Title Page
CSX200 and CSX400
User’s Guide
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Notice
Cabletron Systems reserves the right to make changes in speciÞcations and other information
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Copyright 1998 by Cabletron Systems, Inc. All rights reserved.
Printed in the United States of America.
Order Number: 9032723 July 1998
Cabletron Systems, Inc.
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Contents
HSIM-W6 and HSIM-W84........................................................................................... 1-2
Using the CSX 200 and CSX400 UserÕs Guide.......................................................... 1-2
Common Window Fields...................................................................................... 1-4
Using Window Buttons......................................................................................... 1-6
Viewing Chassis Information...................................................................................... 2-2
Viewing I/F Summary Information.................................................................. 2-12
WAN Redundancy................................................................................................. 3-2
WAN Logical View ....................................................................................................... 3-5
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Contents
WAN Logical View Window Fields.....................................................................3-6
Changing WAN Logical Settings.........................................................................3-6
Bridging Basics ..............................................................................................................4-1
About Transparent Bridging.................................................................................4-2
About Source Route Bridging ..............................................................................4-2
About Source Route-Translational Bridges ........................................................4-4
Viewing and Managing Bridging Interfaces .............................................................4-6
The Bridge Status Window ..........................................................................................4-8
Enabling and Disabling Bridging .............................................................................4-14
Bridge Statistics ...........................................................................................................4-15
Performance Graphs............................................................................................4-15
The Interface Statistics Window.........................................................................4-21
Statistics Window Fields..............................................................................4-22
The CSMACD Statistics Window ......................................................................4-23
Receive Errors................................................................................................4-24
Transmission Errors......................................................................................4-25
Collision Errors .............................................................................................4-26
The PPP Link Statistics Window........................................................................4-26
Errors ..............................................................................................................4-27
Statistics..........................................................................................................4-28
The Dot5 Errors Statistics Window....................................................................4-29
Source Route Statistics.........................................................................................4-32
Received Frames ...........................................................................................4-33
Transmitted Frames......................................................................................4-34
Discards..........................................................................................................4-34
Bridge Spanning Tree..................................................................................................4-35
Bridge Level Fields ..............................................................................................4-36
Bridge Port Level Fields......................................................................................4-38
Changing Bridge Priority ............................................................................4-40
Changing Hello Time ...................................................................................4-41
Changing Max Age Time.............................................................................4-41
Changing Port Priority.................................................................................4-42
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Contents
Altering the Aging Time.............................................................................. 4-47
Changing the Receive Port.......................................................................... 4-48
Ethernet and Token Ring Special Filter Databases................................................. 4-49
Ethernet Special Filter Database Window........................................................ 4-50
Changing the Port Filtering Action................................................................... 4-55
Setting the Port Filtering Action................................................................. 4-55
Clearing the Port Filtering Action.............................................................. 4-56
The Port Source Addresses Window........................................................................ 4-64
SONET/SDH ConÞguration.............................................................................. 4-74
Token Ring Bridge Mode ........................................................................................... 4-83
Setting The Token Ring Bridge Mode............................................................... 4-84
Ethernet Port Physical Status Fields .......................................................... 4-85
vii
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Contents
Using the Interface ConÞguration Window............................................................4-89
DeÞning the Bridge Method...............................................................................4-90
Setting the Bridge Method..................................................................................4-91
DeÞning the Protocol Transmission ..................................................................4-91
ConÞguring SmartTrunking ......................................................................................4-96
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Chapter 1
Introduction
How to use this guide; related guides; software conventions; getting help; CSX200 and CSX400
firmware versions
Welcome to the Cabletron SystemsÕ SPECTRUM Element Manager for the
CSX200 and CSX400 UserÕs Guide. We have designed this guide to serve as a
simple reference for using SPECTRUM Element Manager for the CSX200 and
CSX400.
SPECTRUM Element Manager provides management support for both the
CyberSWITCH CSX200 and CyberSWITCH CSX400 stand-alone LAN-to-WAN
access devices. Both the CSX200 series and the CSX400 device support PPP and
Frame Relay WAN protocols, as well as multiprotocol bridging and IP/IPX
routing.
The CSX200 series (CSX 201, 202, and 203) is designed for smaller branch ofÞces
who need up to twelve Ethernet ports connected to a corporate WAN or ISP. Each
CSX200 device has twelve RJ-45 ports and one WAN interface. Before shipping,
the proper Wide Area Port Interface Module (WPIM) is installed in your device,
depending on the technology you need. WPIM connections currently supported
by SPEL include T1 and synchronous. In the future E1, DDS, DI (Drop-and-
Insert), and HDSL will also be supported by SPECTRUM Element Manager. All of
these WPIM options are discussed in Chapter 3, CSX200 and CSX400 WAN
ConÞguration. The CSX200 also supports Point to Point Protocol (PPP), leased
lines, and Frame Relay (RFC1490), providing up to four Permanent Virtual
Connections (PVCs) to corporate ofÞces or the Internet.
The CSX400 is ideal for corporate ofÞces or larger branch sites that require two
individual Ethernet LAN segments with single or dual WAN connectivity. The
two Ethernet ports can be conÞgured with any available EPIM media, while the
two WAN ports can be occupied by any swappable combination of Cabletron
WPIMs. Currently SPECTRUM Element Manager can only manage a T1 or
synchronous connection, but in the future WPIM options will also include DDS,
DI, E1, and HDSL connectivity. Each WPIM can act independently, allowing
1-1
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Introduction
simultaneous communication, or the pair can be conÞgured to provide redundant
channels if desired. Connectivity is available for Point to Point Protocol (PPP), as
well as Frame Relay and leased lines.
It is also important to note a Windows 95- and NT-based utility called QuickSET was
shipped with your CyberSwitch. This program is designed for point-and-click installation
and set-up of CSX200 and CSX400 devices. QuickSET can also be used to conÞgure
WPIM settings and routing-bridging protocols, including those WPIMs not currently
supported by SPECTRUM Element Manager.
NOTES
The CSX400 can support an ISDN connection with the WPIM-S/T. However, this
connection is designed for WAN redundancy only. A primary ISDN WAN connection is
not an option on the CSX400 at this time. See your CSX400 UserÕs Guide or your
QuickSET documentation for more information.
If you launch Chassis Manager for a CyberSwitch device and have QuickSET installed,
your Utilities menu will display a menu pick for launching QuickSET. See your
QuickSET documentation for more information.
HSIM-W6 and HSIM-W84
The HSIM-W6 and HSIM-W84 are Wide Area Networking HSIMs (High Speed
Interface Modules), which are functionally identical to the CSX200 and CSX400 in
that they provide LAN to WAN switching. They can be installed in SmartSwitch
2000, 6000, and 9000 modules to uplink to WANs. These HSIMs are intelligent
modules with their own IP addresses, and are managed separately through
SPECTRUM Element Manager. Therefore, users of the HSIM-W6 and HSIM-W84
should also use this manual.
The HSIM-W6 supports IP and IPX bridging or routing services, including IP RIP.
Multiple WAN connectivity is similar to that of the CSX400, with the use of two
conÞgurable WAN WPIMs. WPIM options are discussed in Chapter 2, Device
ConÞguration. Each WPIM on the HSIM-W6 can act independently, allowing
simultaneous communication, or the pair can be conÞgured to provide redundant
channels if desired.
The HSIM-W84 provides a Þxed conÞguration of four RJ45 ports for four active
T1 interfaces.
Using the CSX 200 and CSX400 User’s Guide
This guide describes a number of different applications, each of which provides a
portion of the overall management functionality for the CSX200 and CSX400
Cyberswitch devices. This guide contains information about software functions
which are accessed directly from the device icon; for information about
management functions which are accessed via the SPECTRUM Element Manager
1-2
HSIM-W6 and HSIM-W84
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Introduction
primary window menus, consult the SPECTRUM Element Manager UserÕs Guide
and the SPECTRUM Element Manager Tools Guide.
Following is a description of the applications covered in this guide. While we
provide as much background information as we can, we do assume that youÕre
familiar with Ethernet, Frame Relay, and WAN networks, and with general
network management concepts:
¥
Chapter 1, Introduction, provides a list of related documentation, describes
certain software conventions, and shows you how to contact the Cabletron
Systems Global Call Center.
¥
Chapter 2, CSX200 and CSX400 Chassis Views, describes the visual displays
of the CSX200 and CSX400 devices and how to use the mouse with the Chassis
Views. Also described are some basic functions available only from within the
Chassis Views (changing the port display, opening menus and windows,
enabling and disabling ports, checking device and port status, and so on).
¥
¥
Chapter 3, CSX200 and CSX400 WAN ConÞguration, describes the physical
conÞguration of the CSX200 and CSX400 devices, including WPIM options,
and explains the WAN Logical View window.
Chapter 4, Bridging, discusses the Bridge Status window, instructs you on
conÞguring bridge parameters, and discusses the Bridge Filtering and Special
Databases.
In places where information applies to both the CSX200 and CSX400 devices, this
manual may make reference to the ÒCSX200/400,Ó or simply the ÒCSX.Ó
NOTE
Related Manuals
The CSX200 and CSX400 UserÕs Guide is only part of a complete document set
designed to provide comprehensive information about the features available to
you through SPECTRUM Element Manager. Other guides which supply
important information related to managing the CSX200 and CSX400 include:
Cabletron SystemsÕ SPECTRUM Element Manager UserÕs Guide
Cabletron SystemsÕ SPECTRUM Element Manager Tools Guide
Cabletron SystemsÕ SPECTRUM Element Manager Remote Administration Tools
UserÕs Guide
Cabletron SystemsÕ SPECTRUM Element Manager Remote Monitoring (RMON)
UserÕs Guide
Cabletron SystemsÕ Network Troubleshooting Guide
Microsoft CorporationÕs Microsoft Windows UserÕs Guide
Related Manuals
1-3
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Introduction
For more information about the capabilities of the CSX200 and CSX400
management modules, consult the appropriate hardware documentation.
Software Conventions
SPECTRUM Element ManagerÕs device user interface contains a number of
elements which are common to most windows and which operate the same
regardless of which window they appear in. A brief description of some of the
most common elements appears below; note that the information provided here is
not repeated in the descriptions of speciÞc windows and/or functions.
Common Window Fields
Similar descriptive information is displayed in boxes at the top of most
device-speciÞc windows in SPECTRUM Element Manager, as illustrated in
Device
Location
Name
MAC
Address
IP Address
Figure 1-1. Sample Window Showing Group Boxes
Device Name
Displays the user-deÞned name of the device. The device name can be changed
via the System Group window; see the Generic SNMP UserÕs Guide for details.
1-4
Software Conventions
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Introduction
IP Address
Displays the deviceÕs IP (Internet Protocol) Address; this will be the IP address
used to deÞne the device icon. The IP address is assigned via Local Management
to the CSXÕs internal Host interface; it cannot be changed via SPECTRUM
Element Manager.
Location
Displays the user-deÞned location of the device. The location is entered through
the System Group window; see the Generic SNMP UserÕs Guide for details.
MAC Address
Displays the manufacturer-set MAC address associated with the IP address used
to deÞne the device icon; this will be the MAC address assigned to the CSXÕs
internal Host interface. Note that each physical interface in the CSX has its own
MAC address; these addresses are factory-set and cannot be altered.
Using the Mouse
This document assumes you are using a Windows-compatible mouse with two
buttons; if you are using a three button mouse, you should ignore the operation of
the middle button when following procedures in this document. Procedures
within the SPECTRUM Element Manager document set refer to these buttons as
follows:
Left Mouse Button
Right Mouse Button
Figure 1-2. Mouse Buttons
For many mouse operations, this document assumes that the left (primary) mouse
button is to be used, and references to activating a menu or button will not
include instructions about which mouse button to use.
However, in instances in which right (secondary) mouse button functionality is
available, instructions will explicitly refer to right mouse button usage. Also, in
situations where you may be switching between mouse buttons in the same area
or window, instructions may also explicitly refer to both left and right mouse
buttons.
Software Conventions
1-5
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Introduction
Instructions to perform a mouse operation include the following terms:
¥
Pointing means to position the mouse cursor over an area without pressing
either mouse button.
¥
Clicking means to position the mouse pointer over the indicated target, then
press and release the appropriate mouse button. This is most commonly used
to select or activate objects, such as menus or buttons.
¥
Double-clicking means to position the mouse pointer over the indicated
target, then press and release the mouse button two times in rapid succession.
This is commonly used to activate an objectÕs default operation, such as
opening a window from an icon. Note that there is a distinction made between
Òclick twiceÓ and Òdouble-click,Ó since Òclick twiceÓ implies a slower motion.
¥
¥
Pressing means to position the mouse pointer over the indicated target, then
press and hold the mouse button until the described action is completed. It is
often a pre-cursor to Drag operations.
Dragging means to move the mouse pointer across the screen while holding
the mouse button down. It is often used for drag-and-drop operations to copy
information from one window of the screen into another, and to highlight
editable text.
Using Window Buttons
The
button that appears at the bottom of most windows allows you to
exit a window and terminate any unsaved changes you have made. You may also
have to use this button to close a window after you have made any necessary
changes and set them by clicking on an
,
, or
button.
An , or button appears in windows that have
,
conÞgurable values; it allows you to conÞrm and SET changes you have made to
those values. In some windows, you may have to use this button to conÞrm each
individual set; in other windows, you can set several values at once and conÞrm
the sets with one click on the button.
The
button brings up a Help text box with information speciÞc to the
current window. For more information concerning Help buttons, see Getting
The command buttons, for example
, call up a menu listing the windows,
screens, or commands available for that topic.
Any menu topic followed by ... (three dots) Ñ for example Statistics... Ñ calls up
a window or screen associated with that topic.
1-6
Software Conventions
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Introduction
Getting Help
This section describes two different methods of getting help for questions or
concerns you may have while using SPECTRUM Element Manager.
Using On-line Help
You can use the
buttons to obtain information speciÞc to a particular
window. When you click on a Help button, a window will appear which contains
context-sensitive on-screen documentation that will assist you in the use of the
windows and their associated command and menu options. Note that if a Help
button is grayed out, on-line help has not yet been implemented for the associated
window.
From the Help menu accessed from the Chassis View window menu bar, you can
access on-line Help speciÞc to the Chassis View window, as well as bring up the
Chassis Manager window for reference. Refer to Chapter 2 for information on the
Chassis View and Chassis Manager windows.
All of the online help windows use the standard Microsoft Windows help facility. If you
NOTE
are unfamiliar with this feature of Windows, you can select Help from the
or Help Ñ>How to Use Help from the primary SPECTRUM Element Manager
window, or consult your Microsoft Windows product UserÕs Guide.
menu,
Getting Help from the Cabletron Systems Global Call Center
If you need technical support related to SPECTRUM Element Manager, or if you
have any questions, comments, or suggestions related to this manual or any of
our products, please feel free to contact the Cabletron Systems Global Call Center
via one of the following methods:
By phone:
(603) 332-9400
24 hours a day, 365 days a year
By mail:
Cabletron Systems, Inc.
PO Box 5005
Rochester, NH 03866-5005
By Internet mail:
FTP:
ftp.ctron.com (134.141.197.25)
Login
anonymous
Password
your email address
By BBS:
(603) 335-3358
Modem Setting
8N1: 8 data bits, 1 stop bit, No parity
Getting Help
1-7
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Introduction
For additional information about Cabletron Systems products, visit our
World Wide Web site: http://www.cabletron.com/. For technical support,
select Service and Support.
CSX200 and CSX400 Firmware
SPECTRUM Element Manager support for the CSX200 has been tested against
Þrmware version 1.02.06. The CSX400 has been tested against Þrmware version
2.00.11. If you have an earlier version of Þrmware and experience problems,
contact Cabletron Systems Global Call Center for upgrade information.
As a general rule, Þrmware versions for new products are liable to change rapidly; contact
Cabletron Systems Global Call Center for upgrade information for the latest customer
release of Þrmware.
NOTE
1-8
CSX200 and CSX400 Firmware
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Chapter 2
CSX200 and 400 Chassis View
Information displayed in the Chassis View window; the Chassis Manager window; Hub management
functions
The CSX200/400 Chassis View window is the main screen that immediately
informs you of the current condition of individual ports on your switch via a
graphical display. The Chassis View window also serves as a single point of access
to all other CSX windows and screens, which are discussed throughout this
manual.
It is important to note a Windows 95- and NT-based utility called QuickSET was shipped
NOTE
with your device. This program is designed for point-and-click installation and set-up of
CSX200/400 devices. If you launch Chassis Manager for a CyberSWITCH device and
have QuickSET installed, your Utilities menu will display a menu pick for launching
QuickSET. See your QuickSET documentation for more information.
To access the CSX Chassis View window, use one of the following options:
1. In any map, list, or tree view, double-click on the CSX200 or CSX400 you wish
to manage.
or
1. In any map, list, or tree view, click the left mouse button once to select the
CSX you wish to manage.
2. Select Manage—>Node from the primary window menu bar, or select the
Manage Node
toolbar button.
or
1. In any map, list, or tree view, click the right mouse button once to select the
CSX200/400 you wish to manage.
2. On the resulting menu, click to select Manage.
2-1
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CSX200 and 400 Chassis View
Viewing Chassis Information
representation of the device, including a color-coded port display which
immediately informs you of the current conÞguration and status of the switch
and its ports.
Figure 2-1. CSX200 and CSX400 Chassis View Windows
At the time of this release, the Chassis View windows will only display the bridge ports on
a CSX device.
NOTES
See your QuickSET documentation for information on managing your Ethernet ports.
Bridging capabilities are discussed in Chapter 4 of this manual.
By clicking in designated areas of the chassis graphical display (as detailed later
in this chapter), or by using the menu bar at the top of the Chassis View window,
you can access all of the menus that lead to more detailed device- and port-level
windows.
When you move the mouse cursor over a management Òhot spotÓ the cursor icon will
change into a ÒhandÓ
management option.
to indicate that clicking in the current location will bring up a
TIP
2-2
Viewing Chassis Information
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CSX200 and 400 Chassis View
Front Panel Information
The areas surrounding the main chassis area provide the following device
information:
IP
The Internet Protocol address assigned to the CSX appears in the title bar of the
Chassis View window. IP addresses are assigned via Local Management.
Connection Status
This color-coded area indicates the current state of communication between
SPECTRUM Element Manager and the CSX200/400.
¥
Green indicates the CSX200/400 is responding to device polls (valid
connection).
¥
Magenta indicates that the CSX200/400 is in a temporary stand-by mode
while it responds to a physical change in the switch; note that board and port
menus are inactive during this stand-by state.
¥
¥
Blue indicates an unknown contact status Ñ polling has not yet been
established with the CSX200/400.
Red indicates the CSX200/400 is not responding to device polls (device is off
line, or device polling has failed across the network for some other reason).
UpTime
The amount of time, in a X day(s) hh:mm:ss format, that the CSX200/400 has been
running since the last start-up.
Port Status
If management for your device supports a variable port display (detailed in The
CSX200/400 Port Status Displays later in this chapter), this Þeld will show the
display currently in effect. If only a single port display is available Ñ or if the
default view is in effect Ñ this Þeld will state Default.
MAC
Displays the physical layer address assigned to the interface associated with the
IP Address used to deÞne the device icon when it was added to SPECTRUM
Element Manager. MAC addresses are hard-coded in the device, and are not
conÞgurable.
Boot Prom
The revision of BOOT PROM installed in the CSX200/400.
Firmware
The revision of device Þrmware stored in the CSX200/400Õs FLASH PROMs.
Viewing Chassis Information
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CSX200 and 400 Chassis View
Time
The current time, in a 24-hour hh:mm:ss format, set in the CSX200/400Õs internal
clock.
Date
The current date, in an mm/dd/yy format, set in the CSX200/400Õs internal clock.
In accordance with Year 2000 compliance requirements, SPECTRUM Element Manager
now displays and allows you to set all dates with four-digit year values.
NOTE
Menu Structure
By clicking on various areas of the CSX200/400 Chassis View display, you can
access menus with device- and port-level options, as well as utility applications
which apply to the device. The following illustration displays the menu structure
and indicates how to use the mouse to access the various menus:
If QuickSET is installed
on your workstation, it
will also appear in the
Utilities menu.
Clicking the on the
module index will
bring up the Bridge
menu, described in
Chapter 4.
Figure 2-2. CSX200/400 Chassis View Menu Structure
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CSX200 and 400 Chassis View
The Device Menu
From the Device Menu at the Chassis View window menu bar, you can access the
following selections:
¥
¥
¥
¥
Device Type..., which displays a window containing a description of the
device being modeled: CSX200/400 - CyberSWITCH.
Edit Device Time/Edit Device Date..., which allows you set the deviceÕs
internal clock.
System Group..., which allows you to manage the CSX200/400 via SNMP MIB
II. Refer to the Generic SNMP Guide for further information.
I/F Summary, which allows you to view statistics (displayed both graphically
and numerically) for the trafÞc processed by each network interface on
more information.
¥
¥
Bridge Status..., which opens a window that provides an overview of bridging
information for each interface, and allows you to access all other bridge-
related options. Refer to Chapter 4 of this manual for more information.
Find Source Address...,which opens a window that allows you to search the
802.1d Filtering Database of the CSX200/400 to determine which bridging
interface a speciÞed source MAC address is communicating through. If the
MAC address is detected as communicating through the switch, the port
¥
¥
WAN Status..., which accesses the WAN Logical View window of your device.
See Chapter 3 for more information.
Exit, which closes the CSX200/400 Chassis View window.
The Port Status Menu
The Port Status Menu allows you to select the status information that will be
displayed in the port text boxes in the Chassis View window:
¥
Status allows you to select one of four status type displays: Bridge, Bridge
Mapping, Admin, or Operator.
¥
Load will display the portion of network load processed per polling interval
by each interface as a percentage of the theoretical maximum load (10 or 100
Mbits/sec).
¥
¥
Errors allows you to display the number of errors detected per polling interval
by each interface as a percentage of the total number of valid packets
processed by the interface.
I/F Mapping will display the interface (if) index associated with each port on
your CSX200/400 switch.
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CSX200 and 400 Chassis View
¥
I/F Speed will display the speed (10 or 100 Mbits/sec) of the network segment
attached to each port. The speed of the network management port will be
displayed in Kbits/sec.
¥
I/F Type will display the interface type of each port in the CSX200/400 Ñ i.e.,
Eth (ethernet-csmacd) for the bridging interfaces, and PPP for the network
management port.
CSX200/400 Port Status Displays, later in this chapter.
The Utilities Menu
From the Utilities menu you can select:
¥
MIB Tools, a utility provided by SPECTRUM Element Manager for use with
the CSX200/400. The MIB Tools utility provides direct access to the
CSX200/400Õs MIB information. This selection is also available from the Tools
menu at the top of SPECTRUM Element ManagerÕs main window. Refer to
your SPECTRUM Element Manager Tools Guide for more information on
the MIB Tools utility.
¥
Router ConÞg, for launching the Basic Router application. Basic routing is
described in its own UserÕs Guide, and can also be launched from the Tools
menu.
¥
RMON, for launching the Remote Network Monitoring application. RMON is
described in its own UserÕs Guide. Like MIB Tools and Basic Router, RMON
can also be launched from the Tools menu at the top of SPECTRUM Element
ManagerÕs main window. RMON is supported by the CSX400 only.
You will be able to launch the QuickSET application from the Utilities menu, provided it
is installed on your machine. See your QuickSET documentation for more information.
NOTE
The Help Menu
The Help Menu has three selections:
¥
¥
¥
MIBs Supported, which brings up the Chassis Manager window, described
later in this chapter.
Chassis Manager Help, which brings up a help window with information
speciÞcally related to using the Chassis Manager and Chassis View windows.
About Chassis Manager..., which brings up a version window for the Chassis
Manager application in use.
The Port Menus
The menu for bridging ports offers the following selections:
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CSX200 and 400 Chassis View
¥
Connection Type... opens a window displaying a description of the
connection type of the selected bridge interface. This description is comprised
of text based on the ctIfConnectionType MIB.
