The SES can also support a wide range of services over narrowband and mid-band user interfaces. It maps all the service traffic to and from ATM based on standardized interworking methods. When the SES is used as a feeder, it uses a single port to communicate the aggregated traffic over an ATM interface with an IGX 8400 series switch.

The SES supports up to 80 channelized or non-channelized T1 and E1 interfaces on a single switch. These interfaces support:

Frame Relay UNI and NNI
ATM UNI, NNI, and FUNI
Frame Relay to ATM network interworking
Frame Relay to ATM service interworking
Circuit emulation services

Frame-based services on T3 and E3 high speed lines are also supported.

The SES also supports Inverse Multiplexing for ATM (IMA) to provide ATM connectivity below T3 or E3 rates.

The modular, software-based system architecture enables it to support new features through downloadable software upgrades or new hardware modules.

Standards-Based Conversion to ATM

The SES converts all user-information into 53-byte ATM cells by using the appropriate ATM Adaptation Layer (AAL) for transport over the ATM backbone network. The individual service modules segment and reassemble (SAR) cells to eliminate system bottlenecks. The following list shows the applicable AAL for each service:

Circuit emulation services use AAL1.
Frame Relay-to-ATM network interworking uses AAL5 and Frame Relay Service Specific Convergence Sub-layer (FR-SSCS).
Frame Relay-to-ATM service interworking uses both transparent and translation modes to map Frame Relay to native ATM AAL5.
Frame Forwarding uses AAL5.

The complete list of SES technical specifications is contained in Appendix A of the Service Expansion Shelf Hardware Installation Guide.

SES Management

To control the SES, you can use the Cisco WAN Manager (formerly StrataView Plus) application (release 9.2.04) for connection management, the CiscoView application (release 2.03) for hardware configuration, and a command line interface (CLI) for low-level control. The command line interface is identical that of the MGX 8850 and is described in the section "SES and MGX 8850 Command Line Interface". The firmware determines the available functionality, and you can download firmware to upgrade functionality through a TFTP application on a workstation or a PC.

The current status and configuration parameters of the SES modules reside in a SNMP Management Information Base (MIB). Firmware updates the MIB as changes in status and configuration occur.

The control port (SLIP protocol only), the LAN (Ethernet) port, and the in-band ATM connection (feeder application only) all support the CLI (via Telnet), TFTP, and SNMP protocols for communicating with the SES (or an MGX 8850 switch).

Statistics and Command Line Interface

All statistics counters available in MGX 8850 release 1.1 are supported by the SES. There will be no change in the command line interface from MGX 8850. See Appendix A in the Cisco Service Expansion Shelf Hardware Installation Guide for a listing of the supported statistics.

The addshelf command on IGX has been modified to support adding an SES shelf to an IGX's UXM trunk.

Alarm and Error Handling

The SES provides the same alarm and error handling as SWSW Release 9.2 and MGX 8850 Release 1.1.

SES Processor and Service Modules

In this release, the SES as an IGX feeder supports the following processor and service modules:

SES Processor Switching Module (SES-PXM)—This front card controls the switch and supports two types of back cards: the user interface card and the broadband network module, which provides the OC3 feeder trunk to an IGX. Note that SES-PXM is not identical to an MGX 8850 PXM and is keyed so that it will not fit in an MGX 8850 chassis.

Processor Switch Module User Interface (PXM-UI)—The PXM1-UI provides user-control of the switch.
Broadband Network Module (MGX-MMF-4-155)—The MMF-4-155 provides 4 SONET OC3/STM1 ATM interfaces at 155 Mbps over multi-mode fiber. Only port 1 is used as the IGX feeder trunk in this application of the SES.
Broadband Network Module (MGX-SMFIR-4-155)—The SMF-4-155 provides 4 SONET OC3/STM1 ATM interfaces at 155 Mbps over single multi-mode fiber intermediate reach. Only port 1 is used as the IGX feeder trunk in this application of the SES.

Note The SES supports redundant processor modules (SES-PXMs) in chassis slots 1 and 2. If either card malfunctions, the standby set automatically becomes the active set.

