monday - Friday, Pacific Time
APAC Customers
Call Technical Support: Phone: +91 40 23115490
Hours: 9:00 AM to 6:00 P.M. Monday - Friday, IST (UTC/GMT +5:30 hrs)
International Customers
Call Technical Support: Phone: 408-383-7700
Hours: 6:00 AM to 6:00 P.M. Monday - Friday, Pacific Time
ServPak Support
To provide even greater investment protection, Proxim Wireless offers a cost-effective support program called ServPak.
ServPak is a program of enhanced service support options that can be purchased as a bundle or individually, tailored to meet your
specific needs. Whether your requirement is round the clock technical support or advance replacement service, we are confident
that the level of support provided in every service in our portfolio will exceed your expectations.
Advanced Replacement of Hardware: Can you afford to be down in the event of a hardware failure? Our
guaranteed turnaround time for return to factory repair is 30 days or less. Those customers who purchase this service are
entitled to advance replacement of refurbished or new hardware guaranteed to be shipped out by the Next
Business Day. Hardware is shipped Monday - Friday, 8:00 AM - 2:00 PM (PST).
Extended Warranty: Extend the life of your networking investment by adding 1, 2, or 3 years to your products
standard warranty. This service coverage provides unlimited repair of your Proxim hardware for the life of the service
contract. The cost of an extended warranty is far less than the cost of a repair providing a sensible return on your
investment.
7x24x365 Technical Support: This service provides unlimited, direct access to Proxim’s world-class Tier 3 technical
support engineers 24 hours a day, 7 days a week, 365 days a year including Holidays. Customers who purchase this
service can rest assured that their call for technical assistance will be answered and a case opened immediately to
document the problem, troubleshoot, identify the solution and resolve the incident in a timely manner or refer to an
escalation manager for closure.
8x5 Technical Support: This service provides unlimited, direct access to Proxim’s world-class technical support 8
hours a day, 5 days a week from 8:00 AM - 5:00 PM (PST(US)). Technical Support is available at no charge for the first 90
days from the purchase date. Beyond this period, a ServPak support agreement will be required for technical
support. Self-help will be made available by accessing Proxim’s extensive eService knowledgebase.
Software Maintenance: It's important to maintain and enhance security and performance of wireless equipment
and Proxim makes this easy by providing a Software Maintenance program that enables customers to access new
features and functionality, rich software upgrades and updates. Customers will also have full access to Proxim's vast
knowledgebase of technical bulletins, white papers and troubleshooting documents.
Priority Queuing Phone Support: This service provides customers with a one hour response time for technical
phone support. There is no waiting in line for those urgent calls for technical support.
Tsunami® 8100 Series - Software Management Guide 245
Technical Services and Support
24x7Enhanced 8x5 Standard
ServPak Service (Bundled Serv.) (Bundled Serv.)
Extended
Warranty
Advance
Hardware
Replacement
24x7
Software Technical
Maintenance Support
Product Coverage Renewable
Duration Contracts
Renewable Renewable
Contracts Contracts
Renewable Contracts
Renewable
No Contracts
Software Coverage Renewable Renewable
Duration Contracts Contracts
No No
Renewable No
Contracts
Proxim TAC Support Yes Yes No No No Yes
Software Updates &
Upgrades
Yes Yes No No Yes No
Registered Access
to Proxim.com
Yes Yes Yes Yes Yes Yes
Registered Access
to Knowledge Tool
Yes Yes Yes Yes Yes Yes
Advance
Replacement
Yes No No Yes
No No
Depot Repair No Yes Yes No No No
To purchase ServPak support services, please contact your authorized Proxim distributor. To receive more information or for
questions on any of the available ServPak support options, call Proxim Support at 408-383-7700 or send an email to
servpak@proxim.com.
Tsunami® 8100 Series - Software Management Guide 246
FCC Statement
Federal Communication Commission Interference Statement
This equipment has been tested and found to comply with the limits for a Class A digital device,
pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection
against harmful interference in a residential installation. This equipment generates, uses and can
radiate radio frequency energy and, if not installed and used in accordance with the instructions, 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 of the following measures:
Reorient or relocate the receiving antenna.
Increase the separation between the equipment and receiver.
Connect the equipment into 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.
FCC Caution: Any changes or modifications not expressly approved by the party
responsible for compliance could void the user’s authority to operate this equipment.
This device complies with Part 15 of the FCC Rules. Operation is subject to the following two
conditions: (1) This device may not cause harmful interference, and (2) this device must accept any
interference received, including interference that may cause undesired operation.
This device and its antenna(s) must not be co-located or operation in conjunction with any other
antenna or transmitter.
FCC NOTICE: To comply with FCC part 15 rules in the United States, the system must be
professionally installed to ensure compliance with the Part 15 certification. It is the responsibility of the
operator and professional installer to ensure that only certified systems are deployed in the United
States. The use of the system in any other combination (such as co-located antennas transmitting the
same information) is expressly forbidden.
IMPORTANT NOTE:
FCC Radiation Exposure Statement:
This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment.
This equipment should be installed and operated with minimum distance 50cm between the radiator &
your body.

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