¥
¥
Description..., which brings up a window describing the selected port; see
Viewing the Port Description, later in this chapter.
Performance Graph..., which allows you to view the trafÞc going through a
selected bridge. This information is displayed both numerically and
graphically, as described in Chapter 4, Bridging.
¥
¥
Source Addressing..., which displays a list of MAC Addresses that
communicate through the selected bridge port.
I/F Statistics..., which allows you to view color-coded statistical information
chapter.
¥
Alarm ConÞguration..., which opens the Basic Alarm ConÞguration window.
See Basic Alarm ConÞguration in Chapter 4, RMON Alarms and Events, in
your RMON UserÕs Guide for more information. RMON is only supported by
the CSX400. A CSX200 device will allow you to open this window, but alarm
conÞguration will not be possible.
¥
¥
Statistics... see I/F Statistics, above.
Enable/Disable, which administratively turns the selected bridging port on or
The CSX200/400 Port Status Displays
When you open the Chassis View window, each port on the CSX200/400 will
display its Admin status (deÞned below). To change this status display, select one
of the options on the Port Status menu, as described in the following sections.
Selecting a Port Status View
To change the status of your ports:
1. Click on Port Status on the menu bar at the top of the Chassis View window;
a menu will appear.
2. Drag down (and to the right, if necessary) to select the status information you
want to display. The port text boxes will display the appropriate status
information.
Port status view options are:
Status
You can view four port Status categories, as follows:
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CSX200 and 400 Chassis View
¥
¥
¥
¥
Bridge Ñ FWD, DIS, LRN, LIS, BLK, BRK, or UNK
Bridge Mapping Ñ bridge interface index numbers
Admin Ñ ON or OFF
Operator Ñ ON or OFF
If you have selected the Bridge status mode, a port is considered:
¥
FWD (Forwarding) if the port is on-line and forwarding packets across the
CSX200/400 from one network segment to another.
¥
DIS (Disabled) if bridging at the port has been disabled by management; no
trafÞc can be received or forwarded on this port, including conÞguration
information for the bridged topology.
¥
¥
¥
LRN (Learning) if the Forwarding database is being created, or the Spanning
Tree Algorithm is being executed because of a network topology change. The
port is monitoring network trafÞc, and learning network addresses.
LIS (Listening) if the port is not adding information to the Þltering database. It
is monitoring Bridge Protocol Data Unit (BPDU) trafÞc while preparing to
move to the forwarding state.
BLK (Blocking) if the port is on-line, but Þltering trafÞc from going across the
CSX200/400 from one network segment to another. Bridge topology
information will be forwarded by the port.
¥
¥
BRK (Broken) if the physical interface has malfunctioned.
UNK (Unknown) if the interfaceÕs status cannot be determined.
If you have selected Bridge Mapping, the port status boxes will display the bridge
interface index numbers assigned to each interface (which may or may not match
the ifIndex values displayed via the I/F Mapping option described below).
If you have selected the Admin status mode, a port is considered:
¥
¥
ON if the port is enabled by management and has a valid link.
OFF if it has not been enabled or if it has been disabled through management
action.
If you have selected the Operator status mode, a port is considered:
¥
¥
ON if the port is currently forwarding packets.
OFF if the port is not currently forwarding packets.
Load
If you choose Load, the interface text boxes will display the percentage of
network load processed by each port during the last polling interval. This
percentage reßects the network load generated per polling interval by devices
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CSX200 and 400 Chassis View
connected to the port compared to the theoretical maximum load (10 or 100
Mbits/sec) of an Ethernet network.
Errors
If you choose the Errors mode, the interface boxes will display the percentage of
the total number of valid packets processed by each port during the last polling
interval that were error packets. This percentage reßects the number of errors
generated during the last polling interval by devices connected to that port
compared to the total number of valid packets processed by the port.
In SPECTRUM Element Manager, the polling interval is set via the Tools Ñ>
Options...Ñ>Polling option from the main windowÕs menu bar. Refer to the Installing
and Using SPECTRUM Element Manager guide for full information on setting device
polling intervals.
NOTE
I/F Mapping
If you choose the I/F Mapping mode, the interface boxes will display the interface
number (IfIndex) associated with each port on the CSX200/400.
I/F Speed
If you choose the I/F Speed mode, the port text boxes will display the speed of the
network segment connected to each port. The speed of the network management
port will be displayed in Kbits/sec.
I/F Type
If you choose the I/F Type mode, the interface boxes will display the interface
type of each port on the CSX200/400 (e.g., Eth, PPP, other).
Port Status Color Codes
The Port Status display options Ñ Bridge, Admin, and Operator Ñ incorporate
color coding schemes. For the Admin and Operator Status display options,
green = ON, red = OFF, and blue = N/A (not available). For the Bridge Status
display option, green = forwarding, blue = disabled, magenta = learning and
listening, orange = blocking, red = broken, and gray = unknown.
For all other Port Status selections Ñ Load, Errors, I/F Port Mapping, Speed, and
Type Ñ color codes will continue to reßect the most recently selected mode which
incorporates its own color coding scheme.
The Chassis Manager Window
Like most networking devices, the CSX200/400 draws its functionality from a
collection of proprietary MIBs and IETF RFCs. In addition, the CSX200/400
organizes its MIB data into a series of Òcomponents.Ó A MIB component is a
logical grouping of MIB data, and each group controls a deÞned set of objects. For
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CSX200 and 400 Chassis View
example, CSX200/400 bridging information is organized into its own component.
Note, too, that there is no one-to-one correspondence between MIBs and MIB
components. A single MIB component might contain objects from several
different proprietary MIBs and RFCs.
the MIBs and the MIB components Ñ and, therefore, the functionality Ñ
supported by the currently monitored device.
To view the Chassis Manager window:
1. Click on Help on the menu bar at the top of the Chassis View window.
2. Drag down to MIBs Supported, and release.
The MIBs which provide the
CSX200/400’s functionality —
both proprietary MIBs and IETF
RFCs — are listed here.
MIB Components are listed
here. Remember, there’s no
one-to-one correspondence
between MIBs and MIB
Components.
Figure 2-3. Chassis Manager Window
Viewing Hardware Types
In addition to the graphical displays described above, menu options available at
several levels provide speciÞc information about the physical characteristics of
the CSX200/400 and its ports.
Device Type
Choosing the Device Type... option on the Device menu brings up a window that
describes the management device being modeled:
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CSX200 and 400 Chassis View
Figure 2-4. Device Type Windows
Viewing the Port Description
Choosing the Description... option on the individual port interface menus brings
up a window that describes the interface you have selected. This description is
based on a value returned by the ifDescr MIB. Two possibilities for a CSX
Figure 2-5. Interface Description Windows
Managing the Device
The Chassis View provides you with the basic tools available to conÞgure your
device and keep it operating properly.
Until future releases of SPECTRUM Element Manager provide more comprehensive
support of the CSX200 and CSX400 CyberSWITCHes, Cabletron recommends that
anything beyond the basic conÞguration options described in this section be handled with
the QuickSET utility. See your QuickSET documentation for more information.
NOTE
Managing the Device
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CSX200 and 400 Chassis View
Management for the CSX200/400 through SPELÕs Chassis View is comprised of
source address location, viewing interface statistics, and enabling and disabling
ports.
Using the Find Source Address Feature
You can select the Find Source Address option to discover which bridging
interface a speciÞed source MAC address is communicating through. When you
select the Find Source Address option, a search is made of the 802.1d Bridge
Filtering Database to discover the bridge interface associated with the address
that you specify. If the search is successful, the corresponding interface will ßash
in the Chassis View window. For more information on the Filtering Database and
bridging in general, refer to the bridging chapter in your SPECTRUM Element
Manager Tools Guide.
Use the Find Source Address feature as follows:
1. Click to display the Device pull-down menu.
2. Drag to Find Source Address.... The following window will appear.
Figure 2-6. Find Source Address Window
3. In the text field in the middle of the window, enter a valid MAC address in Hex
format and then click OK.
If the address is found in the 802.1d Bridge Filtering Database, the port through
which the address is communicating will ßash in the front panel Chassis View
display.
If the address is not found in the Filtering Database, a separate window will
appear with a ÒCanÕt Find Source AddressÓ message.
Viewing I/F Summary Information
The I/F Summary menu option available from the Device menu lets you view
statistics for the trafÞc processed by each network interface on your device. The
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CSX200 and 400 Chassis View
window also provides access to a detailed statistics window that breaks down
Transmit and Receive trafÞc for each interface.
To access the I/F Summary window:
1. From the Module View, click on the Device option from the menu bar.
2. Click again to select I/F Summary, and release. The I/F Summary window,
Figure 2-7, will appear.
Figure 2-7. I/F Summary Window
When you open the I/F Summary window, you will see Þelds which describe
each interface on your device, as well as a bar graph and statistics which display
each interfaceÕs performance.
The following descriptive information is provided for each interface:
UpTime
The UpTime Þeld lists the amount of time, in a days, hh:mm:ss format, that the
device has been running since the last start-up.
Index
The index value assigned to each interface on the device.
Type
The type of the interface, distinguished by the physical/link protocol(s) running
immediately below the network layer.
Description
A text description of the interface.
Managing the Device
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CSX200 and 400 Chassis View
Physical Status
Displays the current physical status Ñ or operational state Ñ of the interface:
Online or Ofßine.
Logical Status
Displays the current logical status Ñ or administrative state Ñ of the interface:
Up or Down.
Interface Performance Statistics/Bar Graphs
The statistical values (and, where available, the accompanying bar graphs) in the
far-right columns of the I/F Summary window provide a quick summary of
interface performance. You can select the statistical value you want to display and
the units in which you want those values displayed by using the two menu Þelds
directly above the interface display area, as follows:
1. In the right-most menu field, click on the down arrow and select the unit in
which you wish to display the selected statistic: Load, Raw Counts, or Rate.
Bar graphs are only available when Load is the selected base unit; if you select Raw
Counts or Rate, the Bar Graph column will be removed from the interface display.
NOTE
2. Once you have selected the base unit, click on the down arrow in the left-most
field to specify the statistic you’d like to display. Note that the options available
from this menu will vary depending on the base unit you have selected.
After you select a new display mode, the statistics (and graphs, where applicable)
will refresh to reßect the current choice, as described below.
Raw Counts
The total count of network trafÞc received or transmitted on the indicated
interface since device counters were last reset. Raw counts are provided for the
following parameters:
In Octets
Octets received on the interface, including framing
characters.
In Packets
In Discards
Packets (both unicast and non-unicast) received by the
device interface and delivered to a higher-layer protocol.
Packets received by the device interface that were
discarded even though no errors prevented them from
being delivered to a higher layer protocol (e.g., to free up
buffer space in the device).
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In Errors
Packets received by the device interface that contained
errors that prevented them from being delivered to a
higher-layer protocol.
In Unknown
Packets received by the device interface that were
discarded because of an unknown or unsupported
protocol.
Out Octets
Octets transmitted by the interface, including framing
characters.
Out Packets
Packets transmitted, at the request of a higher level
protocol, by the device interface to a subnetwork address
(both unicast and non-unicast).
Out Discards
Outbound packets that were discarded by the device
interface even though no errors were detected that
would prevent them from being transmitted. A possible
reason for discard would be to free up buffer space in the
device.
Out Errors
Outbound packets that could not be transmitted by the
device interface because they contained errors.
Load
The number of bytes processed by the indicated interface during the last poll
interval in comparison to the theoretical maximum load for that interface type
(10 Mbps for standard Ethernet; 100 Mbps for Fast Ethernet). Load is further
deÞned by the following parameters:
In Octets
The number of bytes received by this interface, expressed
as a percentage of the theoretical maximum load.
Out Octets
The number of bytes transmitted by this interface,
expressed as a percentage of the theoretical maximum
load.
When you select this option, a Bar Graph Þeld will be added to the interface
display area; this Þeld is only available when Load is the selected base unit.
Rate
The count for the selected statistic during the last poll interval. The available
parameters are the same as those provided for Raw Counts. Refer to the Raw
Counts section, above, for a complete description of each parameter.
Managing the Device
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CSX200 and 400 Chassis View
Viewing Interface Detail
statistical information Ñ including counts for both transmit and receive packets,
and error and buffering information Ñ for each individual port interface. Color-
coded pie charts also let you graphically view statistics for both received and
transmitted Unicast, Multicast, Discarded, and Error packets.
To open the Interface Statistics window:
1. In the I/F Summary window, click to select the interface for which you’d like to
view more detailed statistics.
Figure 2-8. Detail Interface Statistics
You can also access this information via the I/F Statistics option available on the
individual port menus.
TIP
Three informational Þelds appear in the upper portion of the window:
Description
Displays the interface description for the currently selected interface: Ethernet,
Host, SMB 1, SMB 10, or INB.
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Address
Displays the MAC (physical) address of the selected interface.
Type
Displays the interface type of the selected port: ethernet-csmacd, sdlc, or other.
The lower portion of the window provides the following transmit and receive
statistics (the Þrst four statistics are also graphically displayed in the pie charts).
Unicast
Displays the number of packets transmitted to or received from this interface that
had a single, unique destination address. These statistics are displayed in the pie
chart, color-coded green.
Non-Unicast
Displays the number of packets transmitted to or received from this interface that
had a destination address that is recognized by more than one device on the
network segment. The multicast Þeld includes a count of broadcast packets Ñ
those that are recognized by all devices on a segment. These statistics are
displayed in the pie chart, color-coded dark blue.
Discarded
Displays the number of packets which were discarded even though they
contained no errors that would prevent transmission. Good packets are typically
discarded to free up buffer space when the network becomes very busy; if this is
occurring routinely, it usually means that network trafÞc is overwhelming the
device. To solve this problem, you may need to re-conÞgure your bridging
parameters, or perhaps re-conÞgure your network to add additional bridges or
switches. Consult the Cabletron Systems Network Troubleshooting Guide for
more information.
These statistics are displayed in the pie chart, color-coded magenta.
Error
Displays the number of packets received or transmitted that contained errors.
These statistics are displayed in the pie chart, color-coded red.
Unknown Protocol (Received only)
Displays the number of packets received which were discarded because they were
created under an unknown or unsupported protocol.
Packets Received (Received only)
Displays the number of packets received by the selected interface.
Transmit Queue Size (Transmit only)
Displays the number of packets currently queued for transmission from this
interface. The amount of device memory devoted to buffer space, and the trafÞc
level on the target network, determine how large the output packet queue can
grow before the device will begin to discard packets.
Managing the Device
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CSX200 and 400 Chassis View
Packets Transmitted (Transmit only)
Displays the number of packets transmitted by this interface.
Making Sense of Detail Statistics
The statistics available in this window can give you an idea of how an interface is
performing; by using the statistics in a few simple calculations, itÕs also possible to
get a sense of an interfaceÕs activity level:
To calculate the percentage of input errors:
Received Errors /Packets Received
To calculate the percentage of output errors:
Transmitted Errors /Packets Transmitted
To calculate the total number of inbound and outbound discards:
Received Discards + Transmitted Discards
To calculate the percentage of inbound packets that were discarded:
Received Discards /Packets Received
To calculate the percentage of outbound packets that were discarded:
Transmit Discards /Packets Transmitted
Unlike the Interface Detail window, which this window replaces, the Interface Statistics
window does not offer Disable or Test options. These options are available in the
Interface Group window, which can be accessed via the System Group window (select
System Group... from the Device menu). Refer to your Generic SNMP UserÕs Guide
for further information on the System Group and Interface Group windows.
NOTE
Enabling and Disabling Ports
From the Port menus on the CSX200/400 Chassis View window, you can
administratively enable and disable the ports.
When you administratively disable a bridge port, you disconnect that portÕs
network from the bridge entirely. The port does not forward any packets, nor
does it participate in Spanning Tree operations. Nodes connected to the network
can still communicate with each other, but they canÕt communicate with the
bridge or with other networks connected to the bridge. When you enable a port,
the port moves from the Disabled state, through the Learning and Listening
states, to the Forwarding state; bridge port state color codes will change
accordingly.
To enable or disable a bridge port:
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CSX200 and 400 Chassis View
1. Click on the desired Port index. The Port menu will appear.
2. Click on Enable to enable the port, or Disable to disable the port.Your port
will now be enabled or disabled as desired.
For more information about bridging functions and how to determine the current state of
each bridge port, see Chapter 4 of this manual.
NOTE
Managing the Device
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Chapter 3
CSX200 and CSX400
WAN Configuration
Physical CSX device information; CSX WPIMs; the WAN Logical View window
The CSX200 devices have one WAN interface, a Cabletron Wide Area Port
Interface Module (WPIM) installed at the factory. The CSX400 has two swappable
WAN interfaces, which can currently consist of any combination of CabletronÕs
T1/E1/DI, HDSL, DDS, or synchronous WPIMs.
ItÕs important to note that a Windows 95- and NT-based utility called QuickSET was
shipped with your CyberSWITCH. This program is designed for point-and-click
installation and set-up of CSX200/400 devices. Currently, QuickSET should be used to
conÞgure all WPIM settings and routing/bridging protocols, including those WPIMs not
currently supported by Spectrum Element Manager. See your QuickSET documentation
for more information. Future releases of SPECTRUM Element Manager will support the
CSX200/400 more comprehensively.
NOTE
The CSX200 series (201, 202, and 203) and the CSX 400 come with a variety of
Ethernet LAN and WAN connectivity options. The WPIMs which provide the
WAN connection(s) are discussed in this chapter, along with EPIM possibilities
for the CSX400.
window through SPECTRUM Element ManagerÕs Chassis View. There, you can
view your WAN interface settings.
About the CSX200 Series
There are three devices in the CSX200 family: the CSX201, CSX202, and CSX203.
Each has twelve RJ-45 Ethernet ports for LAN connection via 10BaseT twisted
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CSX200 and CSX400 WAN Configuration
pair cable, along with a WPIM slot to provide one WAN interface. The model
number depends on the type of Wide Area Networking interface installed:
CSX201
CSX202
Provides a T1/E1 Wide Area uplink
Provides a Serial interface (V.35, X.21, RS449, RS232. or
RS530)
CSX203
Provides a DDS WAN uplink
At the time of this release, SPECTRUM Element Manager does not support a DDS
interface on a CSX device. This applies to both the CSX203 and a WPIM-DDS installed
on a CSX400. In addition, the WPIM-DI, WPIM-E1, and WPIM-HDSL are also not
currently supported by SPECTRUM Element Manager but will be in the future. The
Windows 95- and NT-based utility QuickSET, which was shipped with your
CSX200/400 device, can be used to conÞgure these WPIMs. See your QuickSET
documentation for more information.
NOTE
available for your CSX200.
About the CSX400
The CSX400 supports multiple LAN options through two Ethernet ports. These
ports can be conÞgured with any combination of the following Cabletron EPIM
connections:
EPIM-A
EPIM-C
EPIM-T
EPIM-F1
EPIM-F2
EPIM-F3
Female AUI interface with DB-15 connector
10Base-2 coaxial port, BNC connectors
10Base-T twisted pair port with RJ45 connector
10BaseFL multi-mode Þber port with SMA connectors
10Base-FL multi-mode Þber port with ST connectors
802.3 single-mode Þber port with ST connectors
For more information on these EPIMs, consult your hardware documentation.
The CSX400 also consists of two WAN interfaces, which can currently be
conÞgured with any combination of Cabletron WPIMs, which are described in
WAN Redundancy
For a redundant wide-area connection, one of the WAN interfaces on your
CSX400 can be conÞgured as a primary link, with the other interface designated
3-2
About the CSX400
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CSX200 and CSX400 WAN Configuration
as the backup. If the primary link should fail for some reason, the other WAN
interface will take over as the wide area link until the primary is restored.
When a WPIM-S/T is installed as the backup interface, that connection will
activate and provide an ISDN connection to the wide area network, if the primary
WAN link fails. The ISDN WPIM can also provide backup for single or multiple
Data Link Connection Interfaces (DLCIs). If a leased line loses a DLCI or a remote
ofÞce, for example, the WPIM-S/T will restore a 64K connection for that site while
the rest of the connections remain on the leased line. For more information on
WAN redundancy and the WPIM-S/T, consult your QuickSET documentation or
your hardware documentation.
The WPIM-S/T is designed for WAN ISDN redundancy only and is not intended to be
used for a primary WAN connection at this time.
NOTE
CSX WPIMs
The following Cabletron WPIMs provide WAN connectivity for the CSX400,
HSIM-W84, and the CSX200 series. Currently Cabletron recommends that all
WPIM conÞguration be done through the QuickSET application that was shipped
with your device. Consult your QuickSET documentation for more details.
If there is a speciÞc device from the CSX200 series that supports the WPIM, it is
noted below. Otherwise, the WPIM can be special-ordered and installed in a
general CSX200 (contact the Cabletron Systems Global Call Center for more
information).
WPIM-DDS
WPIM-DI
DDS is Digital Data Services, a digital network that
supports data rates of 56Kbps or 64Kbps. The DDS
service provides users with dedicated, two-way
simultaneous transmission capabilities operating at
transfer rates up to 64 Kbps. This WPIM comes with a
built-in CSX/DSU. (CSX203)
The DI (Drop-and-Insert) WPIM provides a T1 interface
through a front-panel RJ45 port and includes a built-in
CSU/DSU for direct connection to a T1 line. The WPIM-
DI provides Full T1 or Fractional T1 using 56 or 64 Kbps
Time Slots. It also provides a second Drop-and-Insert
interface that allows more than one device, such as a
PBX, to share a single T1 connection. (CSX201)
WPIM-E1
This WPIM provides an E1 interface through a front-
panel RJ-45 port and includes a built-in CSU/DSU for
direct connection to an E1 line. This WPIM provides Full
E1 or Fractional E1 using 56 or 64 Kbps Time Slots with a
total throughput of up to 2 Mbps. Time Division
CSX WPIMs
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CSX200 and CSX400 WAN Configuration
Multiplexing (TDM) allows for the channelization of up
to 31 links of a single physical interface. (CSX201)
WPIM-HDSL
WPIM-S/T
This WPIM is designed for campus environments and
provides a connection for sending LAN trafÞc over
existing telephone lines at rates up to 1.544Mbps. It can
communicate reliably up to a distance of 12,000 feet over
Unshielded Twisted Pair (UTP) cabling.
For the CSX400 only. This WPIM provides an ISDN 128
Kbps Basic Rate Interface (BRI) and is designed for an
ISDN back-up link for a frame relay or leased line. In the
United States and Canada, Network Terminator
equipment (NT1) is required to provide an interface
between the WPIM-S/T and the ISDN line.
WPIM-SY
Provides a synchronous serial connection of up to 2.048
Mbps to external communications equipment (an
external CSU/DSU is required). For the CSX202. The
following electrical interfaces are supported. An external
CSU/DSU is required (consult your hardware
documentation for cable pinout information):
EIA-RS449
V.35
EIA-RS232D
X.21
EIA-RS530
EIA-530A
RS530 ALT A
RS530A ALT A
WPIM-T1
Provides a T1 interface through a front-panel RJ45 port
and includes a built-in CSU/DSU for direct connection to
a T1 line. The WPIM-T1 provides both Full T1 or
Fractional T1 using 56 or 64 Kbps Time Slots, with a total
throughput of up to 1.544 Mbps. Time Division
Multiplexing (TDM) allows for channelization of up to 24
links over a single physical T1/FT1 interface. CSX201
WPIM-T1/DDS
This WPIM provides both a T1 and DDS interface that
allows you to easily switch between the two interfaces by
changing the physical cabling and reconÞguring the
desired interface with QuickSET or SPEL. Currently,
however, SPECTRUM Element Manager does not
support a DDS interface on a CSX device.
3-4
CSX WPIMs
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CSX200 and CSX400 WAN Configuration
For more information on these WPIMs, consult the appropriate hardware
documentation or your QuickSET documentation.
WAN Logical View
The WAN Logical View window displays information about the interfaces that
are part of your physical port. The windows are identical for the T1 and the
Synchronous ports. The number of entries is dependent on the type of port. The
T1 port, for example, will have 24 entries.
To open this window:
1. Click on Device on the Chassis View menu bar; the device menu will appear.
2. Drag down to the WAN Status..., then right to Logical View... and release.
Figure 3-1. WAN Logical View Window
The information in this window is static; use the Refresh button to view updated logical
NOTE
settings and statistics.
WAN Logical View
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CSX200 and CSX400 WAN Configuration
WAN Logical View Window Fields
IF
Displays the interface index; a unique value for each interface that this device
connects to.
Protocol
Displays the active Link Layer protocol. This Þeld displays PPP (Point to Point),
Frame Relay, or Other.
Compression
Indicates whether data compression is activated or de-activated.
Data compression is not supported by the CSX at this time; therefore, compression will
always be de-activated or ÒOffÓ.
NOTE
MTU
Displays the MTU (Maximum Transfer Unit) for this interface. The MTU is the
largest packet size that can be transmitted on the selected interface.
Line Coding
Displays the line coding set for this interface. The Þeld displays INV-HDLC, JBZS,
or None. None (the default value) is displayed when the line coding being used
on the interface is B8ZS.
CRC Length
The length of the CRC (Cyclical Redundancy Check) for this interface.
Changing WAN Logical Settings
You can change the protocol setting, from your WAN Logical View window.
To do so:
1. Click anywhere on the line of the interface of interest, and the WAN Logical
3-6
WAN Logical View
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CSX200 and CSX400 WAN Configuration
Figure 3-2. WAN Logical Settings Window
2. Click on the Protocol button to select PPP, Frame Relay, or None. LEX (LAN
Extender) may also appear in the Protocol menu, but it is not applicable to a
CSX device.
3. After making your changes, click on OK to exit the window and save the
changes, or Cancel to exit the window without saving the changes.
Note that this window also displays the state of compression on the interface.
After exiting the Logical Settings window, the WAN Logical View window will
update with the changes you made.
If you do make any conÞguration changes through the WAN Logical Settings window,
make sure they donÕt conßict with other conÞgurations made through the QuickSET
application.
NOTE
WAN Logical View
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CSX200 and CSX400 WAN Configuration
3-8
WAN Logical View
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Chapter 4
Bridging
A brief explanation of bridging methods; viewing and managing bridging interfaces; using the Bridge
Status window; enabling and disabling bridging; viewing bridge statistics; using Spanning Tree; using
the Filtering Database; using the Source Route Configuration window; using the Find Source Address
feature; using the Port Source Addresses window; configuring duplex modes; using SONET port
configuration options; configuring broadcast suppression; using the Token Ring Bridge Mode window;
using the Physical View windows; using the Interface Configuration window; using the Bridge
Configuration and Port Configuration windows; and configuring SmartTrunking
Bridging Basics
Bridges are used in local area networks to connect two or more network segments
and to control the ßow of packets between the segments. Ideally, bridges forward
packets to another network segment only when necessary.
Bridges are also used to increase the fault tolerance in a local area network by
creating redundant bridge paths between network segments. In the event of a
bridge or bridge segment failure, an alternate bridge path will be available to
network trafÞc, without signiÞcant interruption to its ßow.
The method a bridge uses to forward packets, choose a bridge path, and ensure
that a sending stationÕs messages take only one bridge path depends on the
bridgeÕs type: Transparent (generally used in Ethernet or FDDI environments) or
Source Routing (generally used in Token Ring environments), source
routing-transparent, or source route-transparentÑthe two latter being
combinations that are found in a mixed network environment.
Not all of the sections in this chapter Ñ Source Routing and Token Ring information, for
NOTE
example Ñ are applicable to your CSX200/400 device.
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Bridging
About Transparent Bridging
Transparent bridges are most common in Ethernet networks. Individual
Transparent bridges monitor packet trafÞc on attached network segments to learn
where end stations reside in relation to each segment by mapping the Source
Address of each received frame to the port (and segment) it was detected on. This
information gets stored in the bridgeÕs Filtering Database.
When in the Forwarding state, the bridge compares a packetÕs destination address
to the information in the Filtering Database to determine if the packet should be
forwarded to another network segment or Þltered (i.e., not forwarded). A bridge
Þlters a packet if it determines that the packetÕs destination address exists on the
same side of the bridge as the source address.
If two or more bridges are connected to the same Ethernet LAN segmentÑplaced
in parallelÑonly a single bridge must be allowed to forward data frames onto
that segment. If two or more bridges were forwarding data frames onto the same
Ethernet segment, the network would soon be ßooded.
With a data loop in the topology, bridges would erroneously associate a single
source address with multiple bridge ports, and keep proliferating data by
forwarding packets in response to the ever-changing (but incorrect) information
stored in their Filtering Database.
To avoid such data storms, Transparent bridges communicate with one another
on the network by exchanging Bridge Protocol Data Units (BPDUs) to determine
the network topology and collectively implement a Spanning Tree Algorithm
(STA) that selects a controlling bridge for each LAN segment; this ensures that
only a single data route exists between any two end stations and that topology
information remains current.
About Source Route Bridging
Source Routing is typically used to connect two or more Token Ring network
segments. Source Route bridges differ from Transparent bridges in that they do
not build and then use a physical address database to make forwarding decisions.
Instead, the source end station transmits packets with a header that contains
routing information (added by bridges in the network topology during a route
discovery process between end stations); once a route has been determined, a
Source Route bridge simply reads the header of a source routed packet to
determine whether it is a participant in routing the packet.
In Source Routing, sending and receiving devices employ broadcast
packetsÑknown as explorer packetsÑto determine the most efÞcient route for a
message to travel. Generally, before a station sends a message, it will Þrst send a
test packet to all stations on the same ring; if the sending station receives a
response to this packet, it assumes that the destination station is on the same ring
and therefore it will not include routing information in frames sent to that station
in the future. Any further packets issued between stations will appear to be
transparent-style frames without embedded routing information.
4-2
Bridging Basics
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Bridging
If the sending station does not receive a response to the test packet, it will send
explorer packets to the destination; the explorer packets will be propagated by the
networkÕs bridges as either All Paths Explorer (APE) packets or as Spanning Tree
Explorer (STE) packets. The task of both packet types is to get the destination
station to return speciÞc route information to the sending station (by including an
identiÞer for each ring the explorer packet traversed and for each bridge between
any rings).
Since the data ßow on a Source Routed network is determined by end stations
(unlike a Transparently bridged network), a looped bridge topology is not an
issue for data ßow. APE packets are sent from the source station over every
possible bridge path to the end station. The original APE frame contains no
routing information (e.g., bridge numbers and ring numbers). As the frame is
propagated along all available paths to the destination station, each bridge along
the way adds its own bridge and ring numbers to the packetÕs RIF before
forwarding it, thereby providing route information.
In response to each received APE packet, the destination station directs a reply to
the sending station. On receiving the replies, the sending station ideally assumes
that the Þrst returned reply contains the most efÞcient route. The sending station
then stores the route information and uses it to send subsequent transmissions to
the same station.
Because APE frames do increase network trafÞc, some sites may use STE explorer
frames as an alternate method of route discovery. With STE exploration, a
Spanning Tree Algorithm (either conÞgured automatically via BPDUs or
manually via management) is maintained for the sole purpose of determining
how to direct an explorer frame during route discovery.
During the discovery process, a source station will send out STE explorer frames
into a bridged topology. If a bridge is in a forwarding state according to Spanning
Tree, it will forward an explorer frame onto its attached LAN segment (appending
the Bridge and LAN Segment IdentiÞers in the appropriate area of the RIF); if the
bridge is Þltering, it will discard the explorer frames. In this fashion, only a single
explorer frame will reach each individual LAN segment.
Ultimately, the destination station will receive only a single STE packet, and will
respond with APE packets (that return to the sending station on all possible
bridge paths) or an STE packet (that returns to the sending station via in the
reverse route of the STE explorer packet).
Although the Spanning Tree Algorithm determines the bridge path an STE takes
to the destination station, during future communication between the stations,
bridges along the route will use Source Routing to forward the packet (i.e., the
bridges will read the Routing Information Field in the header of speciÞcally
routed frames to decide whether to forward them).
Bridging Basics
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Bridging
About Source Route-Transparent Bridges
Because network topologies have developed in which bridges must be able to
handle network trafÞc from end stations which support source routing and others
which do not, a hybrid type of bridgeÑSource Route-Transparent
(SRT)Ñcombines elements of both bridging methods.
An end stationÕs network drivers can be conÞgured in software to use a bit setting
in the source address portion of a data frame to indicate whether the station is to
operate in a Source Route or Transparently bridged network environment. The
Routing Information Indicator (RII) bit of the source address is set to 1 if the
station is to use Source Routing; if the station is to operate in a Transparently
bridged environment, the RII bit is left unchanged (i.e., at 0).
Not all end stations in a Token Ring environment have network drivers which
support Source RoutingÑwhether the drivers are improperly conÞgured via
management or they simply are not source-route capable.
In a network with a mix of Source Route and Transparent end stations, data
frames from both station types must be bridged correctly. An SRT bridge inspects
the RII bit setting of incoming frames to determine whether they should be
Transparently bridged (if the RII bit was at 0) or Source Routed (if the RII bit was
set to 1) to their destination and will use the appropriate bridge method to
forward the frame.
Cabletron has extended the functionality of Ethernet ports on translational bridges, so the
ports can be set to Source Route mode.
NOTE
When an Ethernet port is in Source Route mode, on receipt of an SR packet from a Token
Ring port, it will save the Source Routing information and send out the packet
transparently. When the response comes back, the source routing information will be
restored and sent to the Token Ring port.
About Source Route-Translational Bridges
Because SmartSwitch 2000, 6000 and 9000 modules have the ability to combine
mixed network topologies, yet another hybrid bridge methodÑcalled a Source
Route Translational bridge (SR-TB)Ñis used by a number of these SmartSwitch
modules.
An SR-TB bridge supports both Source Routing and Transparent bridging
capabilities, with the added requirement of maintaining Source Route
information across an FDDI interfaceÑeither the SmartSwitch 9000 FNB
backplane, or an installed FDDI High Speed Interface Module (HSIM).
An SR-TB bridge does this by ÒtranslatingÓ the Token Ring physical frame format
(by stripping out routing information, if necessary) so that the frameÕs source
address can be recognized on an FDDI, Ethernet, or ATM segment; and then,
when data is returned to the source, restoring the necessary route information to
forward it along a bridged Token Ring environment.
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Bridging Basics
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Bridging
For data that is restricted to the Token Ring networks available from the SR-TB
bridgeÕs front panel, the bridging method used is user-conÞgurable via local
management to be Source Route-only (bridged packets must include RIF
information and will be source routed; no transparent bridging is enabled),
Source Route-Transparent (bridging method will be determined by whether the
RII bit is set), or Transparent only (no source routed packets will be bridged).
Remote management of these interfaces is based upon their current mode (as set
through local management).
For data that will ultimately be sent across an FDDI interface to an ATM, Ethernet,
FDDI, or another Token Ring segment, the Routing Information Field will be
stripped from the packet so the packet can be transparently bridged onto Ethernet
or FDDI media; however, the RIF information as well as the source address of the
packet is stored in a RIF cache of the SR-TB bridge. When data is returned to that
source address, the SR-TB bridge can look up the address information in its RIF
cache, append the proper Routing Information onto the packet, and then forward
the data to the Token Ring segment.
The RIF cache is a software table that can store up to 8192 entries. An SR-TB
bridge updates its RIF cache much like a Transparent bridge dynamically updates
its Filtering Database: it learns new address information by listening to incoming
packets on each port, saves that information to an Address Database, andÑif the
address was learned to be Source-Route capableÑupdates routing information
for that source address in the RIF cache. Every time a packet arrives from an FDDI
interface for a MAC address that is communicating through the SR-TB bridgeÕs
front panel, the RIF cache table is searched for an address/RIF match.
There are conÞguration issues when a Token Ring module receives a packet from
an FDDI interface for a destination address that is unknown, and not in its
Address Database or RIF cache. You must conÞgure your SR-TB bridge to treat
incoming packets with an unknown destination address as either a Source Route
or Transparently bridged packet (since Token Ring end stations attached to the
module may or may not support Source Routing).
If the bridge is conÞgured to treat an incoming packet with unknown addresses as
a Source Routed frame, it will forward it using either STE or ARE frames. If the
bridge is conÞgured to treat an incoming packet with an unknown destination as
a Transparently bridged frame, it simply forwards the frame.
After a packet with a previously unknown destination has been bridged
successfully, and communication begins between the two end nodes, the RIF
cache will be updated and packets will be translated as described previously.
Bridging Basics
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Bridging
Viewing and Managing Bridging Interfaces
With SPECTRUM Element Manager, you can view and manage each bridging
interface supported by your device, including any installed interface modules,
such as BRIMs (Bridge/Router Interface Modules) and HSIMs (High Speed
Interface Modules).
You can manage your bridge by using the following windows:
¥
¥
The Bridge Status window provide you with basic information about the
current status of the deviceÕs bridging interfaces, and allow you to enable or
disable bridging at each interface of the bridge. The Bridge Status window also
lets you access further windows to conÞgure bridging at the device (see The
Bridge statisticsÑincluding the Performance Graph, Interface Statistics,
CSMACD Statistics, PPP Link Statistics, Dot5 Error Statistics, and Source
Route Statistics windowsÑgraphically display the trafÞc passing between
your bridged networks, and let you compare and contrast trafÞc and errors
¥
¥
The Spanning Tree window shows bridge port information and protocol
parameters relating to the Spanning Tree AlgorithmÑthe method of
determining the controlling bridge when a series of bridges are placed in
With the Filtering Database window, you can see the contents of the Static and
Learned databasesÑthe two address databases which construct the IEEE 802.1
Source Address Table. The bridge uses the contents of these databases to make
its packet Þltering and forwarding decisions. You can conÞgure entries in these
databases to increase bridging efÞciency across your network (see Filtering
¥
The Ethernet Special Filter Database and Token Ring Special Filter Database
windows let you conÞgure a special Þltering scheme at your bridge. With this
scheme, you can enter Þlter parameters for a frame based on the contents of its
source or destination address Þeld, type Þeld, or data Þeld (with offset)Ñthen
specify the bridging action to take place at each port when a frame matching
¥
¥
The Duplex Modes window lists each interface on your device and whether
or not it is using Full Duplex mode. The window allows you to switch full
duplex mode on and off for each interface on the device. Full Duplex Switched
Ethernet (FDSE) mode allows the interface to transmit and receive information
The Broadcast Suppression window enables you to monitor the number of
broadcast packets received by each interface of a selected device, and
conÞgure the maximum number of broadcast packets that will be forwarded
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Bridging
¥
The SmartTrunk option invokes the SmartTrunk ConÞguration and Status
window, which enables you to group interfaces logically to achieve greater
bandwidth between devices, if both devices support the SmartTrunk feature.
There is no limit to the number of ports that can be included in a single
Òtrunk,Ó nor is there a limit to the number of trunked ÒinstancesÓ that can be
¥
¥
The Token Ring Bridge Mode window lets you select which type of bridging
that will be used by the Token Ring bridging deviceÑTransparent, Source
The Bridge ConÞguration option opens a window that allows you to set
address and routing information for all interfaces on a Token Ring bridging
device, including the Bridge Number and the Virtual Ring Number. It also
allows you to set source route bridging parameters at the device level (see
¥
¥
¥
The Port ConÞguration option opens a window that allows you to view the
address and routing information for an individual Token Ring bridging
interface. This window displays information that is set at the device level via
the Bridge ConÞguration window, such as the Bridge Number and the Virtual
Ring Number. It also allows you to set source route bridging parameters for
The I/F ConÞguration port-level menu option invokes the Interface
ConÞguration window, which allows you to select a bridging method for a
Token Ring bridging interface. This window also allows you to select one of
three transmission methods that should be used when unknown addresses are
The Source Route ConÞguration option enables you to conÞgure source
The menu options that are available will vary depending on the type of device you are
monitoring, and on the type of bridge interfaces supported by the device.
NOTE
The following sections detail how to use each of the bridge management
windows.
Viewing and Managing Bridging Interfaces
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Bridging
The Bridge Status Window
The Bridge Status window provides you with basic information about the current
status of bridging across your device. Color-coding of each port display allows
you to quickly ascertain the status of each interface. The Bridge Status window
also lets you access further windows to control bridging at your device.
To access the Bridge Status window from the Chassis View window:
1. Click on the Device selection in the menu bar. A pull-down menu will appear.
Bridge Status Window Information Fields
The following information is provided by the Bridge Status window for the
monitored device as a whole and for each individual bridging interface. Since the
Bridge Status window can only display four interfaces simultaneously, the
and
buttons are activated when a device supports over four bridge
interfaces, so that you can scroll the display to show all interfaces.
When you Þrst open the Bridge Status window the Prev and Next buttons will be grayed
out, and a message will appear stating that the application is initializing and processing
each interface. You will not be able to scroll the display until after all the bridging
interfaces have been processed.
NOTE
4-8
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Bridging
Figure 4-1. The Bridge Status Window
Up Time
At the top of the Bridge Status window, you can see the time period (in a days,
hours, minutes, seconds format) that has elapsed since the device was last reset or
initialized.
Bridge State on Interface
Indicates the state of bridging over the port interface. Possible bridge states and
their corresponding colors are:
¥
Forwarding (green)ÑThe port is on-line and forwarding packets across the
bridge from one network segment to another.
¥
Disabled (blue)ÑBridging at the port has been disabled by management; no
trafÞc can be received or forwarded on this port, including conÞguration
information for the bridged topology.
¥
¥
Listening (magenta)ÑThe port is not adding information to the Þltering
database. It is monitoring Bridge Protocol Data Unit (BPDU) trafÞc while
preparing to move to the forwarding state.
Learning (magenta)ÑThe Forwarding database is being created, or the
Spanning Tree Algorithm is being executed because of a network topology
change. The port is monitoring network trafÞc, and learning network
addresses.
The Bridge Status Window
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Bridging
¥
Blocking (orange)ÑThe port is on-line, but Þltering trafÞc from going across
the bridge from one network segment to another. Bridge topology information
will be forwarded by the port.
Interface Type
Indicates the interface type which applies to each device bridging port interface
(e.g., ethernet). The interface type (ifType) is a mandatory object type from the
SNMP MIB II Interface (if) Group.
Bridge Address
Indicates the physical address of the bridge interface.
Speed
Indicates the speed of the interface in Mb/s or Gb/s.
Accessing Other Options from the Bridge Status Window
At the top of the Bridge Status window, you can click
to access a menu that
provides other bridge management options. Depending on which device you are
monitoring via SPECTRUM Element Manager, the following bridge management
options will be available:
¥
The Module TypeÉ window displays a description of the device that is
currently being monitored.
¥
The Find Source AddressÉ window allows you to discover the bridge
interface through which a particular MAC address is communicating (see
¥
¥
The Performance GraphÉ window displays statistics for trafÞc across the
The Spanning TreeÉ window allows you to set the Spanning Tree Algorithm
¥
The SmartTrunkÉ option invokes the SmartTrunk ConÞguration and Status
window, which enables you to group interfaces logically to achieve greater
bandwidth between devices, if both devices support the SmartTrunk feature.
There is no limit to the number of ports that can be included in a single
Òtrunk,Ó nor is there a limit to the number of trunked ÒinstancesÓ that can be
¥
The Filtering DatabaseÉ window lets you see the contents of the Static and
Learned databasesÑthe two address databases which construct the IEEE 802.1
Source Address Table. The bridge uses the contents of these databases to make
its packet Þltering and forwarding decisions. You can conÞgure the bridgeÕs
acquired and permanent Þltering databases to Þlter or forward trafÞc across
4-10
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Bridging
¥
The Ethernet Special Filter DatabaseÉ window lets you conÞgure a special
Þltering scheme at your bridge. With this scheme, you can enter Þlter
parameters for a frame based on the contents of its source or destination
address Þeld, type Þeld, or data Þeld (with offset)Ñthen specify the bridging
action to take place at each port when a frame matching your speciÞcations is
¥
¥
The Token Ring Special Filter DatabaseÉ window enables you to deÞne
complex Þlters for transparently bridged Token Ring frames based upon
receive port, source or destination MAC address, Token Ring data type, or data
The Token Ring Bridge ModeÉ window lets you select which type of
bridging that will be used by the Token Ring bridging deviceÑTransparent,
¥
¥
The Duplex ModesÉ window allows you to conÞgure duplex mode (on or
Enable Bridge and Disable Bridge options allow you to administratively
¥
The Bridge ConÞgurationÉ option opens a window that allows you to set
address and routing information for all interfaces on a Token Ring bridging
device, including the Bridge Number and the Virtual Ring Number. It also
allows you to set source route bridging parameters at the device level (see
The individual bridge port index ( ) menu that you can access from the Bridge
Status window will provide the following options, depending on which device
you are monitoring through SPECTRUM Element Manager:
¥
¥
¥
The Connection TypeÉ window displays a text description of the connection
type of the selected bridge interface.
The DescriptionÉ option displays a text description of a bridge interface from
the ifDescr value of the ifIndex related to the selected port.
The Performance GraphÉ window graphically displays the trafÞc passing
between your bridged networks, and lets you compare and contrast trafÞc
¥
The Source AddressingÉ window displays the contents of the deviceÕs
Filtering Database with respect to a selected port. This will display the source
MAC addresses that have been detected by the port as it forwards data across
the network. The window also lets you set the aging timer that controls how
long an inactive MAC address will continue to be stored in the Source Address
The Bridge Status Window
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Bridging
¥
¥
¥
The PPP Link StatusÉoption invokes the PPP Link Statistics Window, which
enables you to view color-coded statistics related to the PPP (Point-to-Point
The Source Route StatisticsÉ option opens a window that allows you to view
statistics for source routed trafÞc passing between bridging ports. The window
enables you to view the frames that were received, transmitted, and discarded
The I/F ConÞguration port-level menu option invokes the Interface
ConÞguration window, which allows you to select a bridging method for a
Token Ring bridging interface. This window also allows you to select one of
three transmission methods that should be used when unknown addresses are
¥
¥
The Source Route ConÞgurationÉ option opens a window that enables you
The Port ConÞgurationÉ option opens a window that allows you to view the
address and routing information for an individual Token Ring bridging
interface. This window displays information that is set at the device level via
the Bridge ConÞguration window, such as the Bridge Number and the Virtual
Ring Number. It also allows you to set source route bridging parameters for
¥
¥
The Dot5 ErrorsÉ invokes a window that enables you to view 802.5 statistics
The RMON MAC LayerÉ option opens the Token Ring Statistics window for
Token Ring devices that support RMON, which enables you to view a
statistical breakdown of trafÞc on the monitored Token Ring interface
(network segment). Note that if the RMON default MIB component is
disabled, the RMON MAC Layer menu option will launch the Interface
Statistics window. Refer to the SPECTRUM Element Manager Remote
Monitoring (RMON) UserÕs Guide for more information on how to enable and
disable RMON MIB components. For more information about this menu
option, refer to the Statistics chapter in the SPECTRUM Element Manager
Remote Monitoring (RMON) UserÕs Guide, and/or the appropriate
device-speciÞc UserÕs Guide.
¥
The RMON Promiscuous StatsÉ option opens the Token Ring Promiscuous
Statistics window, which allows you to view statistical information on those
packets that carry the normal data ßow across a bridging interface (network
segment). Note that if the RMON default MIB component is disabled, the
RMON Promiscuous Stats menu option will launch the Interface Statistics
window. Refer to the SPECTRUM Element Manager Remote Monitoring
(RMON) UserÕs Guide for more information on how to enable and disable
RMON MIB components. For more information about this menu option, refer
4-12
The Bridge Status Window
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Bridging
to the Statistics chapter in the SPECTRUM Element Manager Remote
Monitoring (RMON) UserÕs Guide, and/or the appropriate device-speciÞc
UserÕs Guide.
¥
The RMON Alarm ConÞgurationÉ invokes the Basic Alarm ConÞguration
window that enables you to create alarms or actions at a speciÞc bridge
interface based on rising and falling thresholds for Kilobits,
Broadcast/Multicast packets, or Total Errors. Note that if the RMON default
MIB component is disabled, the RMON Alarm ConÞguration menu option
will still appear and the window will still display; however, you will not have
the ability to set anything. Refer to the SPECTRUM Element Manager Remote
Monitoring (RMON) UserÕs Guide for more information on how to enable and
disable RMON MIB components. For more information about this menu
option, refer to the RMON Alarms and Events chapter in the SPECTRUM
Element Manager Remote Monitoring (RMON) UserÕs Guide, and/or the
appropriate device-speciÞc UserÕs Guide.
¥
The I/F StatisticsÉ option activates the Interface Statistics Port window,
which allows you to view color-coded statistical information about each
individual bridge port on the currently monitored device (see The Interface
¥
¥
The ConÞgurationÉ option opens a window that enables you to conÞgure the
The Alarm ConÞgurationÉ option appears as a menu choice for Ethernet
devices which support RMON, and invokes the RMON Basic Alarm
ConÞguration window that enables you to create alarms or actions at a speciÞc
bridge interface based on rising and falling thresholds for Kilobits,
Broadcast/Multicast packets, or Total Errors. Note that if the RMON default
MIB component is disabled, the Alarm ConÞguration menu option will still
appear and the window will still display; however, you will not have the
ability to set anything. Refer to the SPECTRUM Element Manager Remote
Monitoring (RMON) UserÕs Guide for more information on how to enable and
disable RMON MIB components. For more information about this window,
refer to the RMON Alarms and Events chapter in the SPECTRUM Element
Manager Remote Monitoring (RMON) UserÕs Guide, and/or the appropriate
device-speciÞc UserÕs Guide.
¥
The StatisticsÉ option appears as a menu choice for Ethernet devices which
support RMON, and it opens the Ethernet Statistics window, which enables
you to view a statistical breakdown of trafÞc at the monitored Ethernet
network segment. Note that if the RMON default MIB component is disabled,
the Statistics menu option will launch the Interface Statistics window. Refer to
the SPECTRUM Element Manager Remote Monitoring (RMON) UserÕs Guide
for more information on how to enable and disable RMON MIB components.
For more information about this menu option, refer to the Statistics chapter in
the SPECTRUM Element Manager Remote Monitoring (RMON) UserÕs Guide,
and/or the appropriate device-speciÞc UserÕs Guide.
The Bridge Status Window
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Bridging
¥
The Sonet/SDH ConÞgurationÉ window enables you to determine whether
any installed FE-100Sx Fast Ethernet Port Interface Modules or APIM-2x ATM
Port Interface Modules, both of which provide direct access to SONET
(Synchronous Optical Network) networks, will operate according to SONET
or SDH (Synchronous Digital Hierarchy) standards (see SONET/SDH
¥
¥
The Sonet StatisticsÉ option opens a window that will let you view some of
the statistical information related to any installed FE100-Sx Fast Ethernet Port
The Physical ViewÉ option allows you to view the physical state of the
Ethernet bridge port through the ETW EtherPhysStatus window and the
Token Ring bridge port through the Token Ring Phys Status window when
you are monitoring an ETWMIM via SPECTRUM Element Manager (see
¥
¥
The CSMACD StatsÉ option opens a window that enables you to view
color-coded statistical information for some Ethernet bridging interfaces,
including receive errors, transmission errors, and collision errors (see The
Enable and Disable options allow you to administratively enable or disable
Enabling and Disabling Bridging
When you disable a bridge port, you disconnect that portÕs network from the
bridge entirely. The port does not forward any packets, nor does it participate in
Spanning Tree operations. Nodes connected to the network can still communicate
with each other, but they canÕt communicate with the bridge and other networks
connected to the bridge. When you enable a port, the port moves from the
Disabled state through the Learning and Listening states to the Forwarding or
Blocking state (as determined by Spanning Tree).
Enabling and Disabling Individual Interfaces
There are two ways to disable an individual port interface:
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to Enable to restart bridging on the selected interface, or Disable
to halt bridging across the selected interface.
4-14
Enabling and Disabling Bridging
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Bridging
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to Enable to restart bridging on the selected interface, or Disable
to halt bridging across the selected interface.
Enabling and Disabling All Installed Interfaces
Similarly, there are two ways to disable bridging across all interfaces installed in a
device:
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to Enable Bridge to enable bridging across all installed interfaces,
or to Disable Bridge to disable bridging across all installed interfaces.
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to Enable Bridge to enable bridging across all installed interfaces,
or to Disable Bridge to disable bridging across all installed interfaces.
Bridge Statistics
The following sections describe Statistics windows that are available for the
bridge that is being monitored via SPECTRUM Element Manager, both at the
device and port levels.
Performance Graphs
You use Bridge Performance Graphs to view a color-coded strip chart that shows
you the trafÞc being bridged through all networks or an individual network
supported by your device. You can conÞgure the display to show frames Þltered,
forwarded, or transmitted across the device or its individual bridging interfaces,
as well as the number of errors experienced at both levels. The graph has an X axis
that indicates the 60-second interval over which charting occurs continuously,
while its Y axis measures the number of packets or errors that are processed by
the device or its bridging interfaces.
You can select the type of errors you wish to monitor by using the available menu
buttons. When you click on the error type you wish to view, the name of that error
will appear in the button, and the Performance Graph will refresh. The graph will
now generate a strip chart based on the newly deÞned parameters.
Bridge Statistics
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Bridging
At the device level, a Detail button on the window allows you to compare the
packets forwarded, Þltered, or transmitted on all networks supported by the
device, as well as errors on all networks.
For a selected bridged network, the Detail button allows you to view the number
of packets forwarded to, or received from, each other network supported by the
device.
To access the device-level Bridge Performance Graph window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select Performance Graph…. The device Bridge Performance
Performance Graph windows are similar, except that they display a graph
applicable to the selected interface.)
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to select Performance Graph…. The device Bridge Performance
To access the port-level Bridge Performance Graph window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select Performance Graph…. The port Bridge Performance
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select Performance Graph…. The port Bridge Performance
The displayed graphic in Figure 2-2 is a device-level window; the window that is
displayed at the port level is virtually identical to the one at the device level.
NOTE
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Bridging
Figure 4-2. Bridge Performance Graph
Bridge Performance Graph Window Fields
You can select the following statistics to display in the Bridge Performance Graph
or Bridge Port Performance Graph. Statistics are provided numerically (as an
average or peak value) and graphically. The device is polled for the graphed
information every 2 seconds, and numeric values are updated based on this poll.
The graph updates at the Þxed two second interval. For the Þrst 60 seconds of
graphing, you will note the graph lines extending as each intervalÕs data is added
to the graph. Once the Þrst 60 seconds has passed, the newest data is added at the
right edge of the graph, and the oldest data is scrolled off to the left.
Peak statistics are based on the peak level of activity returned from a single poll
since the Performance Graph window was invoked. A date and time is provided
for peak levels.
The Average statistics are updated every two seconds as averaged over the
previous four poll intervals (i.e., averaged over a sliding eight second time
window).
Frames Forwarded (Green)
Forwarded
The number of frames forwarded by the deviceÕs bridge,
at the device or port level.
Nothing
The Frames Forwarded function is currently not
measuring any statistics.
Filtered (Magenta)
Filtered
The total number of frames Þltered by the deviceÕs
bridge, at the device or port level.
Nothing
The Filtered scale is not currently measuring the number
of packets Þltered by the bridge at the device or port
level.
Bridge Statistics
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Bridging
Errors (Red)
Total Errors
The total number of errors that all bridging interfaces on
the device, or an individual bridge interface, has
experienced during bridging.
Nothing
The Errors scale is currently not measuring any type of
error packets coming through the device or port.
Xmitted (Blue)
Xmitted
The total number of frames transmitted by the selected
bridge interface, or all bridge interfaces.
Nothing
The Xmitted scale is not currently measuring the number
of packets Þltered by the bridge or the individual
interface.
Configuring the Bridge Performance Graphs
To conÞgure the Bridge Performance Graph:
1. Using the mouse, click on (with green statistics to the right). The
Forwarded menu will appear. Click on the desired mode.
2. Click on (with magenta statistics to the right). The Filtered menu
will appear. Click on the desired mode.
3. Click on (with red statistics to the right). The Errors menu will
appear. Click on the desired mode.
4. Click on (with blue statistics to the right). The Xmitted menu will
appear. Click on the desired mode.
Once you have selected a new mode, it will appear in its respective button, and
after the next poll the Performance Graph will refresh and begin to measure using
the new mode.
The Bridge Detail Breakdown Window
The Bridge Detail Breakdown window allows you to compare the number of
frames forwarded, Þltered, and transmitted on the network segments connected
to each interface of your device bridge, as well as the number of errors
experienced on each interface.
The Bridge Detail Breakdown window will not be available if your device has more than
13 bridge ports.
NOTE
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Bridging
To access this window from the Bridge performance graph, click on
. The
Figure 4-3. The Bridge Detail Breakdown Window
The following information is available for the network segments connected to
each of the bridge ports on the device, and any installed BRIM or HSIM port.
The information is expressed both numerically and in pie charts. Each portÕs
network segment has a corresponding color for its statistics or pie chart segments.
Depending on your particular bridge and its conÞguration, the segments are
color-coded as follows: light red = LAN 1, light green = LAN 2, yellow = LAN 3,
light gray = LAN 4, light cyan = LAN 5, light blue = LAN 6, green = LAN 7,
red = LAN 8, hot pink = LAN 9, light magenta = LAN 10, blue = LAN 11,
cyan = LAN 12, black = LAN 13.
The values given in these Þelds are cumulative totals.
Frames Forwarded
The total number of frames forwarded on each portÕs network segment, as read
from the device after each poll interval.
Filtered
The total number of frames Þltered on each portÕs network segment, as read from
the device after each poll interval.
Errors
The total number of frames (either inbound or outbound) containing errors which
prevented them from being processed by each bridge interface, as reported from
the device during the last poll interval.
Bridge Statistics
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Bridging
Xmitted
The total number of frames transmitted over each portÕs network segment, as
read from the device after each poll interval.
The Bridge Port Detail Breakdown Window
For the selected bridge interface, the Bridge Port Detail Breakdown window
allows you to view the number of packets forwarded to or received from each of
the other interfaces on your device.
To access the Bridge Port Detail Breakdown window from the port Bridge
performance graph, click
Figure 4-4, will appear.
. The Bridge Port Detail Breakdown window,
Figure 4-4. The Bridge Port Detail Breakdown Window
The following information is available for each bridge interface on the device. The
information is expressed both numerically and in pie charts. The colors
corresponding to the forwarding interfaces will vary, depending on which
interface is selected.
Forwarded to
The number of frames forwarded by the selected bridge interface to each other
interface on the bridge, as read from the device after each poll interval.
Forwarded from
The total number of frames received by the selected bridge interface from each of
the other bridge interfaces, as read from the device after each poll interval.
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Bridging
The Interface Statistics Window
You can use the interface Statistics window to view color-coded statistical
information for each individual bridge port on your device. Statistics are
provided for both transmit and receive packets at each port, as well as error and
buffering information.
Color-coded pie charts in the middle of the window lets you graphically view
statistics for Unicast, Non-Unicast, Discarded and Error packets.
To access the Statistics window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select I/F Statistics…. The device port I/F Statistics window,
Figure 4-5, will appear.
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select I/F Statistics…. The device port I/F Statistics window,
Figure 4-5, will appear.
Figure 4-5. I/F Statistics Window
Bridge Statistics
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Bridging
Statistics Window Fields
The following informational and statistics Þelds appear in the interface Statistics
window.
Three informational Þelds appear in the upper portion of the window:
Description
Describes the interface description for the currently selected port.
Address
Displays the MAC (physical) address of the selected port.
Type
Displays the interface type of the selected port.
The following transmit and receive statistics Þelds are displayed in the lower
portion of the window. The Þrst four statistics are also graphically displayed in a
pie chart. The statistics are read directly from the device, and are updated with
each poll from SPECTRUM Element Manager to the device.
Unicast
Displays the number of packets transmitted to, or received from, this interface
that had a single, unique source or destination address. These statistics are
displayed in the pie chart (color-coded green).
Non-Unicast
Displays the number of packets transmitted to, or received from, this interface
that had a source or destination address that is recognized by more than one
device on the network segment. The non-unicast Þeld includes a count of
broadcast packetsÑthose that are recognized by all devices on a segment. These
statistics are displayed in the pie chart (color-coded dark blue).
Discarded
Displays the number of packets which were discarded even though no errors
were detected to prevent transmission. One possible reason for discarding such a
packet could be to free up buffer space.
Discarding good packets indicates a very busy network. If a device routinely
discards packets, it usually means that network trafÞc is overwhelming the
device, perhaps because the device is performing poorly.
These statistics are displayed in the pie chart (color-coded hot pink).
Error
Displays the number of packets received or transmitted that contained errors.
These statistics are displayed in the pie chart (color-coded red).
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Bridging
Unknown Protocol
Displays the number of packets received which were discarded because of an
unknown or unsupported protocol. The device bridge interface will discard the
packet and increment this counter if it canÕt recognize the packet.
Packets Received
Displays the number of packets received by this interface.
Transmit Queue Size
The number of packets currently queued by the device for transmission from this
interface. The amount of device memory devoted to buffer space, and the trafÞc
level on the target network, determine how large the output packet queue can
grow before the device begins to discard packets.
Packets Transmitted
Displays the number of packets transmitted by this interface.
The CSMACD Statistics Window
The CSCMACD Statistics Windows display statistics for some Ethernet bridging
interfaces. Receive errors, transmission errors, and collision errors are displayed
in this window.
Three color-coded pie charts allow you to graphically view the breakdowns of
each statistics group.
To access the CSMACD Statistics window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select CSMACD Stats…. The device port CSMACD Statistics
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select CSMACD Stats…. The device port CSMACD Statistics
Bridge Statistics
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Bridging
Figure 4-6. CSMACD Statistics Window
Each of the receive, transmission, and collision errors are described in detail
below.
Receive Errors
Alignment
The number of frames received on a particular interface that contain a nonintegral
number of bytes (color-coded green). Misaligned packets can result from a MAC
layer packet formation problem, or from a cabling problem that is corrupting or
losing data.
FCS
The number of frames received on a particular interface that are an integral
number of bytes in length, but do not pass the FCS (Frame Check Sequence)
check.
FCS, or Frame Check Sequence, errors occur when packets are somehow
damaged on transit. When each packet is transmitted, the transmitting interface
computes a frame check sequence (FCS) value based on the contents of the packet,
and appends that value to the packet. The receiving interface performs the same
computation; if the FCS values differ, the packet is assumed to have been
corrupted and is counted as an FCS error.
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Bridging
SQE Test
Displays the number of times that the SQE Test Error message is generated by the
PLS sublayer on the selected interface.
The SQE (Signal Quality Error) Test tests the collision detect circuitry after each
transmission. If the SQE Test fails, a SQE Test Error is sent to the interface to
indicate that the collision detect circuitry is malfunctioning.
Carrier Sense
Displays the number of times that the carrier sense condition was lost or never
asserted when attempting to transmit a frame on a particular interface.
Carrier sense describes the action an interface desiring to transmit will take to
listen to the communication channel to see if any other interface is transmitting. If
a Òcarrier is sensed,Ó the sensing interface will wait a random length of time, and
then attempt to transmit.
Frame Too Long
Displays the amount of frames received on this interface that exceed the
maximum permitted frame size.
Internal MAC
The number of frames that failed to be received by the interface due to an internal
MAC sublayer receive error. These errors are only counted if a Frame Too Long,
Alignment, or FCS Error did not occur along with the internal MAC error.
Receive Errors
Displays the total number of receive errors of all types that were detected by the
selected interface while it was receiving a transmission.
Transmission Errors
Deferred
Displays the number of frames for which the Þrst transmission attempt on this
interface is delayed because the medium is busy.
Internal MAC
The number of frames for which transmission fails due to an internal MAC
sublayer transmit error. This error is only counted in this window if there have
not been corresponding Late Collisions, Excessive Collisions, or Carrier Sense
Errors.
Transmit Errors
The total of transmission errors of all types that occurred while the selected
interface was attempting to transmit frames.
Bridge Statistics
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Bridging
Collision Errors
Single
Displays the number of successfully transmitted frames on the selected interface
for which transmission was prevented by one collision.
Multiple
Displays the number of successfully transmitted frames on the selected interface
for which transmission was prevented by more than one collision.
Late
Displays the number of times that a collision has been detected on this interface
later than 51.2 microseconds into the transmission of the packet on a 10 Mbit/s
system or later than 5.12 microseconds on a 100 Mbit/s system.
Excessive
Displays the number of frames from this interface for which transmission was not
complete due to excessive collisions.
Collision Errors
Displays the total number of collision errors of all types that occurred during
transmission from this interface.
The PPP Link Statistics Window
The PPP Link Status menu option opens the PPP Link Statistics window, which
enables you to view color-coded statistics related to the PPP (Point-to-Point
Protocol) link at the selected interface.
The Point-to-Point Protocol is a standard method of transporting multiprotocol
datagrams over point-to-point links. A PPP Link provides full-duplex
communication between the endpoints, allowing a simultaneous bidirectional
operation that should maintain the order in which data packets are transmitted.
To access the PPP Link Statistics window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select PPP Link Status…. The device port PPP Link Statistics
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select PPP Link Status…. The device port PPP Link Statistics
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Bridging
Figure 4-7. PPP Link Statistics Window
Each of the errors and statistics related to the PPP Link at the selected bridging
interface is described in detail below.
Errors
Bad Addresses
The Bad Addresses Þeld displays the number of packets received with an
incorrect Address Þeld.
Bad Controls
The Bad Controls Þeld displays the number of packets received on the selected
interface that have an incorrect Control Þeld.
Packets Too Long
The Packets Too Long Þeld displays the number of received packets that were
discarded because their length exceeded the MRU (Maximum Receive Unit). Note
that packets that are longer than the MRU and that are successfully received and
processed are not included in the count.
Bridge Statistics
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Bridging
Bad FCSs
The Bad FCSs Þeld displays the number of received packets that were discarded
due to having an incorrect FCS (Frame Check Sequence) value.
Total Errors
The Total Errors Þeld displays the total number of errors of all types: Bad
Addresses, Bad Controls, Packets Too Long, and Bad FCSs.
Statistics
Local MRU
The Local MRU Þeld displays the current value of the MRU (Maximum Receive
Unit) for the local PPP entity. This value is the MRU that the remote entity uses
when sending packets to the local PPP entity. The MRU is the maximum length of
data information (included ÒpaddedÓ data octets, but excluding the Protocol Þeld
which identiÞes the datagramÕs protocol type) that can be received by this
interface. The default MRU size is 1500 octets. The auto-negotiation process may
establish another value for MRU if consent is given at both ends of the PPP link (if
either the local or remote PPP entity informs the other that larger packets can be
sent, or requests that smaller packets be sent).
Remote MRU
The Remote MRU Þeld displays the current value of the MRU (Maximum Receive
Unit) established for the remote interface at the other end of the PPP Link. This
value is the MRU that the local entity uses when sending packets to the remote
PPP entity.
Local to Peer ACC Map
The Local to Peer ACC Map Þeld displays the current value of the Asynchronous
Control Character (ACC) Map used for sending packets from the local PPP entity
to the remote PPP entity. In effect, this is the ACC Map that is required in order to
ensure that all characters can be successfully transmitted through the local
modem. The actual ACC Map used on the transmit side of the link will be a
combination of the local nodeÕs pppLinkConÞgTransmitACCMap and the remote
nodeÕs pppLinkConÞgReceiveACCMap.
Peer to Local ACC Map
The Peer to Local ACC Map Þeld displays the Asynchronous Control Character
(ACC) Map used by the remote PPP entity when transmitting packets to the local
PPP entity. In effect, this is the ACC Map that is required in order to ensure that
the local modem will successfully receive all characters. The actual ACC Map
used on the receive side of the link will be a combination of the local nodeÕs
pppLinkConÞgReceiveACCMap and the remote nodeÕs
pppLinkConÞgTransmitACCMap.
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Bridging
Local to Remote Protocol Compression
The Local to Remote Protocol Compression Þeld determines whether or not the
local PPP entity uses Protocol Compression when transmitting packets to the
remote PPP entity.
Remote to Local Protocol Compression
The Remote to Local Protocol Compression Þeld determines whether or not the
remote PPP entity uses Protocol Compression when transmitting packets to the
local PPP entity.
Local to Remote AC Compression
The Local to Remote AC Compression Þeld determines whether or not the local
PPP entity uses Address and Control (AC) Compression when transmitting
packets to the remote PPP entity.
Remote to Local AC Compression
The Remote to Local AC Compression Þeld determines whether or not the remote
PPP entity uses Address and Control (AC) Compression when transmitting
packets to the local PPP entity.
Transmit FCS Size
The Transmit FCS Size Þeld displays the size of the Frame Check Sequence (FCS),
in bits, that the local node generates when sending packets to the remote node.
Currently, only a 16 bit FCS is supported.
Receive FCS Size
The Receive FCS Size Þeld displays the size of the Frame Check Sequence (FCS),
in bits, that the remote node generates when sending packets to the local node.
Currently, only a 16 bit FCS is supported.
The Dot5 Errors Statistics Window
The Dot5 Errors menu option invokes the Dot5 Errors Statistics window, which
enables you to view IEEE 802.5 error statistics reported for a Token Ring bridge
interface.
To access the Dot5 Errors Statistics window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select Dot5 Errors…. The device port Dot5 Errors Statistics
Bridge Statistics
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Bridging
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select Dot5 Errors…. The device port Dot5 Errors Statistics
Figure 4-8. Dot5 Errors Statistics Window
Each type of IETF 802.5 error detected by the selected station port is described in
detail below.
Line Errors
The Line Errors Þeld displays the number of the line errors detected by the
selected port. This error indicates a nondata bit between the starting and ending
delimiters of data or a frame check sequence (FCS) error.
Burst Errors
The Burst Errors Þeld displays the number of burst errors detected by the selected
port. This error indicates a bit information encoding error when there are no
transitions between 0 and 1 over Þve half-bit times.
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Bridging
A. C. Errors
The A. C. Errors Þeld displays the number of A. C. errors detected by the selected
port. These errors count protocol data units (PDUs) that contain errors in the A or
C bits.
Abort Sequences
The Abort Sequences Þeld displays the number of abort sequences transmitted by
the selected port.
Internal Errors
The Internal Errors Þeld displays the number of recoverable internal errors
detected by the selected port.
Lost Frames
The Lost Frames Þeld displays the number of lost frames transmitted by the
selected port that have not returned because the Timer Return to Repeat (TRR)
expired.
Congestion Errors
The Congestion Errors Þeld displays the number of times the selected port has not
been able to copy a protocol data unit (PDU) addressed to it because of a lack of
internal buffering.
F. C. Errors
The F. C. Errors Þeld displays the number of protocol data units (PDUs)
addressed to the selected station with the A bits already set to 1. This error
indicates that a possible electrical line disturbance or a duplicate address has
occurred on the ring.
Token Errors
The Token Errors Þeld displays the number of times that the selected station,
acting as the active monitor, detected an error condition that needed a token
transmitted.
Soft Errors
The Soft Errors Þeld displays the number of soft errors detected by the selected
port.
Hard Errors
The Hard Errors Þeld displays the number of immediately recoverable fatal errors
detected by the selected port.
Signal Loss
The Signal Loss Þeld displays the number of times that the selected port has
detected the loss of a signal condition from the ring.
Bridge Statistics
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Bridging
Transmit Beacons
The Transmit Beacons Þeld displays the number of beacon frames transmitted by
the selected station.
Recoveries
The Recoveries Þeld displays the number of frames the ring has been purged and
recovered into a normal operating state.
Lobe Wires
The Lobe Wires Þeld displays the number of open or short circuits detected in the
lobe data path.
Removes
The Removes Þeld displays the number of Remove Ring Station MAC frame
requests detected by the selected port.
Singles
The Singles Þeld displays the number of times the selected station has detected
that it is the only station on the ring. This error may indicate that the station is the
Þrst on the ring or that there is a hardware problem.
Frequency Errors
The Frequency Errors Þeld displays the number of times that the selected station
detected a larger-than-allowed difference between the incoming frequency and
the expected frequency.
Source Route Statistics
The Source Route Statistics menu option invokes the Bridge Source Routing
window, which allows you to compare the statistics on frames received,
transmitted, and discarded at the Token Ring interfaces of devices that are
bridging from a source routing network to a transparent network.
To access the Bridge Source Routing window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select Source Route Statistics…. The Bridge Source Routing
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select Source Route Statistics…. The Bridge Source Routing
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Bridging
Figure 4-9. The Bridge Source Routing Window
Bridge Source Routing Window Fields
The Bridge Source Routing window provides basic statistics for source routed
trafÞc passing between the bridging ports. Pie charts graphically break down the
statistical information.
The following frame types are provided for frames transmitted, received, and
discarded by the bridge ports. All statistics are calculated since the device was last
reset or powered up.
Received Frames
Specif. Routed
Displays the total number of SpeciÞcally Routed Explorer frames received by the
indicated port from its attached segment.
These frames have data and routing information and are following a known route
from source to destination.
All Paths Expl.
Displays the total number of All Path Explorer frames received by the indicated
port from its attached segment.
Bridge Statistics
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Bridging
When a sending station needs to determine the best route to an intended
destination, it transmits an All Paths Explorer (APE) frame. The APE frame
contains no routing information; it is propagated along all available paths to the
destination station, which then directs a reply back to the source. The Þrst reply
received by the original sending station is considered the most efÞcient route and
is used in subsequent transmissions.
Span.Tree Expl.
Displays the total number of Spanning Tree Explorer (STE) frames received by the
indicated port from its attached segment.
STE frames, also known as Single Route Broadcast frames, follow the topology
established by the Spanning Tree Algorithm.
Transmitted Frames
Specif. Routed
Displays the total number of SpeciÞcally Routed Frames transmitted by the
indicated port onto its attached segment.
All Paths Expl.
Displays the total number of All Path Explorer frames transmitted by the
indicated port onto its attached segment.
Span Tree Expl.
Displays the total number of Spanning Tree Explorer (STE) frames transmitted by
the indicated port onto its attached segment.
Discards
Segment Mismatch
Displays the number of explorer frames discarded because their routing
descriptor Þeld contained an invalid value for a segment attached to the port.
The routing information Þeld of a SpeciÞcally Routed frame contains LAN
Segment In (Ring In)ÐBridge NumberÐLAN Segment Out (Ring Out) information.
If the bridgeÕs LAN Segment Out value does not match the LAN Segment Out
speciÞed in the frameÕs Routing Information Field, the bridge logs a Segment
Mismatch and discards the frame.
Duplicate Segment
Displays the number of frames discarded because the frameÕs Routing
Information Field identiÞes a particular segment more than once.
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Bridging
Hop Cnt. Exceeded
Displays the number of All Paths Explorer frames discarded at the speciÞed port
because they exceeded the number of routing descriptors (bridge hops) speciÞed
by the Hop Count Limit.
Bridge Spanning Tree
The Bridge Spanning Tree window allows you to display and modify the deviceÕs
bridge port information and protocol parameters relating to the Spanning Tree
Algorithm.
In a network design with multiple bridges placed in parallel (i.e, attached to the
same LAN), data loops must be prevented. The Spanning Tree Algorithm (STA) is
the method that bridges use to communicate with each other to ensure that only a
single data route exists between any two end stations.
On a LAN interconnected by multiple bridges, Spanning Tree selects a controlling
Root Bridge and Port for the entire bridged LAN, and a Designated Bridge and
Port for each individual LAN segment. A Designated Port/Bridge for a LAN
segment forwards frames from that LAN towards the Root Bridge, or from the
Root Bridge onto the LAN. All other bridge ports attached to that LAN are
conÞgured to Þlter (block) frames.
When data passes from one end station to another across a bridged LAN, it is
forwarded through the Designated Bridge/Port for each LAN segment towards
the Root Bridge, which in turn forwards frames towards Designated
Bridges/Ports on its opposite side.
During the Root Bridge Selection process, all bridges on the network
communicate STA information via Bridge Protocol Data Units (BPDUs). With
BPDUs, all network bridges collectively determine the current network topology
and communicate with each other to ensure that the topology information is kept
current.
To access the Bridge Spanning Tree window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select Spanning Tree…. The Bridge Spanning Tree window,
Figure 4-10, will appear.
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to select Spanning Tree…. The Bridge Spanning Tree window,
Figure 4-10, will appear.
Bridge Spanning Tree
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Bridging
Figure 4-10. Bridge Spanning Tree Window
Configuring the Bridge Spanning Tree Window
The Bridge Spanning Tree window displays STA parameters and allows you to
alter parameters for the device bridge as a whole, and for each individual
bridging interface.
The currently selected bridging interface is highlighted in the lower right
quadrant of the window. To alter the parameters of another interface, click on the
appropriate Port X name listed in the quadrant.
Bridge Level Fields
Bridge Priority
This Þeld displays the ÒpriorityÓ component of the deviceÕs unique bridge
identiÞer. The Spanning Tree Algorithm assigns each bridge a unique identiÞer,
which is derived from the bridgeÕs MAC address and the Priority. The bridge with
the lowest value of bridge identiÞer is selected as the Root. A lower priority
number indicates a higher priority; a higher priority enhances a bridgeÕs chance
of being selected as the Root.
You can edit this text box to change network topology, if needed. The default
value is 8000; the range is 0ÑFFFF hexadecimal.
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Bridging
Part of a bridgeÕs IdentiÞer is based on its MAC address. In most network installations,
performance differences between bridges may be negligible. You may, however, Þnd your
data bottle-necked in installations where both a low-performance bridge and a
high-performance bridge are attached to the same LAN segment and the two (or more)
bridges have the same Priority component set (e.g., at the default 8000 Hex). In such a
scenario you may want to alter the Priority component of the higher performance bridge to
ensure that it becomes root for the segment (or overall root). Remember, if Priority
components are equal, the bridge on the segment with the lowest MAC address would
have a better chance of being selected as the root bridgeÑas it would have a lower Bridge
IdentiÞer. If your bridges come from multiple vendors, they will have different MAC
address values (e.g., Cabletron devices have a lower MAC address than 3Com devices); if
they come from the same vendor, the bridge with the earlier manufacture date will have the
lower MAC address value.
TIP
Root Bridge
Displays the MAC address of the bridge that is currently functioning as the Root
Bridge.
Root Cost
Indicates the cost of the data path from this bridge to the Root Bridge. Each port
on each bridge adds a ÒcostÓ to a particular path that a frame must travel. For
example, if each port in a particular path has a Path Cost of 1, the Root Cost
would be a count of the number of bridges along the path. (You can edit the Path
Cost of bridge ports as described later.) The Root BridgeÕs Root Cost is 0.
Root Port
This Þeld displays the identiÞer (the physical index number) of the device bridge
port that has the lowest cost path to the Root Bridge on the network. If the device
is currently the Root Bridge, this Þeld will read 0.
Protocol
Displays the Spanning Tree Algorithm Protocol type the device is currently using.
The choices are:
¥
¥
¥
802.1
DEC (DEC Lanbridge 100)
None
The following four Þelds display values used for various Spanning Tree timers
that are set at the Root Bridge and this bridge. In Spanning Tree operations, the
value used for the tree is the one set at the Root Bridge (with the exception of
Hold Time, which is a Þxed value); but you can change the value for each bridge
on your network in the event that it becomes Root.
Bridge Spanning Tree
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Bridging
Hello Time
This parameter indicates, in seconds, the length of time the Root Bridge (or bridge
attempting to become the Root) waits before resending ConÞguration BPDUs.
The range for this Þeld is 1 to 10 seconds, with a default value of 2 seconds. The
Root Bridge sets the Hello Time.
Max Age
This parameter displays the bridgeÕs BPDU aging timer. This controls the
maximum time a BPDU can be retained by the bridge before it is discarded.
During normal operation, each bridge in the network receives a new
ConÞguration BPDU before the timer expires. If the timer expires before a
ConÞguration BPDU is received, it indicates that the former Root is no longer
active. The remaining bridges begin Spanning Tree operation to select a new Root.
The current Root Bridge on the network sets the Max Age time. The range for this
Þeld is 6 to 40 seconds, with a default value of 20 seconds.
Forwarding Delay
This parameter displays the time period which elapses between states while the
bridge is moving to the Forwarding state. For example, while moving from a
Blocking to a Forwarding state, the port Þrst moves from Blocking to Listening to
BPDU activity on the network, remains there for the Forward Delay period, then
moves to the Learning State (and remains in it for the Forward Delay period), and
Þnally moves into a Forwarding state. This timer is set by the Root Bridge. During
a topology change, the Forward Delay is also used as the Filtering Database
Aging Time, which ensures that the Filtering Database maintains current
topology information.
Hold Time
This parameter displays, in seconds, the minimum time that can elapse between
the transmission of ConÞguration BPDUs through a bridge port. The Hold Time
ensures that ConÞguration BPDUs are not transmitted too frequently through any
bridge port. Receiving a BPDU starts the Hold Timer. After the Hold Timer
expires, the port transmits its ConÞguration BPDU to send conÞguration
information to the Root. The Hold Time is a Þxed value, as speciÞed by the IEEE
802.1d speciÞcation.
Bridge Port Level Fields
The following Þelds are applicable to each bridge port on the device.
Priority
If two or more ports on the same bridge are connected to the same LAN segment,
they will receive the same Root ID/Root Cost/Bridge ID information in
ConÞguration BPDUs received at each port. In this case, the BPDUÕs Port ID
informationÑthe transmitting portÕs identiÞer and its manageable Priority
componentÑis used to determine which is the Designated Port for that segment.
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Bridging
A lower assigned value gives the port a higher Priority when BPDUs are
compared. The allowable range is 0ÑFF hexadecimal (0Ñ255 decimal); the
default is 80 hexadecimal.
Path Cost
Displays the cost that this port will contribute to the calculation of the overall
Root path cost in a ConÞguration BPDU transmitted by this bridge port. You can
lower a portÕs Path Cost to make the port more competitive in the selection of the
Designated PortÑfor example, you may want to assign a lower path cost to a port
on a higher performance bridge. The allowable range is 1 to 65,535.
Designated Cost
Displays the cost of the path to the Root Bridge of the Designated Port on the
LAN to which this port is attached. This cost is added to the Path Cost to test the
value of the Root Path Cost parameter received in ConÞguration BPDUs.
Designated Root
Displays the unique bridge identiÞer of the bridge that is assumed to be the Root
Bridge.
Designated Bridge
Displays the network address portion of the Bridge ID (MAC address/priority
component) for the bridge that is believed to be the Designated Bridge for the
LAN associated with this port.
The Designated Bridge ID, along with the Designated Port and Port IdentiÞer
parameters for the port, is used to determine whether this port should be the
Designated Port for the LAN to which it is attached. The Designated Bridge ID is
also used to test the value of the Bridge IdentiÞer parameter in received BPDUs.
Designated Port
Displays the network address portion of the Port ID (which includes a
manageable priority component) of the port believed to be the Designated Port
for the LAN associated with this port.
The Designated Port ID, along with the Designated Bridge and Port IdentiÞer
parameters for the port, is used to determine whether this port should be the
Designated Port for the LAN to which it is attached. Management also uses it to
determine the Bridged LAN topology.
Topology
This indicates how many times the bridgeÕs Topology Change ßag has been
changed since the device was last powered up or initialized. It also indicates the
time elapsed since the topology last changed. The Topology Change ßag
increments each time a bridge enters or leaves the network, or when the Root
Bridge ID changes.
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Bridging
Changing Bridge Spanning Tree Parameters
The Bridge Spanning Tree window allows you to update the following
parameters for your device bridge. When you have Þnished making changes to
the following individual parameters, you must click on
at the bottom of
the Spanning Tree window to write the changes to the device.
Any values you set at the bridge will cause a Topology Change ßag to be issued in the next
ConÞguration BPDUs it transmits. This will cause the bridged network to immediately
recalculate Spanning Tree and change topology accordingly.
NOTE
Changing Bridge Priority
To change the part of the bridge address that contains the identiÞer used in the
Spanning Tree Algorithm for priority comparisons:
1. Highlight the Bridge Priority field.
2. Enter the new identifier, in hexadecimal format; the allowed range is 0-FFFF
hexadecimal.
3. Click on
.
The selected Bridge Priority will be applied to the bridge (a lower number
indicates a higher priority in the root selection process).
Changing the Spanning Tree Algorithm Protocol Type
To change the type of protocol used in Spanning Tree:
1. Click the mouse on the appropriate option button: 802.1, DEC, or None.
2. Click on
.
The selected Spanning Tree Algorithm protocol type will be applied to the bridge.
If you selected None, the Spanning Tree Algorithm will be disabled (if it already
was enabled). If STA Protocol Type was changed from None to IEEE 802.1 or DEC,
you must restart the bridge for the newly selected STA protocol to be applied.
All bridges in a network must use the same Spanning Tree version. Mixing Spanning Tree
Algorithm protocols will cause an unstable network.
!
CAUTION
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Bridging
Changing Hello Time
If the bridge is the Root Bridge, or is attempting to become the Root, and you
want to change the length of time the bridge waits between sending conÞguration
BPDUs:
1. Highlight the Hello Time field, and type in a new value.
2. Click on
.
The IEEE 802.1d speciÞcation recommends that Hello Time = 2 seconds, with an
allowable range of 1 to 10 seconds.
Changing Max Age Time
If the device is the Root Bridge or attempting to become the Root, and you want to
change the maximum time that bridge protocol information will be kept before it
is discarded:
1. Highlight the Max Age field, and type in a new value.
2. Click on
.
The IEEE 802.1d speciÞcation recommends that Max Age = 20 seconds, with an
allowable range of 6 to 40 seconds.
Changing Forwarding Delay Time
If the device is the Root Bridge or attempting to become the Root, and you want to
change the time period the bridge will spend in the Listening state (e.g. either
listening to BPDU activity on the network while moving from the Blocking to the
Learning state or in the Learning state while the bridge is moving from the
Listening to the Forwarding state):
1. Highlight the Forwarding Delay field, and type in a new value.
2. Click on
.
The IEEE 802.1d speciÞcation recommends that Forward Delay = 15 seconds, with
an allowable range of 4 to 30 seconds.
To ensure proper operation of the Spanning Tree Algorithm, the IEEE 802.1d speciÞcation
recommends that you always observe the following relationship between Forwarding
Delay, Max Age, and Hello Time:
NOTE
2 x (Forwarding Delay - 1.0) > Max Age > 2 x (Hello Time +1.0)
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Bridging
Changing Port Priority
To change the part of the Port Priority used in priority comparisons:
1. If necessary, select the desired port by clicking the mouse to highlight the port
in the lower right quadrant of the window. The lower left quadrant of the
window will now allow you to edit parameters for the selected port.
2. Highlight the port Priority field, and enter the new priority identifier. Only valid
hexadecimal numbers (0 to FF) are allowed in this field. The default is 80
hexadecimal.
3. Click on
. The new port priority will be saved.
Changing Path Cost
To change the Path Cost:
1. If necessary, select the desired port by clicking the mouse to highlight the port
in the lower right quadrant of the window. The lower left quadrant of the
window will now allow you to edit parameters for the selected port.
2. Highlight the Path Cost field, and type in a new value from 1 to 65535 decimal
(default is 100 decimal).
3. Click on
.
The new path cost will be applied to the port.
Filtering Database
The Filtering Database, which makes up the IEEE 802.1 Source Address Table, is
used to determine which frames will be forwarded or Þltered across the deviceÕs
bridging ports.
During initialization, the bridge copies the contents of its Permanent Database to
the Filtering Database. Next, the bridge learns network addresses by entering the
source address and port association of each received packet into the Filtering
Database. When in the Forwarding state, the bridge examines each received
compares the destination address to the contents of the Filtering Database.
If the destination address is located on the network from which the packet was
received, the bridge Þlters (does not forward) the packet. If the destination
address is located on a different network, the bridge forwards the packet to the
appropriate network. If the destination address is not found in the Filtering
Database, the bridge forwards the packet to all networks. To keep Filtering
Database entries current, older entries are purged after a period of time, which is
called the Dynamic Aging Time.
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Bridging
The Filtering Database consists of two separate databases: the Static and the
Learned Databases.
The Static Database contains addresses that are entered by a network
administrator. You add these addresses directly to the database while the bridge is
powered up, or to the deviceÕs battery-backed RAM so that they are stored on
shutdown until the next power-up.
The Learned Database consists of addresses that accumulate as part of the
bridgeÕs learning process as it is up and running. These do not remain in the
Source Address Table when the system is shut down. The Learned Database also
contains the addresses that are in the Static Database upon start-up of the bridge.
Entries to the Source Address Table are one of four types: Permanent, Static,
Dynamic, or Learned.
¥
Permanent entries are addresses that you add to the Static Database (via the
Filtering Database window) that are stored in the deviceÕs battery-backed
RAM. Since they remain in the device on shutdown or restart, they are
considered ÒPermanent.Ó
¥
¥
Static entries are addresses that you add to the Static Database (via the
Filtering Database window). These entries remain in the device until it is shut
down.
Dynamic entries are addresses that you add to the Static Database (via the
Filtering Database window). With the Aging Time feature, you set the time
period that these addresses are saved in the Source Address Table. Addresses
that have not transmitted a packet during one complete cycle of the aging
timer are deleted from the database.
¥
Learned entries are addresses that are added to the Learned Database through
the bridgeÕs learning process. With the Aging Time feature, you set the time
period that these addresses are saved in the Source Address Table. Addresses
which are inactive within a cycle of the aging timer are dropped from the
database.
Learned address entries are divided into two types, Learned and Self.Address
entries classiÞed as Learned have transmitted frames destined for a device
attached to a device portÕs connected segment. Address entries classiÞed as
Self are those that have sent a frame with a destination address of one of the
deviceÕs bridging ports.
number of entries of each type: Permanent, Static, Dynamic, or Learned.
Even though new entries into the Filtering Database are added as Static entries by
default, note that some devices, including the FN100, do not support Static entries. For
these devices, once you add an entry into the Filtering Database, it must be changed to a
Permanent type before clicking on OK to apply the change. If the entry is not changed to
a Permanent type before clicking on OK, you will receive a Set Failed message.
NOTE
Filtering Database
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Bridging
A scrollable Address Entry panel allows you to:
¥
¥
¥
View the address entries in the Filtering Database.
Alter an entryÕs type (e.g., from Learned to Permanent, Dynamic, or Static).
View and conÞgure the bridging action taking place on the packets entering
each of the bridging ports.
In addition, you can use buttons to add individual addresses to, or delete them
from, these databases, or clear all Permanent, Static, or Dynamic entries in the
database.
To access the Filtering Database window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select Filtering Database…. The Filtering Database window,
Figure 4-11, will appear.
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to Filtering Database…. The Filtering Database window,
Figure 4-11, will appear.
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Bridging
Figure 4-11. The Filtering Database Window
Filtering Database Window Fields
The following Þelds are listed in the top portion of the Filtering Database
window.
List
The List checkboxes indicate whether the associated entry type (Permanent,
Static, Dynamic, or Learned) will be displayed in the scrollable table of address
entries. A check next to the entry type indicates that it will be displayed.
Type
Indicates the type of entry in the database.
Number
Displays the current number of Permanent, Static, Dynamic, and Learned
Address entries.
Capacity
Indicates the total capacity of each entry type in the Static and Learned databases.
Filtering Database
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Bridging
Aging Time
Indicates the length of time, in seconds, that Dynamic and Learned Addresses in
the Source Address Table are allowed to remain inactive before they are dropped
from the database. The allowable time range for these entries is 10 to 1,000,000
seconds. Aging time is not applicable to Static or Permanent entries. You can
conÞgure this Þeld, as described in the next section.
The following Þelds are applicable to the scrollable Address Entry panel of
Filtering Database entries.
Address
Lists the addresses for which the bridgeÕs Filtering Database has forwarding
and/or Þltering information.
Type
Indicates the type of an entry in the database. The possible types are Static,
Dynamic, Learned, Self, or Permanent. You can alter the entry type, as described
in the next section.
Source Port
Indicates the port number on which the address entry was Þrst detected. A
question mark (?) indicates that the address entry was not a learned entry, but
Port Filtering information applies to it (i.e., the entry is a created Permanent,
Dynamic, or Static entry and has corresponding Þltering information).
Receive Port
Indicates the number of the port on which a frame must be received in order for
the entryÕs Port Filtering information to apply. An asterisk ( ) indicates that the
*
receive port is promiscuous, and applies to all ports of the bridge (assuming no
conßicting entry applies). You can change the receive port, as described in the
following section.
Port Filtering
Indicates the action that will take place at each bridge port when it receives
frames from the selected address entry. A green arrow indicates that the frames
received from the address will be forwarded to the portÕs associated segment
(
). A red circle indicates that frames will be Þltered (blocked) from the portÕs
associated segment ( ). You can change the Port Filtering action, as described
in the next section. (Note that port Þltering is scrollable among all the potential
ports; however, only two consecutive ports can be viewed simultaneously.)
Configuring the Filtering Database
You can conÞgure the Filtering Database by:
¥
¥
Altering the Aging Time for Dynamic and Learned entries.
Changing the type of entry with the Type buttons.
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Bridging
¥
¥
¥
¥
Changing the Receive port for the Þlter.
Changing the Port Filtering action at each bridge port.
Adding or deleting individual Filtering Database entries.
Clearing all Permanent, Static, or Dynamic entries from the Filtering Database.
Note that although conÞguration changes will appear in the window, no action
actually takes place in the bridgeÕs Filtering Database until you click on the OK
button in the bottom right of the window. This saves the new conÞguration.
When you reconÞgure the Filtering Database and click OK, the screen will clear
temporarily and a message will appear to indicate that the information is being updated.
When the changes have been successfully set and the Filtering Database has updated, the
screen information will be refreshed.
NOTE
If you change the window without clicking on OK, then attempt to exit the
window by clicking on Cancel, a text box will appear stating ÒChanges have been
made. Cancel them?Ó. Click on Yes to exit the window without changing the
Filtering Database, or select No to return to the window.
Altering the Aging Time
To alter the Aging Time for Dynamic and Learned entries:
1. Highlight the Aging Time field with the cursor.
2. Type in the new Aging Time (allowable range is 10 to 1,000,000 seconds).
Note that the Filtering Database Aging Time is the same as the Aging Time displayed
(and conÞgured) via the Port X Source Addresses window. Setting the Aging Time in the
Filtering Database window also changes the time in the Source Addresses window, and
vice versa.
NOTE
Changing the Type of Entry
You can change any entry type from its current type (Learned, Self, Permanent,
Static, or Dynamic) to either a Permanent, Static, or Dynamic entry. To do so:
1. Click on the shadowed Type button. A menu will appear with the three types
to which the entry can be changed.
2. Highlight the desired type.
Filtering Database
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Bridging
Changing the Receive Port
You can change the Receive port of an address entry in the scrollable panel, so
that a frame must be received at the speciÞed port for the Þltering action to apply.
To do so, click on the Receive port in the panel. With each click, the Receive port
will cycle to the next port (e.g., from (promiscuous), to 1, to 2, to 3, to 4, to 5, up
*
to 32, back to ).
*
Changing the Port Filtering Action
You can change the Port Filtering action at each bridge port from its current action
to the opposing action.
1. Maneuver the scroll bar until the desired port is in the Port Filtering panel.
2. Click on the port to alter its filtering action from forwarding frames from the
associated address (
), to filtering frames (
) (or vice versa).
Adding or Deleting Individual Entries
You can add or delete entries individually from the Filtering Database.
To add an address:
1. Click on the New button in the lower left of the window. A window
Figure 4-12. Filter DatabaseÑNew Filter Window
2. In the Filter Address field, type in the address (Hex format) for which you
desire bridging. Be sure to add “-” as a separator between each byte in the
address.
3. In the Receive Port field, type in the port at which the address must be
detected for bridging to take place. If you enter a value of 0 in this field, the
Receive Port is considered promiscuous (i.e., any port), and will be
designated by an “ in the Address Entry panel.
*”
4. Click on
.
5. Specify the Port Filtering action on the address entry as described in the
previous section.
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Bridging
To delete an address:
1. Click to highlight the address entry in the Address Entry panel that you wish to
delete from the filtering database.
2. Click on
.
Clearing All Permanent, Static, or Dynamic Entries
To erase all Permanent, Static, or Dynamic entries from the Filtering Database,
click on the associated button in the upper portion of the window.
Ethernet and Token Ring Special Filter Databases
While the Filtering Database deÞnes Þlters for all packets from a particular source
address, the Ethernet Special Filter Database and the Token Ring Special Filtering
Databases allow you to Þlter packets through an Ethernet or a Token Ring bridge,
respectively, using a special Þltering scheme.
When a packet is received at an Ethernet bridging interface, it is Þrst checked
against the Ethernet Special Filter Database to see if any Þltering action applies to
it. Because of this, an entry in the Ethernet Special Filter Database takes
precedence over a Þlter entry in the Filtering Database that would otherwise
apply to the packet.
The Ethernet Special Filter Database allows you to:
¥
DeÞne and save a Þlter based on a combination of SourceAddress, Destination
Address, Ethernet Data Type and Data (including the offset).
¥
¥
Specify the receive ports at which the Þlter will take effect.
Specify the forwarding/Þltering action at each bridging port of the device.
When checking for Transparent Þltering information, the bridge Þrst checks the
Token Ring Special Filter Database to see if any Þltering action applies to it.
Because of this, a Þlter entry in the Token Ring Special Filter Database takes
precedence over a Þlter entry in the Filtering Database that would otherwise
apply to the packet.
Looking at each enabled Þlter, starting with the lowest numbered Þlter, the bridge
compares the following Þelds to the corresponding Þelds in the received packet:
¥
¥
¥
¥
Destination address
Source address
Ethernet or Token Ring data type
Up to 16 hex integers (64 bytes) of the data Þeld
In addition, a Þlter can also specify at which port or ports the packet must be
received for the Þlter to be applicable. If a received packet matches all the contents
of an enabled Þlter, the bridge forwards the packet to the deÞned set of ports.
Ethernet and Token Ring Special Filter Databases
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Bridging
Filters provide broad conÞguration ßexibility. For example, you can deÞne
multiple scenarios for a single Þlter by specifying different combinations of
receive port/destination port. You can use wildcard characters in Þlter Þelds to
force a match with particular bits of the received packetÕs destination address,
source address, type, or data. You can specify an offset for the data Þeld, to specify
the starting point in the data where the bridge looks for the match. For entries that
donÕt match any of the enabled Þlters, you can conÞgure the bridge to Þlter or
forward the entry or pass the Þlter/forward decision to the Filtering Database.
Ethernet Special Filter Database Window
the special Þlters for the selected bridge. There are 19 available Þlters in the
Special Filter Database. You can not add any additional Þlters. You can view Þve
of these Þlters at a time in the Special Filter Database window. Use the scroll bars
to view the other fourteen Þlters.
the following page; Þlters 2 through 5 are undeÞned.) For each Þeld, bytes will be
initialized with Òmatch-anyÓ characters (xx) for each digit. Any hexadecimal byte
will be accepted as valid for the corresponding wildcard (xx) characters. For
example, a Source Address Þlter deÞned as Òxx-xx-xx-xx-bf-coÓ will pass the Þrst
four bytes of a frameÕs source address unconditionally, but the last two bytes must
match the Òbf-coÓ Þlter.
To access the Ethernet Special Filter Database window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select Ethernet Special Filter Database…. The Ethernet
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to select Ethernet Special Filter Database…. The Ethernet
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Bridging
Figure 4-13. Ethernet Special Filter Database Window
Token Ring Special Filter Database Window
of the special Þlters for the selected bridge. There are 19 available Þlters in the
Token Ring Special Filter Database. You can not add any additional Þlters. You
can view Þve of these Þlters at a time in the Token Ring Special Filter Database
window. Use the scroll bars to view the other fourteen Þlters.
When you Þrst open the window, all Þlters will be undeÞned. For each Þeld, bytes
will be initialized with match any characters (xx) for each digit. Any hexadecimal
byte will be accepted as valid for the corresponding wildcard (xx) characters. For
example, a Source Address Þlter deÞned as Òxx-xx-xx-xx-bf-coÓ will pass the Þrst
four bytes of a frameÕs source address unconditionally, but the last two bytes must
match the Òbf-coÓ Þlter.
To access the Token Ring Special Filter Database window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select Token Ring Special Filter Database…. The Token Ring
Ethernet and Token Ring Special Filter Databases
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Bridging
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to select Token Ring Special Filter Database…. The Token Ring
Figure 4-14. Token Ring Special Filter Database Window
Special Filter Database Window Fields
File
An X in this checkbox indicates that the Þlter is associated with the Þle name
shown in the title bar of the window. If a Þle has not yet been saved, the title bar
will not display any Þlter name. A saved Þle name is only displayed in the title
bar after you have opened a saved Þlter Þle or saved your current Þlters.
Enable
A Þlled-in circle indicates the Þlter is enabled.
Destination Address
Displays a six-byte hexadecimal Þeld for the Þlter which can be used to mask out
Destination Addresses.
Source Address
Displays a six-byte hexadecimal Þeld for the Þlter which can be used to mask out
Source Addresses.
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Bridging
Data Type
Displays the hexadecimal two-byte Þeld for the Þlter which can be used to mask
out a speciÞed protocol type Þeld. Examples of protocol type are:
¥
¥
¥
¥
0800 = IP
8137 = Novell
0bad = Banyan
80f3 = AppletalkARP
Data Offset
Indicates the offset (in bytes, from the beginning of the data in the packet) where
the Data Mask will be applied. The default for this Þeld is 0000 (no data offset).
An example of a valid offset to enter into this Þeld is 0016 (16 bytes).
Data Mask
Displays the 64-byte overlay used to Þlter packets. The Data Mask is applied to
the packet after the Þxed part of the packet, which includes Source Address,
Destination Address, and Type Þelds. The Þlter applies the mask directly at the
start of the data portion of the packet unless there is a Data Offset. If a Data Offset
has been deÞned, the mask will apply to the data that comes after the speciÞed
offset in the packet.
Receive Port(s)
Indicates the ports at which the packet must be received for Þltering information
to be applied. Note that you can only immediately see one receive port per Þlter,
even though you can set more than one receive port for the Þltering action to
apply. The receive port Þeld can display each device bridge port, BRIM port, or
Ò Ó. The Ò Ó indicates that a packet can be received at any port for the Þlter to
*
*
apply (i.e., the port is promiscuous).
Port Filtering
forwarding
Indicates the forwarding/blocking information for the
Þlter at each port on the device. Note that you can only
view two ports at a time.
blocking
Use the scroll bar at the top of the column to view the
hidden ports.
Selected Filter
This Þeld, visible at the bottom of the window, displays the number of the Þlter
that is currently highlighted. The possible range is from 01-19.
Defining and Editing Filters in the Special Database
You can edit an existing Þlter or deÞne a new Þlter using the following steps:
1. Click to select the filter you wish to edit. (The filter is selected when it is
highlighted. When the bridge uses the Special Database, it starts with the
lowest numbered enabled filter.)
Ethernet and Token Ring Special Filter Databases
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Bridging
2. Click
with the following fields:
•
•
•
•
•
Destination Address (six-byte hexadecimal field)
Source Address (six-byte hexadecimal field)
Type (two-byte hexadecimal field)
Data Offset (decimal field)
Data Mask (64-byte hexadecimal data mask)
Figure 4-15. The Special Database Filter Window
3. If you are editing an existing filter, the fields will reflect the current
configuration. A filter that has not yet been defined will have wildcards in every
field.
If you want to completely reconfigure an existing filter, click on
will revert all the fields to all xx’s.
. This
4. Highlight the field which you want to define, and enter the appropriate
information.
5. When you have finished defining the filter, click on
. This will save the
filter you created and return you to the Special Filter Database window, where
the configured filter will be displayed.
If you do not wish to save what you have entered in the Special Database Filter Window,
click on the Cancel button. This will cancel what you have entered into this window and
return you to the Ethernet Special Filter Database window.
NOTE
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Bridging
6. Click on
to save the changes you have made and exit the Special
Database Filter window.
Changing the Receive Ports
You can set the receive ports in the Special Filter Database window either before
or after you deÞne a Þlter. These are the ports at which the frame must be received
for the Þltering parameters to apply. The default selection is Port 1.
To designate a receive port, click on the receive port icon ( ) for the Þlter. As you
click on the icon, it will cycle though the ports (e.g., 1, 2, 3, 4, etc. until the end of
the interface table, and Ò Ó). When you have selected a port, you can set the port
*
Þltering action that will apply when the packet is received at that particular port
(refer to the following section for further information).
In this fashion, you can specify all receive ports at which the packet must be
received and the designated Þltering action which will apply when the packet is
received at each port. Selecting Ò Ó (promiscuous or any port) will apply the Þlter
*
and its speciÞed Þltering action to all ports on the device.
Remember that you can only view a single receive port and its Þltering action. To
check all receive ports for a single Þlter, you must click on the receive port icon to
cycle through the series of ports.
Changing the Port Filtering Action
Use the port icons under the Port Filtering section of the Special Filter Database
window to determine the port Þltering action associated with the Þlter when it is
received at a speciÞed receive port. You can select the port Þltering action either
before or after deÞning the Þlter. By default, the Þltering action is initially not set
at any port. You must click on a port to invoke the Þltering action symbols. After
the Þrst port is set (either to Þltering or blocking), the remaining ports in the Þlter
are set to blocking until you specify otherwise.
Setting the Port Filtering Action
When you set the port Þltering action for a Þlter, you determine whether the port
will block or forward packets which match the ÞlterÕs speciÞcations. To set port
Þltering action, click on the desired port icon (e.g., 1, 2, 3, 4, 5, 6, up to 32) to toggle
from blocking (
) to forwarding (
) or vice versa.
You can set the port Þltering action for the bridging port on each port of the
device, as well any BRIM ports.
Ethernet and Token Ring Special Filter Databases
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Bridging
Clearing the Port Filtering Action
When you clear the port Þltering action of a Þlter, all ports that were conÞgured to
forwarding or blocking will be reset to no action. Note that when you clear port
Þltering for a Þlter, the Þltering or blocking action will be simultaneously cleared
at all of its receive ports.
In order to clear the port Þltering action, use the following steps.
1. Click to select the filter whose port filtering action you would like to disable.
2. Click on
. This will clear the port filtering action for the
selected filter at all of its receive ports.The port filtering symbols will appear in
cleared mode.
Enabling and Disabling a Filter
To determine if a Þlter is enabled, check the Enable radio button.
To enable a Þlter:
1. Click on the empty Enable radio button. When the radio button is filled ( ),
the filter is enabled.
To disable a Þlter:
1. Click on the filled Enable radio button. When the radio button is empty ( ),
the filter is disabled.
Saving a Set of Filters to a File
When you have deÞned a set of Þlters, you can save that set to a Þle. This allows
you to conveniently recall a series of Þlters when the need arises.
To save a set of Þlters:
1. Make sure that all filters that you want contained in the set have the File
checkbox checked.
2. Click on
. A menu will appear.
3. Click on Save As…. A standard Microsoft Windows Save File window will
appear.
4. In the File name field, specify the file name and file path in which you want to
save the filter series.
5. Click on OK. The file will be saved as indicated.
To update the file while it is still open, click on the Save selection from the
Filters pull-down menu.
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Bridging
To open an existing Þle containing a Þlter set:
1. Click on . A menu will appear.
2. Click on Open…. A standard Microsoft Windows Open File window will
appear.
3. To specify the file:
•
•
In the File name field, specify the file to open by path and name, or
Use the Look in drop-down list box and associated file list to select the
desired file, and click to highlight it.
4. Click on Open.
The Þlters will appear in the Special Filter Database window, with all parameters
(File, Enable, Source and Destination Address, Data Type and Offset, Data Mask,
Receive Port, and Port Filtering Action) displayed as they were conÞgured at the
last Þle save.
Source Route Configuration
With the Source Route ConÞguration window, you can view address and routing
information, and set source route bridging parameters for bridging interfaces.
To access the Source Route ConÞguration window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select Source Route Configuration…. The Source Route
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select Source Route Configuration…. The Source Route
Source Route Configuration
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Bridging
Figure 4-16. Source Route ConÞguration Window
Information on Source Routing
Source Routing is a bridging technique developed by IBM and the 802.5 standards
committee in which a bridge routes frames based on the contents of their media
access control frame header, rather than by maintaining a Þltering database to
determine whether a packet should be forwarded or Þltered. Source Routing
functions as follows:
¥
An end point station transmits discovery (explorer) frames to a particular
destination address in order to seek the best route through a bridged topology
to that node. These frames are broadcast over the entire network.
In a network topology with parallel bridges, multiple paths may be available
to the same destination. In this case, the explorer frame may be further deÞned
as:
-
All Routes Explorer, so that all possible routes to the destination are
recorded, and multiple explorer frames can reach the same segment.
-
Spanning Tree Explorer (also known as Single Route Broadcast), so that
only one path is possible to a segment (i.e., through a designated bridge in
a Spanning Tree topology), and only one explorer frame will be forwarded
onto each segment. The Spanning Tree can be conÞgured either
automatically (i.e., by algorithm) or manually.
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Bridging
¥
When a source routing bridge processes the explorer frame, it adds a unique
identiÞer to the frame in a reserved portion of the frame. This identiÞes the
segment the frame was received from, followed by the speciÞc bridge, and
Þnally the segment it was forwarded onto.
¥
¥
¥
When the discovery frame (or frames if more than one route is possible)
reaches its destination, it contains a complete record of bridge hops on its
route.
The destination address then returns All Routes Explorer (using speciÞcally
routed frames) and Single Route (spanning tree) Explorer frames (using All
Routes Broadcast frames), to the source address.
The source station selects one path from the returned explorer frames, and
includes that path speciÞcation (with bridge and segment identiÞers) in
subsequent transmissions to that particular destination.
All bridges in the topology then examine the routing information Þeld of a
speciÞcally source routed frame and either forward it if there is a match in the
routing informationÑor if it is an All Routes explorer frameÑor discard it.
The Source Route Configuration Window
The Source Route ConÞguration window allows you to view IP address and
routing information, and to view and set source route bridging parameters for
any bridging device which supports this menu option.
It is recommended that the device be restarted when changes are made that affect source
route bridging in order to clear the buffers, but you do not need to restart for the changes
to take effect.
NOTE
Source Route Configuration Fields
IP Address
This Þeld displays the Internet Protocol (IP) address, which acts as a logical
identiÞer on the network, currently assigned to each port on the device. This is
needed for SNMP network management capability. The IP address is expressed in
dotted decimal notation (four decimal values between 0 and 255, separated by a
period, e.g., 255.255.255.255).
This Þeld can only be edited (with the correct security access) via Local
Management for the device (or the MIBTools utility). Refer to the appropriate
device-speciÞc UserÕs Guide for more information.
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Bridging
Subnet Mask
A subnet mask is used by a device to determine whether a destination address
exists within its own subnetwork (logical division of the network by router or
gateway) and can be reached directly, or whether it is unknown and therefore
must be delivered to a router (as speciÞed by the deviceÕs IP routing table or
default gateway address).
A subnet mask should be set at the device if it will issue SNMP traps in a routed
environment, so that the trap messages it generates will be routed correctly.
A subnet mask acts as a Þlter for destination IP addresses. It is a 32-bit quantity in
which all bits that correspond to the network portion (both site and subnet
identifying bits) of the deviceÕs IP address are set to 1, and all bits that correspond
to the host portion are set to 0.
The device will logically AND a destination trap IP address with the subnet mask
to determine which portion of the address identiÞes the network/subnetwork.
The device then compares the result on a bit-to-bit basis with the network
identifying bits in its own IP address. If the network portions match, the bridging
device transmits the trap onto its subnetwork. If they do not match, the device
transmits the trap through a router or gateway.
This Þeld can only be edited (with the correct security access) via Local
Management for the device (or the MIBTools utility). Refer to the appropriate
device-speciÞc UserÕs Guide for more information.
MAC Address
This Þeld displays the Media Access Control (MAC) layer address which
identiÞes the ports/interfaces of the bridging device on a network. This six-byte
address is set at the factory and is unique to each interface. Each byte is identiÞed
in bit order starting with the most signiÞcant bit. You cannot conÞgure this Þeld.
The following Þelds apply to the Source Route ConÞguration window:
Local Segment
This Þeld displays the unique segment number that identiÞes the segment
attached to the selected interface (either of the Token Ring or FDDI interfaces).
The bridge adds the Local Segment number to the routing information Þeld of
source route discovery frames. Valid values range from 0 to 4095.
Target Segment
This Þeld displays the unique segment number of the target segment that the
source routed frame will be forwarded to. Valid values range from 0 to 4095.
Hop Count Limit
The maximum number of routing descriptors (i.e., bridge hops) allowed for an All
Routes Explorer or a Spanning Tree Explorer frame received by the device. This
will reduce the unnecessary propagation of explorer frames through the network.
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Bridging
You can use the Set button at the bottom of the window to change the Hop Count
The permissible value for this Þeld is 0 to 28.
Spanning Tree Expl.
This read-only Þeld displays the action currently being applied to Spanning Tree
Explorer frames received by the indicated port. This Þeld will appear in one of
two ways:
¥
¥
If the Spanning Tree Mode for the bridge is set to Auto (as explained in the
following section), this Þeld will display the Spanning Tree Port State for the
indicated port.
If set to Auto, the device is subject to the Spanning Tree Algorithm. Each port
will treat incoming frames according to its current Spanning Tree bridging
state (i.e., Forwarding, Disabled, Listening, Learning, Blocking, or Broken).
If the Spanning Tree Mode is set to Manual (as explained in the following
section) this Þeld will display either Enabled or Disabled as the Spanning Tree
Port Enable State for the indicated port.
Bridge Number
The Bridge Number uniquely identiÞes a bridge port when more than one bridge
is used to span the same two segments. The Bridge Number should be in the
range of 0 to 15.
You can use the Set button at the bottom of the window to change the bridge
page 4-63. Current source routing protocols allow a range of 0 to 15 (0ÐF
hexadecimal) for the bridge number identiÞer. If no bridge number is assigned to
the device, a default value of 1 will appear in this Þeld.
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Bridging
Spanning Tree Mode
Indicates how a port on the device will behave with an incoming single-route
broadcast (Spanning Tree ExplorerÑSTE) frame. You can conÞgure this Þeld with
the radio buttons and checkboxes, or via the MIBTools utility or local
management.
This Þeld allows you to conÞgure a Spanning Tree for your network. You can set
the Spanning Tree Mode to Auto or Manual using the radio buttons. We
recommend that all bridges in your network topology have the same setting for
Spanning Tree Mode (i.e., all set to Auto or all set to Manual).
Auto
If the Spanning Tree Mode is set to Auto, a port that implements
the Spanning Tree Algorithm (STA), and is enabled and in the
forwarding state, will accept and relay STE frames onto its
attached segment.
Using STA, a bridge port will only forward frames if it is the
designated port for its attached segment. A port is ÒdesignatedÓ
for its segment if it has the lowest Root Path Cost of all bridge
ports attached to that segment. The Root Path Cost is the lowest
total path cost calculated by adding the costs of each port along
the path of a frame that traverses the bridge topology from the
root to that port (including its own path cost).
If two ports on a segment have equal Root Path Costs, the port on
the bridge with the highest priority bridge identiÞer (for
convenience sake, that have the lowest numerical value) will be
chosen as the root port.
You can affect Spanning Tree topology by changing the deviceÕs
bridge priority (Bridge Label) and path cost for its port pair (path
cost increment) via the Spanning Tree window (discussed in
earlier in this chapter).
Manual
If the Spanning Tree Mode is set to Manual, you can manually
conÞgure the bridge to forward STE frames (i.e., manually
establish a Spanning Tree for STE frames by determining which
bridge in a parallel series of bridges will forward these frames).
If you set the Spanning Tree Mode to Manual, you can use the Enable or Disable
checkboxes to set a portÕs Spanning Tree Enable State to:
-
-
Enabled (participating in frame relay).
Disabled (not participating in the bridging process or in operation of the
Spanning Tree Algorithm and protocol). If the Spanning Tree Mode is set
to Disabled, the bridge port will not send or accept any STE frames. Any
STE frame received will be discarded. The Spanning Tree Expl Þeld at the
ConÞguration window, and the STE Frames Þeld at the Status window
will both read ÒDisabled.Ó
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Making and Setting Changes
The Source Route ConÞguration window allows you to affect changes for the
following Source Route Bridging parameters: Bridge Number, Local Segment,
Target Segment, Hop Count Limit, and the deviceÕs Spanning Tree Mode.
To make a change to Bridge Number, Local Segment, Target Segment, or Hop
Count Limit, use the mouse to highlight the existing value in the desired Þeld,
and type in a new value.
To set the Spanning Tree Mode to Auto or Manual, click on the radio button next
to the appropriate selection. If set to Auto, a Spanning Tree Algorithm will
calculate the deviceÕs priority in a series of parallel bridges to determine a root
bridge on the network. If set to Manual, you conÞgure a Spanning Tree by
administratively enabling or disabling each bridging port on the network.
When the deviceÕs Spanning Tree Mode is set to Manual, you can change how a
bridge port will treat a Spanning Tree Explorer frame. Use the Enable checkbox to
allow STE frame forwarding at the port, or use the Disabled checkbox to prevent
STE frame forwarding at the port. Click on the Enabled or Disabled checkbox to
make your selection.
When you make changes in the Source Route ConÞguration window, they are not
implemented at the device until you click on the Set button. This will cause the
device to reboot. Since rebooting the device will bring it down for several
minutes, a ÒReset with new parameters?Ó pop-up dialog box will appear to
ensure that you are ready. Click on OK to accept the changes, or Cancel to return
to the Source Route ConÞguration window.
Using the Find Source Address Feature
You can select the Find Source Address option to discover which bridging
interface a speciÞed source MAC address is communicating through. When you
select the Find Source Address option, a search is made of the 802.1d Bridge
Filtering Database to discover the bridge interface associated with the address
that you specify. If the search is successful, the corresponding interface will ßash
in the Chassis View window. For more information on the Filtering Database,
Use the Find Source Address feature as follows:
1. Click to display the Device menu.
2. Drag to Find Source Address…. The following window will appear.
Using the Find Source Address Feature
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Figure 4-17. Find Source Address Window
3. In the text field in the middle of the window, enter a valid MAC address in
hexadecimal format and then click OK.
If the address is found in the 802.1d Bridge Filtering Database, the port through
which the address is communicating will ßash in the front panel Chassis View
display.
If the address is not found in the Filtering Database, a separate window will
appear with a ÒCanÕt Find Source AddressÓ message.
The Port Source Addresses Window
You can use the port-level Source Addresses window to view all the MAC
addresses that are communicating through a selected bridge interface.
To open the Source Addresses window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select Source Addressing…. The following window,
Figure 4-18, will appear.
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select Source Addressing…. The following window,
Figure 4-18, will appear.
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Figure 4-18. Port Source Addresses Window
The Port Source Addresses window displays the MAC addresses of all devices
that have transmitted packets that have been forwarded through the selected
bridging interface during the last cycle of the Filtering DatabaseÕs deÞned aging
timer (learned addresses that have not transmitted a packet during one complete
cycle of the aging timer are purged from the Source Address Table). For more
The aging time displayed in the Port Source Addresses window is the same as the aging
time displayed in the Filtering Database window. The aging time can be set from either
window, and any changes to its value will be reßected in both locations.
NOTE
Setting the Aging Time
The Filtering Database Aging Time is user-conÞgurable through the Device Aging
Time window.
To alter the Aging Time for Dynamic and Learned entries:
1. Click the I-bar cursor ( ) next to the Device Aging Time field. The Device
The Port Source Addresses Window
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Figure 4-19. Device Aging Time Window
2. Type in the new Aging Time, in seconds, then click on
. The allowable
range is 10 to 1000000 seconds; the default is 300 seconds.
Duplex Modes
Some of the bridge interfaces on a device will support Full Duplex Switched
Ethernet (FDSE) mode. Enabling full duplex mode on an interface allows the
interface to receive and transmit packets at the same time, effectively doubling the
available bandwidth.
On an Ethernet connection that is not using full duplex mode, the interface can
either transmit or receive packets. The interface has to wait for one activity to be
completed before switching to the next activity (receive or transmit).
Using the full duplex mode allows for faster transmission of packets over
Ethernet connections because the bridging interface can transmit and receive
packets; the interface does not have to wait for one activity to be completed before
switching to the next one.
Full Duplex should only be enabled on an interface that has a connection to a single
destination address at the other end of the connection (i.e., it is not a segment with an
attached repeater cascading the connection to multiple destination addresses).
WARNING
Full Duplex mode disables the collision detection circuitry at the interface, so that both
Transmit and Receive wires can be used simultaneously. With a single destination address
at the other end of the connection (for example, if the connection was to a full duplex
interface on another switching module, or if a single Þle server was connected to the full
duplex switch port), this essentially doubles the available bandwidth from 10 Mbit/sec to
20 Mbit/sec. Note that the interface at the other end of the connection must also have Full
Duplex enabled at the attached interface.
Full Duplex mode must be disabled if the interface is communicating with multiple
destinations simultaneously (i.e., if a repeater is cascaded from the interface), since
Ethernet relies on Collision Sense for proper operation.
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The Duplex Modes Window
The bridge-level Duplex Modes window allows you to enable and disable full
duplex mode capability for each bridging interface on your device. The window
lists each interface on the device and whether full duplex is ÒONÓ or ÒOFFÓ for
each interface.
To access the Duplex Modes window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select Duplex Modes…. The Duplex Modes window,
Figure 4-20, will appear.
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to select Duplex Modes…. The Duplex Modes window,
Figure 4-20, will appear.
Figure 4-20. Duplex Modes Window
Duplex Modes Window Fields
The following information is displayed in the Duplex Modes window:
Interface:
Lists the bridging interfaces available on the device (Interface 1, Interface 2, and
so on).
Duplex Modes
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Full Duplex
Displays the current state of full duplex on each interface. Possible values for this
Þeld are as follows:
Connect A
Indicates that the interface is connected to MMAC
Channel A and does not support full duplex mode
(Interface 1 only). You will not be able to change the
value of this Þeld from this window.
ON
Indicates that full duplex mode is being used on this
interface.
OFF
N/A
Indicates that full duplex mode is not being used on this
interface.
Indicates that full duplex mode is not available on this
interface.
Setting the Duplex Mode
You set an interface to use or not use Full Duplex Switched Ethernet by turning
the full duplex capability ON or OFF from this window.
To turn the full duplex mode ON or OFF:
1. In the Duplex Modes window, highlight the interface you want to change.
2. Double-click on the highlighted interface. The interface list will be briefly
grayed-out as the set is being made to the device.
If the set is successful, the interface list will reactivate and the Full Duplex:
indicator will switch from ON to OFF or OFF to ON.
If you attempt to set an interface to full duplex mode that does not support this
feature, you will receive a “Set Failed” error message.
Click on Cancel to close the window.
Because full duplex conÞguration takes place as you set each change individually, any
changes that have been completed up to the point of clicking on Cancel will have been set
at the device. Make sure that you have undone any unwanted changes before exiting the
window.
NOTE
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Ethernet Port Configuration Window
You can also conÞgure duplex modes from the Port ConÞguration window.
To access the Port ConÞguration window:
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select Configuration…. The Port Configuration window for the
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select Configuration…. The Port Configuration window for the
Figure 4-21. Port ConÞguration Window
This window will indicate which mode is being used on the interface, standard
mode or full duplex mode.
Standard Mode
Standard mode is being used on this interface. In standard mode, the interface can
transmit or receive packets. The interface has to wait for one activity to be
completed before switching to the next activity (receive or transmit).
Full Duplex
Full duplex mode is being used on this interface. In full duplex mode, the
interface receives and transmits packets at the same time.
Duplex Modes
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You set an interface to use standard or full duplex by selecting the appropriate
mode from this window. When you open the Port ConÞguration window the
currently used mode appears selected.
To change the mode from standard to full duplex mode or from full duplex to
standard mode, click in the radio button of the appropriate option and then click
on Apply. To cancel the action without applying any changes, click on Cancel.
Fast Ethernet Port Configuration
You can use the port-level Fast Ethernet ConÞguration window to manually
conÞgure 100Base-TX Fast Ethernet ports and FE100-TX Fast Ethernet Interface
Modules (FEPIMs) for 10Base-T and 100Base-TX full or half duplex operation.
You can also conÞgure them to auto-negotiate with the device at the other end of
the connection, based upon each deviceÕs Advertised and Remote Capabilities.
If you are monitoring a device with 100Base-FX Fast Ethernet ports, you can use
the Fast Ethernet ConÞguration window to manually conÞgure them to full or
half duplex operation. No auto-negotiation is available for the 100Base-FX ports,
and by extension, no Advertised or Remote capabilities.
From this window you can manually set the operational mode of the port,
determining the speed of the port (10 Mbps or 100 Mbps), and whether it uses full
duplex or standard mode bridging.
You can also set a 100Base-TX port to auto-negotiation so that the appropriate
operational mode can be determined automatically (using the Advertised
Abilities of the local interface that you determine, and the Remote Capabilities of
the Remote Link). The mode you set will determine the speed of the port and
whether it uses full duplex or standard mode bridging.
To access the Fast Ethernet ConÞguration window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select Configuration….The Fast Ethernet Configuration Port X
window (where X represents the port number of the selected interface),
Figure 4-22, will appear.
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select Configuration….The Fast Ethernet Configuration Port X
window (where X represents the port number of the selected interface),
Figure 4-22, will appear.
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Figure 4-22. Fast Ethernet ConÞguration Port X Window
From this window you can manually set the operational mode of the port, orÑfor
100Base-TX interfacesÑset the port to auto-negotiation so that the appropriate
operational mode can be determined automatically. The mode you set will
determine the speed of the port and whether it uses full duplex or standard mode
bridging.
The following information about the selected Fast Ethernet port is displayed:
Port Type
Displays the type of Fast Ethernet port: FE-100TX or FE-100FX.
Link State
Displays the connection status of the selected port: Link or No Link.
Current Operational Mode
Displays the mode that the port is operating in at the present time. Possible
operational modes include 10Base-T, 10Base-T Full Duplex, 100Base-TX,
100Base-TX Full Duplex, 100Base-FX or 100Base-FX Full Duplex.
If no current operational mode is returned, it indicates the port is operating under
auto-negotiation.
Fast Ethernet Port Configuration
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Desired Operational Mode
Displays the operational mode that you want to conÞgure for this port. The
following operational modes are available for each port:
FE-100TX
Auto-Negotiation, 10Base-T, 10Base-T Full Duplex,
100Base-TX, and 100Base-TX Full Duplex.
FE-100FX
100Base-FX and 100Base-FX Full Duplex
Desired Operational Mode for the FE-100FX, following, for more information.
Advertised Abilities
This Þeld works in conjunction with auto-negotiation on FE-100TX ports. During
auto-negotiation, the local hardware will advertise all selected modes in
descending bandwidth order: 100Base-TX Full Duplex, 100Base-TX, 10Base-T Full
Duplex, and 10Base-T.
Of the selected abilities, the highest mode available on the port on the other side
of the connection will automatically be used. The Advertised Abilities will only be
used when auto-negotiation is enabled.
Remote Capabilities
This Þeld displays the advertised abilities of the remote hardware at the other end
of the link from the FE-100TX port. Again, possible advertised abilities by the
remote partner include 10Base-T, 10Base-T Full Duplex, 100Base-TX, or
100Base-TX Full Duplex.
If auto-negotiation is not enabled or supported at either the local or remote
interface, or if there is no active link, all entries in this Þeld will be grayed out.
Auto-negotiation is not available on the FE-100FX; therefore, the Advertised Abilities
and Remote Capabilities section of the Fast Ethernet ConÞguration window will be
grayed out when you are viewing the port conÞguration of an FE-100FX.
NOTE
If you choose to select a speciÞc mode of operation (rather than auto-negotiation), you
should be sure that the link partner supports the same mode. Otherwise, no link will be
achieved.
!
CAUTION
If you select a full duplex mode and the link partner supports the same wire speed but not
full duplex, a link will be achieved, but it will be unstable and will behave erratically.
If you select auto-negotiation, the local node will try to match the mode of the link partner,
even if the link partner is not set to auto-negotiate, and even if the local node must use a
mode which it is not currently advertising.
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Setting the Desired Operational Mode for the FE-100TX
You can manually set the FE-100TX to use any one of four operational modes. You
can also set the port to auto-negotiation, which allows the port to determine for
itself the best operational mode using the Advertised Abilities and Remote
Capabilities of the local and remote interface, respectively.
If you want to manually conÞgure the mode:
1. Click on the Desired Operational Mode list-box, and select one of the
following modes:
•
•
•
•
10Base-T—10 Mbps connection, Standard Mode
10Base-T Full Duplex—10 Mbps connection, Duplex Mode
100Base-TX—100 Mbps connection, Standard Mode
100Base-TX Full Duplex—100 Mbps connection, Duplex Mode
2. Click on
. The mode that you have chosen will be set at the port.
If you want the port to use auto-negotiation:
1. Click on the Desired Operational Mode list-box and select Auto
Negotiation.
2. Click in the Advertised Abilities check boxes to select either 10Base-T,
10Base-T Full Duplex, 100Base-TX, or 100Base-TX Full Duplex.
3. Click on
.
When an active link is established, the operational mode will be dynamically
set based on the modes selected in the Advertised Abilities field and the
speeds and modes supported by the attached device; see the definition for
Setting the Desired Operational Mode for the FE-100FX
You can manually set the FE-100FX to use either of two operational modes:
1. Click on the Desired Operational Mode list-box, and select one of the
following modes:
•
•
100Base-FX—100 Mbps connection, Standard Mode
100Base-FX Full Duplex—100 Mbps connection, Duplex Mode
2. Click on
. The mode that you have chosen will be set at the port.
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SONET Port Configuration
The FE100-Sx series of Fast Ethernet Port Interface Modules and the APIM-2x
series of ATM Port Interface Modules provide SONET (Synchronous Optical
Network) access for some of CabletronÕs devices.
The FE100-Sx Port Interface Modules and the APIM-2x Port Interface Modules
link high-speed local or metropolitan area networks by using an OC-3 connection
(leased from your local telco or Internet service provider) to a SONET ring.
If your device is equipped with an FE100-Sx or an APIM-2x port interface
module, you can use the SONET/SDH ConÞguration window to set its operating
parameters, and the SONET/SDH Statistics window to view performance
information for the interface (which can tell you if your telco/service provider is
meeting any guarantees regarding network reliability).
SONET/SDH Configuration
The SONET/SDH ConÞguration window lets you determine whether your
FE-100Sx or APIM-2x port interface module will operate according to SONET or
SDH (Synchronous Digital Hierarchy) standards.
SONET is the ANSI (American National Standards Institute) standard for the
optical transport of data according to the transmission standards in effect in
North America (United States/Canada), Korea, Taiwan, and Hong Kong.
ANSI sets industry standards in the U.S. for the telecommunications industry,
among other industries.
The basic SONET building block signal (transmitted at 51.84 Mbps) is referred to
as STS-1 (Synchronous Transport Signal Level 1). SONET can multiplex (or
combine) STS-1 signals into STS-N signals, where N is some integer multiple of
STS-1 signals.
The ITU, or International Telecommunications Union (formerly known as the
CCITTÑthe Consultative Committee on International Telegraph and Telephone)
incorporated the SONET standard into its Synchronous Digital Hierarchy (SDH)
recommendations, which address differences between the European and North
American transmission standards. The ITU sets standards for international
communications (except for nations adhering to ANSI standards). SDH is a world
standard, and as such, the SONET standard is considered a subset within it.
The SDH transmission hierarchy uses the STM-1 (Synchronous Transfer Module
Level 1) as its basic building block signal (transmitted at 155.52 Mbps). Again,
there are STM-N signals, which are STM-1 signals that have been multiplexed into
a higher signaling rate.
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Table 4-1. SONET/SDH Transmission Hierarchies
SONET
Bit Rate
51.84 Mbps
SDH
STS-1/OC-1
Ñ
STS-3/OC-3 (supports
FE-100Sx and APIM-2x
in SONET operational
mode)
155.52 Mbps
STM-1 (supports
FE-100Sx and APIM-2x
in SDH operational
mode)
STS-12/OC-12
STS-24/OC-24
STS-48/OC-48
STS-192/OC-192
622.08 Mbps
1244.16 Mbps
2588.32 Mbps
9953.28 Mbps
STM-4
Ñ
STM-16
STM-64
You should be sure that the operational mode for both the local and remote ends
of the SONET connection is set appropriately for your region. Setting the wrong
operational mode may cause errors to be generated during transmission, since
there are slight differences in framing SONET and SDH signals.
To access the SONET/SDH ConÞguration window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select SONET/SDH Configuration…. The SONET/SDH
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select SONET/SDH Configuration…. The SONET/SDH
Figure 4-23. SONET/SDH ConÞguration Window
SONET Port Configuration
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To set the operational mode of the SONET port via the SONET/SDH
ConÞguration window:
1. Click in the radio box adjacent to the appropriate selection, SONET or SDH,
to choose the data transmission standard to be used by the interface.
2. Click on Apply to set your change at the interface, or Cancel to exit the
SONET/SDH Configuration window without applying any changes.
SONET/SDH Statistics Window
SONET/SDH statistics are available for each FE100-Sx or APIM-2x port interface
module installed in your device. The same statistics apply whether you have
conÞgured the interface to operate according to SONET or SDH transmission
standards.
The FE100-Sx and the APIM-2x port interface modules are SONET
path-terminating equipment (PTE). They act as an endpoint of an end-to-end
connection between themselves and another similar port interface module. As
endpoints, they are capable of generating and receiving the Path Overhead
information contained within the SPE (Synchronous Payload Envelope) of the
base-level SONET or SDH signals. Simply put, overhead is the extra bits in the
digital stream that relay information besides trafÞc signals.
The Path Overhead provides for end-to-end performance monitoring of the link,
the signal label (the content of the SPE, including status of mapped payloads), the
pathÕs current status, and path trace capabilities.
The SONET/SDH Statistics window enables you to view some of the error
information contained within the Path Overhead that your FE100-Sx or APIM-2x
is receiving from the remote endpoint.
The window will inform you whether there have been speciÞc defects
experienced on the SONET link, and if the network has experienced any
signiÞcant unavailability time as a result.
With a SONET link, there are three levels of error conditionsÑanomalies, defects,
and failures.
¥
Anomalies are small discrepancies between a desired and actual characteristic
of an item, which when occurring singly will not interrupt the ability of the
SONET network elements to perform their required functions.
¥
Defects indicate that anomalies have reached a level where the ability of the
SONET network elements to perform their required functions has been
interrupted. Defects are used in performance monitoring and in determining
the faultÕs cause, and have impact on consequent actions on the network.
¥
Failures indicate that a network element has been unable to perform its
required functions beyond a maximum time allocated to a given error
condition.
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These errors can occur in any of the four optical layers of a SONET network,
which are (in order from lowest to highest layer in the hierarchy) the physical
Medium, Section, Line, and Path layers.
¥
The Medium layer is the Photonic layer that physically converts electrical
signals to optical signals.
¥
The Section layer deals with the transport of frames across the optical
medium, including framing and scrambling data for transmission, the error
monitoring and maintenance between section-layer elements (such as signal
regenerators/repeaters), and orderwire (provisioning channels).
¥
¥
The Line layer is responsible for reliably transporting the higher-level Path
layer payload and overhead across the physical medium. It is responsible for
synchronizing (clocking) the data transmission, multiplexing signals into a
single channel, error monitoring and maintenance between line-layer
elements (such as Add/Drop Multiplexers), and switching to secondary data
paths should the primary path experience failure.
The Path layer transports services between path-terminating equipment.
It maps signals into a format required by the line layer, and reads, interprets,
and modiÞes path overhead for performance monitoring and automatic
protection switching.
Error reporting occurs at the Section, Line, and Path layers, and is carried within
the corresponding SONET overhead. In terms of the SONET protocol stack, the
three layers with overhead are mapped to the SONET link as shown in the
following diagram.
The statistics and errors indicators provided in the SONET/SDH statistics
window are taken from both the end-to-end Path layer, and from the Section layer
between the FE100-Sx or APIM-2x and the Add/Drop Multiplexer to which it is
connected. They reßect errors that may be occurring on your customer premises
equipment, as well as errors that may be occurring at the Line or Section layers
within the SONET MAN/WAN ring itself.
Line-
Line-
Regenerators
Path-
Terminating
Equipment—
Telco/SP ADM
(Add/Drop
Path-
Terminating
Equipment—
Telco/SPADM
(Add/Drop
Terminating
Equipment—
(FE100-Sx
or APIM-2x)
Terminating
Equipment—
(FE100-Sx
or APIM-2x)
OC-3c
link
OC-3c
link
Section
Line
Multiplexer)
Multiplexer)
Path
SONET Port Configuration
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To access the SONET/SDH Statistics window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select SONET/SDH Statistics…. The SONET/SDH Statistics
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select SONET/SDH Statistics…. The SONET/SDH Statistics
Figure 4-24. The SONET/SDH Statistics Window
Errors
The Errors indicators at the bottom of the SONET/SDH Statistics window show
the status of the SONET link as reported by the monitored interface, by indicating
whether the link has experienced Loss of Pointer, Loss of Signal, or Loss of
Frame defects or failures during the current 15-minute interval.
Note that Loss of Pointer is detected at the Path level on the SONET link, meaning
that the error occurred anywhere on the end-to-end link between the connected
FE100-Sx or APIM-2x devices that are customer premises equipment (CPE), and
Loss of Signal and Loss of Frame are detected at the Section level, meaning that
the error occurred on the SONET section between the monitored CPE device and
the ADM node (line-terminating equipmentÑLTE) to which it is connected.
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Note also that these indicators simply show which error conditions have been
detected during the last 15-minute interval; they do not alter the display of the
statistics above.
Loss of Pointer
SONET uses ÒpointersÓ to compensate for frequency and phase variations as data
is being transmitted across the optical network, so that data is not delayed or lost
on the network. Basically, a pointer is a data offset value that indicates where in
the frame that the ÒpayloadÓ (user data and path overhead) begins, so that it can
be differentiated from the Òtransport overheadÓ (the information in the frame
used for transporting it across the SONET network).
A Loss of Pointer (LOP) defect occurs when either a valid pointer is not detected
in eight consecutive SONET STS-N frames, or when eight consecutive frames are
detected with the New Data Flag (NDF) set without being validly combined into
an STS-N(c)Ña concatenated STS-N signalÑto carry a larger payload.
An LOP defect is cleared when three consecutive frames are detected with either a
valid pointer and a normal NDF, or a valid concatenation indicator. Note that
incoming Alarm Indicator Signals (which are alarm messages generated by the
line and section layers that are propagated along the path to indicate a loss of
signal condition on upstream network elements) cannot contribute to an LOP
defect.
A Loss of Pointer failure is declared when a defect condition persists for a period
of 2 to 3 seconds; the LOP failure is cleared when there is no defect condition
detected for 9.5 to 10.5 seconds
Loss of Signal
Incoming SONET signals are monitored for Loss of Signal (LOS) errors, which
indicate a loss of physical signal failure (either optical or electrical) at the source
(e.g., a laser failure) or in the transmission facility (e.g., a Þber cut). Loss of signal
is detected in the data (before scrambling) by an Òall zerosÓ pattern, which
indicates that there are no light pulses for OC-N optical interfaces (on the
line-terminating equipment or a regenerator), or no voltage transitions for STS-1
or STS-3 electrical interfaces (on path-terminating equipment, such as the
FE100-Sx or APIM-2x).
A state of no transitions that lasts 2.3 µs (microseconds) or less is insigniÞcant.
A state of no transitions that lasts between 2.3 µs and 100 µs is declared an LOS
defect. The LOS defect is cleared after a 125 µs interval (the time required to
transmit one frame on a SONET network) during which no LOS defect is
detected.
If the LOS defect persists for a period of 2 to 3 seconds, an LOS failure will be
declared, an alarm indicator will be set, and an alarm message will be sent to an
Operations Systems application (responsible for overseeing the entire network).
The LOS failure is cleared when the LOS defect is absent for a period of 9.5 to 10.5
seconds.
SONET Port Configuration
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Bridging
A Loss of Signal may also be detected if the received signal level (e.g., the
3
incoming optical power) falls below a Bit Error Rate (BER) threshold of 1 in 10 .
A BER is the number of coding violations detected in an interval of time (usually
3
one second). A predicted BER of 1 in 10 means that during each second, there is
an error ratio of 1 errored bit per 1,000 bits sent. This state clears when two
consecutive framing patterns are received, and no Òall zerosÓ LOS conditions are
detected in the intervening time (one frame).
Note that for path- or line-terminating SONET network elements, LOS failure
detection is also linked to the declaration or clearing of Loss of Frame (LOF)
failures (described below). If there was a previously existing LOF failure at the
time an LOS failure is declared, the LOF failure will be cleared; if an existing LOS
failure is cleared, but LOF failure conditions still exist, an LOF failure will be
immediately declared on clearing the LOS failure.
Loss of Frame
SONET frames uses A1 and A2 framing bytes in the section overhead to indicate
the beginning of the frame. An Out of Frame (OOF) alignment defect (also known
as a Severely Errored FrameÑSEFÑdefect) occurs when four consecutive SONET
frames are received with invalid patterns in these framing bytes. This defect is
cleared when two consecutive SONET frames are received with valid framing
patterns.
A Loss of Frame (LOF) defect occurs when this OOF/SEF defect persists for a
period of 3 milliseconds. This defect is cleared when the incoming signal remains
continuously in-frame for a period of 1 to 3 milliseconds.
An LOF failure is declared when an LOF defect persists for a period of 2 to 3
seconds (except when a Loss of Signal defect or failure is present, as described
above). An LOF failure is cleared if an LOS failure is declared, or when the LOF
defect is absent for 9.5 to 10.5 seconds.
Statistics
Statistics are given for both the Near-End and Far-End of the SONET/SDH path.
Far-end statistics are taken from the far-end block error code (FEBE)Ñused to
indicate that the remote entity at the far-end of the path has detected errored data
Ñwithin the Path Overhead of SONET frames.
You can view statistics for the current 15-minute interval, or accumulated over the
last one-, eight-, or 24-hour period by clicking on the appropriate selection button.
Errored Seconds
The counter associated with the number of Errored Seconds, or Far-End Errored
Seconds, encountered by a SONET/SDH Path in the speciÞed interval.
An Errored Second (ES) is a second with one or more coding violations (bit parity
errors) at the associated layer reported at the Section, Line, or Path layer of the
SONET link, or a second during which at least one or more incoming defects
(e.g., Loss of Signal, Loss of Pointer, or Loss of Frame) has occurred at that layer.
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Bridging
Coding Violations are Bit Interleaved Parity (BIP) errors that are detected in the
incoming signal (as described below).
Severely Errored Seconds
The number of Severely Errored Seconds, or Far-End Severely Errored Seconds,
encountered by a SONET/SDH Path in the speciÞed interval.
A Severely Errored Second (SES) is a second with X or more coding violations
(bit parity errors) reported at the Section, Line, or Path layer of the SONET link, or
a second during which at least one or more incoming defects (e.g., Loss of Signal,
Loss of Pointer, or Loss of Frame) has occurred at that layer. The statistic provided
in this Þeld is provided by the STS-Path level of the link.
Values of X at each layer depend on the linkÕs line rate and the Bit Error Rate. For
-7
the STS-Path layer, with a line rate of 51.84 Mbps (STS-1) and a BER of 1.5 x 10 ,
-7
X is 9; with a line rate of 155.52 Mbps (STS-3) and a BER of 1 x 10 , X is 16.
If the FE100-Sx or APIM-2x is experiencing consecutive Severely Errored Seconds,
it may indicate an impending period of network unavailability (which begins at
the onset of 10 consecutive SESs). Periods of unavailability can severely impact
service (e.g., the disconnection of switched services). Availability is restored at the
onset of 10 consecutive error-free seconds.
Severely Errored Framing Seconds
The counter associated with the number of Severely Errored Framing Seconds
encountered by a SONET/SDH Section in the speciÞed interval. A Severely
Errored Framing Second (SEFS) is a second containing one or more SEF events.
This counter is only counted at the Section Layer, and is not available as a Far-End
counter.
Code Violations
The number of Coding Violations (CVs) encountered by a SONET/SDH Path
interface, or the number of Far-End Coding Violations reported via the far-end
block error count to the monitored SONET/SDH Path interface, in the speciÞed
interval.
Coding Violations are Bit Interleaved Parity (BIP) transmission errors that are
detected in the incoming signal. Bit Interleaved Parity is a check at the receiving
interface that groups all bits in a block into a unit (e.g., a byte), then veriÞes the
block for parity for each bit position in the group by making sure that the number
of bits set to the value Ô1Õ is either even or odd, as reported by the transmitting
entity.
SONET Port Configuration
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Bridging
Configuring Broadcast Suppression
Excessive broadcasts to all ports, or broadcast storms, can result in severe
network performance problems, and possibly cause the network to crash. Devices
which support the broadcast suppression feature provide automatic protection
against broadcast/multicast storms.
In many ways, broadcast suppression is similar to Þltering. To protect against
storms, an acceptable rate for broadcast trafÞc across a port is deÞned. Ports
which reach this user-deÞned threshold will be throttled, and an SNMP trap
message will be sent to the network management station.
To access the Broadcast Suppression window:
1. Click on the Device menu from the Chassis View window of the selected
device.
2. Drag down to select Broadcast Suppression….The Broadcast Suppression
Figure 4-25. The Broadcast Suppression Window
In the Broadcast Suppression Window, each interface of the device that is being
monitored can be individually conÞgured for automatic broadcast/multicast
storm protection.
You can also deÞne what level of broadcasts the device will recognize as a
broadcast storm by specifying the number of broadcast packets that can be
transmitted within a given time period.
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Bridging
To conÞgure a port for broadcast storm protection:
1. Click to highlight the entry for the port you wish to configure for automatic
broadcast storm protection.
2. In theTime on Selected Ports field, enter the desired time period in seconds.
Note that a value of 0 will disable the threshold alarm.
3. In the Transmit (Frames Per Second) Threshold on Selected Ports field,
enter the number of broadcast packets that will be the threshold for the time
period set in Step 2.
4. Click Apply and your settings will be added to the window. Click Cancel to
close the window.
Token Ring Bridge Mode
The Token Ring Bridge Mode window allows you to choose between three
different modes of bridging on a deviceÕs Token Ring bridge port: Source Route
Transparent, Transparent, or Source Routing. The default setting is Source Route
Transparent.
To access the Token Ring Bridge Mode window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select Token Ring Bridge Mode…. The Token Ring Bridge
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to select Token Ring Bridge Mode…. The Token Ring Bridge
Token Ring Bridge Mode
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Figure 4-26. Token Ring Bridge Mode Window
Defining the Bridge Modes
Transparent
When the bridge is set to Transparent mode, the bridge will only transmit
transparent frames from the Token Ring connection. If a source route frame is
received by the bridge, the Source Route information in the frame will be dropped
from the packet. (A transparent frame is the same as a source route frame without
a RIFÑRouting Information Field.)
Source Routing
When the bridge is set to Source Routing mode, the bridge will only transmit
source route frames from the Token Ring connection.You should set the bridging
mode to Source Route when you are bridging from Ethernet to Token Ring. The
source route information (as conÞgured at the Ethernet portÕs Source Route
ConÞguration window) will be appended to the RIF for frames transmitted on
the Token Ring.
Source Route Transparent
When the bridge is set to Source Route Transparent, the bridge will transmit both
transparent and source route frames. The frames received which have source
route information will be transmitted as source route, while frames received that
are transparent will be transmitted as transparent.
Setting The Token Ring Bridge Mode
1. Click on the radio button next to the bridging mode you would like your Token
Ring bridge port to use:Transparent Bridge, Source Routing, or Source
Route Transparent.
2. Click on OK to close the window and set the bridge to the desired mode.
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Using the Physical View Windows
ETWMIM Ethernet Port Physical View
The Physical View allows you to view the physical state of the Ethernet port when
you are monitoring an ETWMIM via SPECTRUM Element Manager.
To use the Physical View option
from the Bridge Status window:
1. Click on the Ethernet bridge port (Port 1). The Ethernet bridge port pull-down
menu will appear.
2. Drag down to select Physical View…. The ETWMIM EtherPhysStatus
from the Chassis View window:
1. Click on the Ethernet bridge interface (Port 1). The Ethernet bridge port
pull-down menu will appear.
2. Drag down to select Physical View…. The ETWMIM EtherPhysStatus
Figure 4-27. Ethernet Port Physical View
Ethernet Port Physical Status Fields
Active Port
This Þeld will have an enabled check box next to the active port conÞguration
option you have selected for your ETWMIM Ethernet port.
¥
If you have conÞgured the ETWMIM for use with the Ethernet backplane
connection, the X will appear in the BackPlane checkbox.
Using the Physical View Windows
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Bridging
¥
If you have opted to use a front panel EPIM for your Ethernet connection, the
X will appear in the EPIM checkbox.
You cannot change your active port conÞguration from the window. It must be
changed physically on the ETWMIM itself.
Epim Type
This Þeld will show the type of EPIM you have installed via the front panel of
your ETWMIM, if applicable. The types of EPIMs are listed below, along with the
type of segment each will be connected to.
¥
¥
¥
¥
¥
¥
¥
EPIM-TÑ10BASE-T Twisted Pair Segment
EPIM-F1/F2ÑFiber Optic Link Segment
EPIM-F3ÑSingle Mode Fiber Optic Link Segment
EPIM-CÑThin-net segment
EPIM-AÑAUI cable segment
EPIM-XÑAUI cable segment
EPIM UnknownÑSPECTRUM Element Manager cannot determine the
EPIM Type.
¥
N/AÑThe backplane connection is being used.
Link State
This Þeld will display the link state of the EPIM Ethernet port. The possible
states are:
¥
¥
¥
LinkedÑindicates a link has been established on the EPIM.
UnlinkedÑindicates a link has not been established on the EPIM.
UnknownÑindicates the status of the EPIM link is unknown, or not valid for
the type of EPIM installed.
¥
N/AÑindicates that the backplane connection is being used.
ETWMIM Token Ring Port Physical View
The Physical View option allows you to view and conÞgure the physical set up of
the Token Ring port when you are monitoring an ETWMIM via SPECTRUM
Element Manager.
To use the Physical View option
from the Bridge Status window:
1. Click on the Token Ring bridge port (Port 2). The Token Ring bridge port
pull-down menu will appear.
2. Drag down to select Physical View…. The ETWMIM Token Ring Phys(ical)
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from the Chassis View window:
1. Click on the Token Ring bridge port (Port 2). The Token Ring bridge port
pull-down menu will appear.
2. Drag down to select Physical View…. The ETWMIM Token Ring Phys(ical)
Figure 4-28. Token Ring Port Physical View
Token Ring Physical Status Fields
Ring Speed
Displays the current ring speed conÞgured for your Token Ring port. You can
change the ring speed from this window by clicking on the radio button next to
the desired ring speed: 4 Megabits/second or 16 Megabits/second. When you
reconÞgure the ring speed, the new speed will appear in the text box in this Þeld.
Ring State
Displays the state of the ETWMIMÕs Token Ring MAU with respect to the ring.
When the ring is Òopen,Ó the Token Ring MAU is participating in the ring poll
process and is receiving and transmitting data onto the ring. When the ring is
Òclosed,Ó the MAU is removed from the ring, and data is not being transmitted or
received on the ring. You can change the ring state from this window by clicking
on the radio button next to the desired option: Open or Close. If you successfully
reconÞgure the ring state, the new state will appear in the text box in this Þeld.
Using the Physical View Windows
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Bridging
FNB State
The FNB State section displays, and lets you conÞgure, the state of the backplane
FNB connectors on the ETWMIM.
The right-hand side of the window displays the current connection conÞguration
for the FNB connectors on the ETWMIM, and lets you alter those options by using
the appropriate radio button selections:
¥
Connect Left indicates that the ETWMIM is/will be connected on the FNB to
the Þrst board to its left in the MMAC chassis with a valid right FNB
connection.
¥
¥
Disconnect Left indicates that the ETWMIM is/will be disconnected on the
FNB from any boards to its left in the MMAC chassis.
Connect Right indicates that the ETWMIM is/will be connected on the FNB
to the Þrst board to its right in the MMAC chassis with a valid left FNB
connection.
¥
¥
Disconnect Right indicates that the ETWMIM is/will be disconnected on the
FNB from any boards to its right in the MMAC chassis.
Enable Bypass indicates that the ETWMIM is/will be in bypass state. It will
not be connected to any boards on its left or right. In a shunting chassis, the
FNB will bypass the board to maintain the integrity of the ring across the
chassis.
¥
Disable Bypass indicates that the ETWMIM is/will be inserted into the FNB,
according to the established FNB connection options above.
The left-hand side of the window indicates the results of the current FNB
conÞguration, with an X next to the appropriate state of the FNB connection:
Connected Left, Connected Right, Bypassed, Right Connection Fault, or Left
Connection Fault. For example, if you choose Connect Right and Disconnect Left,
the Connected Right and Left Connect Fault Þelds will appear with an X next to
them.
Active Monitor
This Þeld allows you to conÞgure whether or not the ETWMIMÕs onboard
management station will engage in the active monitor contention process, which
occurs as part of the recovery procedures initiated after certain ring error
situations.
If you select Enable, the station will contend in the process used to establish a ring
station as an Active Monitor.
If you select Disable, the station will not contend, even if the contention process is
activated for the ring. Note that if the ETWMIM is currently serving as the active
monitor, it will continue in that role until the next contention.
The box to the left of the choices will reßect your actions by displaying On when
the Active Monitor has been enabled, and Off when the Active Monitor has been
disabled.
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Bridging
Using the Interface Configuration Window
The I/F ConÞguration port-level menu option invokes the Interface
ConÞguration window, which allows you to select a bridging method for a Token
Ring bridging interface. You can also make this selection via the Token Ring
information.
This window also allows you to select one of three transmission methods that
should be used when unknown addresses are received from end stations attached
to the selected bridge port.
To access the Interface ConÞguration window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select I/F Configuration…. The Interface Configuration
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select I/F Configuration…. The Interface Configuration
Using the Interface Configuration Window
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Figure 4-29. Interface ConÞguration Window
Defining the Bridge Method
Transparent
When the bridge is set to Transparent mode, the bridge will only transmit
transparent frames from the Token Ring connection. If a source route frame is
received by the bridge, the Source Route information in the frame will be dropped
from the packet. (A transparent frame is the same as a source route frame without
a RIFÑRouting Information Field.)
Source Routing
When the bridge is set to Source Routing mode, the bridge will only transmit
source route frames from the Token Ring connection.You should set the bridging
mode to Source Route when you are bridging from Ethernet to Token Ring. The
source route information (as conÞgured at the Ethernet portÕs Source Route
ConÞguration window) will be appended to the RIF for frames transmitted on
the Token Ring.
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Source Route Transparent
When the bridge is set to Source Route Transparent, the bridge will transmit both
transparent and source route frames. The frames received which have source
route information will be transmitted as source route, while frames received that
are transparent will be transmitted as transparent.
Setting the Bridge Method
1. Click on the radio button next to the bridging mode you would like your Token
Ring bridge port to use:Transparent Bridge, Source Routing, or Source
Route Transparent.
2. Click on Set to apply the desired mode.
Defining the Protocol Transmission
The choices in the Protocol Transmission for Unknown Address Þeld are deÞned
as follows:
TCP/IP
Determines whether IP frames received at the interface should be forwarded as a
transparent frame, source route frame, or both.
IPX
Determines whether IPX frames received at the interface should be forwarded as
a transparent frame, source route frame, or both.
NetBIOS
Determines whether NetBIOS frames received at the interface should be
forwarded as a transparent frame, source route frame, or both.
SNA
Determines whether SNA frames received at the interface should be forwarded as
a transparent frame, source route frame, or both.
Other
Determines whether frames of all other protocols not mentioned above (IP, IPX,
NetBIOS, and SNA) that are received at the interface should be forwarded as a
transparent frame, source route frame, or both.
If Transparent is selected, the frame is forwarded out of the bridge interface as a
transparent frame. If Source Route is selected, the frame is forwarded out of the
bridge interface as a source route frame. If Auto is selected, the frame is
forwarded out of the bridge interface as both a transparent frame and as a source
route frame.
Using the Interface Configuration Window
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Bridging
To select Transparent as the transmission method for TCP/IP, IPX, SNA, NetBIOS
or Other protocols:
1. Click on the radio button next to the transmission method you would like your
Token Ring bridge port to use:Transparent, Source Route, or Auto.
2. Click on Set to apply the desired mode.
Using the Bridge and Port Configuration Windows
The Bridge ConÞguration and the Port ConÞguration windows look similar and
are used for similar purposes, with the only exception being that the former
window is set at the device level, while the latter is set at the interface level.
The Bridge ConÞguration window provides a global capability to conÞgure all of
the Token Ring bridging interfaces on a device simultaneously as well as set the
bridge number and virtual ring number (target ring).
The Port ConÞguration window provides the capability to conÞgure individual
Token Ring bridging interfaces on a device. This window displays the
information that is set at the device level via the Bridge ConÞguration window,
such as the Bridge Number and the Virtual Ring NumberÑboth of which are
read-only Þelds in the Port ConÞguration window.
The Ring Number Þeld is the only Þeld that is not common to both windows,
because this value cannot be set globally on a device. It appears in the Port
ConÞguration window only, since the value assigned to this Þeld must be unique
to each interface.
To access the Bridge ConÞguration window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select Bridge Configuration…. The Bridge Configuration
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to select Bridge Configuration…. The Bridge Configuration
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Figure 4-30. Bridge ConÞguration Window
To access the Port ConÞguration window
from the Bridge Status window:
1. Click on the desired Port button ( ) to display the port menu.
2. Drag down to select Port Configuration…. The Port Configuration window,
Figure 4-31, will appear.
from the Chassis View window:
1. Click on the appropriate port index to access the Port menu.
2. Drag down to select Port Configuration…. The Port Configuration window,
Figure 4-31, will appear.
Using the Bridge and Port Configuration Windows
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Bridging
Figure 4-31. Port ConÞguration Window
The Bridge ConÞguration and Port ConÞguration window Þelds are deÞned as
follows:
Bridge Number
Displays the number of the Token Ring bridge. This value is limited to the range
of 0 through 15; a value of 65535 signiÞes there is no bridge number assigned.
This Þeld is settable in the Bridge ConÞguration window and read-only in the
Port ConÞguration window.
Virtual Ring Number
Displays the segment number that corresponds to the target segment the selected
port is connected to by the bridge. This value is limited to the range of 0 through
4095; a value of 65535 signiÞes there is no virtual ring number assigned. This Þeld
is settable in the Bridge ConÞguration window and read-only in the Port
ConÞguration window.
Ring Number
Displays the segment number that uniquely identiÞes the segment to which this
port is connected. This value is limited to the range of 0 through 4095; a value of
65535 signiÞes there is no ring number assigned. (This Þeld appears in the Port
ConÞguration window only.)
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Port Mode
Displays the two port mode options that are available, Lobe or Station.
Novell Translation
Displays the three bit-order options that are availableÑEnable LLC (Logical Link
Control Translation), Enable DLC (Data Link Layer Translation), and Disable (No
translation will take place) at the bridge or bridge interface.
Ring Speed
Displays the selected ring speed, 4 Mb/s or 16 Mb/s.
Bridge Mode/Explorer Type
Displays the available bridging modes/explorer frame typesÑSource Route
Transparent/Transparent, Source Route Transparent/ARE, Source Route
Transparent/STE, Source Route/ARE, Source Route/STE, and
Transparent/Transparent. The default selection is Transparent/Transparent.
To set the Bridge Number or the Virtual Ring Number in the Bridge ConÞguration
window:
1. Click in the Bridge Number or the Virtual Ring Number field in the upper
portion of the Bridge Configuration window. Enter a hexadecimal value
between 0 and F in the Bridge Number field, or a hexadecimal value between
001 and FFF in the Virtual Ring Number field.
2. Click on Set to apply the change, or click on Cancel to exit the window without
applying the change.
To set the Ring Number in the Port ConÞguration window:
1. Click in the Ring Number field in the upper portion of the Port Configuration
window. Enter a hexadecimal value between 001 and FFF.
2. Click on Set to apply the change, or click on Cancel to exit the window without
applying the change.
To set the Port Mode globally for all bridge interfaces on a device in the Bridge
ConÞguration window or for an individual interface in the Port ConÞguration
window:
1. Click on the empty radio button adjacent to either choice in the Port Mode
field, Lobe(DTR) or Station. When the radio button is filled ( ), the selected
choice will be enabled.
2. Click on Set to apply the change, or click on Cancel to exit the window without
applying the change.
Using the Bridge and Port Configuration Windows
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Bridging
To set the Novell Translation method globally for all bridge interfaces on a device
in the Bridge ConÞguration window or for an individual interface in the Port
ConÞguration window:
1. Click on the empty radio button adjacent to one of the three choices in the
Novell Translation field, Enable LLC, Enable DLC, or Disable. When the
radio button is filled ( ), the selected choice will be enabled.
2. Click on Set to apply the change, or click on Cancel to exit the window without
applying the change.
To set the Ring Speed globally for all bridge interfaces on a device in the Bridge
ConÞguration window or for an individual interface in the Port ConÞguration
window:
1. Click on the empty radio button adjacent to one of the two choices in the Ring
Speed field, 4 Mb/s or 16 Mb/s. When the radio button is filled ( ), the
selected choice will be enabled.
2. Click on Set to apply the change, or click on Cancel to exit the window without
applying the change.
To select the Bridge Mode/Explorer Type globally for all bridge interfaces on a
device in the Bridge ConÞguration window or for an individual interface in the
Port ConÞguration window:
1. Click in the Bridge Mode/Explorer Type pull-down list box. Pull down with the
left mouse button to select one of the available choices: Source Route
Transparent/Transparent, Source RouteTransparent/ARE, Source Route
Transparent/STE, Source Route/ARE, Source Route/STE, and
Transparent/Transparent. (The default selection is
Transparent/Transparent.)
2. Click on Set to apply the change, or click on Cancel to exit the window without
applying the change.
Configuring SmartTrunking
The SmartTrunk menu option invokes the SmartTrunk ConÞguration and Status
window, which allows you to group interfaces logically to achieve greater
bandwidth between devices (both devices must support the SmartTrunk feature).
There is no limit to the number of ports that can be included in a single Òtrunk.Ó
SmartTrunking is designed to work in the traditional bridging mode only, and is not
available if a switch is in the Securefast VLAN mode. The Securefast VLAN architecture
supports a fully-meshed topology, which has beneÞts similar to SmartTrunking.
NOTE
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To access the SmartTrunk ConÞguration and Status window
from the Bridge Status window:
1. Click on
to display the Bridge menu.
2. Drag down to select SmartTrunk…. The SmartTrunk Configuration and
from the Chassis View window:
1. Click on the Board Index of the device of interest; the Board menu will
appear.
2. Drag down to select SmartTrunk…. The SmartTrunk Configuration and
Figure 4-32. The SmartTrunk ConÞguration and Status Window
The SmartTrunk ConÞguration and Status window displays all of the ports on the
selected device. The following information is given for each port:
Port
Displays each port on the selected module. If the number of listed ports is more
than what can be seen in the list box, you can scroll down to view the additional
ports.
Name
Displays the name assigned to each listed port.
Configuring SmartTrunking
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Bridging
Mode
Displays the connection type for each port, either User or Network. User
connections do not participate in SmartTrunking; Network connections do. At
least two ports (from two separate chassis) must be designated as Network
connections to participate in SmartTrunking. All FNB interfaces must be
designated as User connections.
SmartTrunk State
Displays the current operating state of each listed port. The possible states
include:
¥
¥
NoneÑThe port is operating as a normal switch port.
BlockingÑThe port is load sharing, but in the blocked mode. While the
module performs the function of determining if there is a network loop, data
is temporarily blocked on new SmartTrunk ports and on any port that becomes
newly linked.
¥
SmartTrunkingÑThe port is load sharing with other Network-designated
ports of the same instance.
Instance
Displays the ports associated with each redundant loop. A module can have
multiple instances.
# SmartTrunks
Displays the total number of load-sharing ports in the redundant loop.
The only conÞgurable Þelds in the SmartTrunk ConÞguration and Status window
are the two Þelds with radio buttons, each with two possible settings:
SmartTrunk (with the options of Enable and Disable) and Enable and Disable
Port # X (with the options of LoadSharing and Disable).
When you Þrst open the SmartTrunk ConÞguration and Status Screen, the Enable and
Disable Port # X Þeld will be labeled SmartTrunk State Port #. After you click on a
port number in the list box, the Þeld title will change to Enable and Disable Port # X.
NOTE
To enable or disable SmartTrunking on an individual interface:
1. Click to select the interface number under the Port column in the list box for
which you wish to enable or disable SmartTrunking.
2. Click on the empty radio button adjacent to one of the two choices in the
SmartTrunk field: Enable or Disable. When the radio button is filled ( ), the
selected choice will be enabled.
3. Click on Set to apply your selection, or Cancel to exit the window without
applying the change.
4-98
Configuring SmartTrunking
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Bridging
To enable or disable Load Sharing on an individual bridge port:
1. Click to select the interface number under the Port column in the list box. The
interface number will then be listed as “X” in the Enable/Disable Port # X field.
2. Click on the empty radio button adjacent to one of the two choices in the field:
LoadSharing or Disable. When the radio button is filled ( ), the selected
choice will be enabled.
3. Click on Set to apply your selection, or Cancel to exit the window without
applying the change.
When you Þrst open the SmartTrunk ConÞguration and Status Screen, the Enable and
Disable Port # X Þeld will be labeled SmartTrunk State Port #. After you click on a
port number in the list box, the Þeld title will change to Enable and Disable Port # X.
NOTE
Configuring SmartTrunking
4-99
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Bridging
4-100
Configuring SmartTrunking
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Index
Forwarding Delay Time
Duplex Mode
G
H
E
Entries
I
Ethernet Special Filtering
I/F Summary
Individual Entries
F
Filter
Filter Database
Filters
L
Index-2
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Index
Port Filtering Action
Port Priority
M
Max Age Time
Q
R
N
O
P
S
SmartTrunk ConÞguration and Status
Index-3
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Index
SmartTrunk ConÞguration and Status
the SmartTrunk ConÞguration
Token Ring Special Filter
Token Ring Special Filtering Database
Total Bridge Detail Breakdown window
Type of Entry
U
Spanning Tree Algorithm Protocol Type
W
Special Filter Database
X
T
Index-4
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