Frame Service Module for T3 and E3 (MGX-FRSM-2E3T3)—The FRSM-2E3/T3 card provides interfaces for up to two T3 or E3 frame relay lines, each of which can support either 2 T3 lines (each at 44.736 Mbps) or 2 E3 lines (each at 34.368Mbps) FR-UNI, FR-NNI, ATM-FUNI, or Frame Forwarding port.
Frame Service Module for channelized T3 (MGX-FRSM-2CT3)—The FRSM-2CT3 card supports interfaces for up to two T3 channelized frame relay lines, each of which supports
56 Kbps, 64 Kbps, Nx56 Kbps, Nx64 kbps, T1 ports for a total of 256 ports that can be freely distributed across the two T3 lines.
Frame Service Module for unchannelized HSSI (MGX-HS2/B)
Frame Service Module for T1 (MGX-FRSM-8T1)—The FRSM-8T1 card provides interfaces for up to eight T1 lines, each of which can support one 56 Kbps or one Nx64 Kbps FR-UNI, FR-NNI port, ATM-FUNI, or a Frame Forwarding port.
Frame Service Module for T1, channelized (MGX-FRSM-8T1-C)—The FRSM-8T1-C card provides interfaces for up to eight T1 lines, each of which can support up to 24 56 Kbps or
Nx64 Kbps FR-UNI, FR-NNI, ATM-FUNI, or Frame Forwarding port.
Frame Service Module for E1 (MGX-FRSM-8E1)—The FRSM-8E1 card provides interfaces for up to eight E1 lines, each of which can support one 56 Kbps or one Nx64 Kbps FR-UNI, FR-NNI, ATM-FUNI, or Frame Forwarding port.
Frame Service Module for E1, channelized (MGX-FRSM-8E1-C)—The FRSM-8E1-C card provides interfaces for up to eight E1 channelized frame relay lines, each of which can support multiple (up to 31) 56 Kbps or Nx64 Kbps FR-UNI, FR-NNI, ATM-FUNI, or Frame Forwarding port.
ATM UNI Service Module for T1 (MGX-AUSM/B-8T1E1)—This card provides interfaces for up to eight T1 or E1 lines, each of which can support one T1 ATM UNI or ATM NNI plus additional support for IMA, permitting the BPX ATM trunk to be used over multiple T1 or E1 lines instead of a single T3 or E3 line.
Circuit Emulation Service Module for T1 (MGX-CESM-8T1)—The CESM-8T1 card provides interfaces for up to eight T1 lines, each of which is a 1.544 Mbps structured or unstructured synchronous data stream.
Circuit Emulation Service Module for E1 (MGX-CESM-8E1)—The CESM-8E1 card provides interfaces for up to eight E1 lines, each of which is a 2.048-Mbps structured or unstructured synchronous data stream.

Note The SES does not support the Route Processor Module (RPM), the Voice Interface Service Module, or the Service Resource Module (SRM-3T3) of the MGX 8850 card set.

SES IGX Feeder to IGX Functional Overview

All functions supported on IGX release 9.2 are supported when an SES is added as an IGX feeder. This includes features such as ports and trunks, virtual trunks on IGX UXM etc.

Switch software Release 9.2 supports UXM as feeder trunks to the SES. Only the MMF and SMFIR backcards for the UXM can be connected to an SES uplink backcard.

Figure E-3 illustrates a typical configuration for an network with an SES feeder to the IGX.

Figure E-3: Typical SES as IGX Feeder Application

The following cards are supported as end points for SES connections through the IGX. All physical interfaces to these cards are supported.

Within an IGX/BPX network with SES as feeders to the IGX, the following trunks are supported:

IGX-BPX—UXM-BXM
IGX-IGX:

UXM-UXM ATM trunk
UXM-UXM IMA trunk
NTM-NTM Fast Packet trunk

A BPX interface cannot be used as an end point on an SES connection. The BPX switch will function as a routing node (via node) within the IGX/BPX network, however.

The SES feeder to the IGX supports the following end point combinations. All interface speeds supported in MGX 8850 release 1.1 and in IGX release 9.2 are supported.

From	To
SES-CESM	SES-CESM through IGX/BPX network
SES-FRSM	SES-FRSM through IGX/BPX network
IGX-UFM
IGX-UXM with Service Interworking
SES-AUSM	SES-AUSM
IGX-UXM
IGX-UFM with Service Interworking

Table E-1: SES Feeder Connection Endpoints

From To

SES-CESM

SES-CESM through IGX/BPX network

SES-FRSM

SES-FRSM through IGX/BPX network

IGX-UFM

IGX-UXM with Service Interworking

SES-AUSM

SES-AUSM

IGX-UXM

IGX-UFM with Service Interworking

SES and MGX 8850 Relationship

In the IGX feeder application, the SES serves as a cost-reduced, smaller form-fit, MGX 8850 feeder. The SES has many similarities to the MGX 8850, which include:

SES and MGX 8850 Command Line Interface

The preferred tools for configuring, monitoring, and controlling an SES are the CiscoView and Cisco WAN Manager applications for equipment management and connection management, respectively. (The Cisco WAN Manager application is the former Cisco StrataView Plus application with the equipment management removed.) The SES and MGX 8850 command line interface (CLI) also provides access to the SES and is highly applicable during initial installation, troubleshooting, and any situation where low-level control is useful.

The Cisco MGX 8850 Wide Area Edge Switch Command Reference provides detailed information about the SES and MGX 8850 CLI commands. In the MGX 8850 Command Reference, the CLI commands are divided into major functional groups. The command reference gives complete name of the command and the cards for which the command is valid. This appendix contains examples of the use of some of the more common commands, but for complete information, look at The Cisco MGX 8850 Wide Area Edge Switch Command Reference.

The SES (or MGX 8850) CLI is typically accessed by a terminal attached to PXM-UI backcard control port or through a telnet session as described in the section "SES and MGX 8850 User Interface Access".

The command line prompt shows the name of the switch, the number of the switch (which is always "1"), the slot number and type for the current card, and whether the card is in the active ("a") or standby state ("s"). The following is an example of the command line prompt:

excel.1.6.AUSM.a >

In this case, the current card is an active AUSM in slot 6, and the name of the node is "excel."

The command notation and argument parameters follow standard programming convention: a space separates the command and each parameter; variables have an italicized typeface; required arguments appear within "<>" marks; optional parameters appear within square brackets ("[ ]"); and a vertical bar (|) represents the logical OR function.

Note When you use the SES CLI, you must type all command arguments then press Return or Enter rather than enter one parameter at a time.

When you enter a command with no parameters, a usage message appears. This message shows syntax and ranges for the applicable command parameters.

The SES commands are divided into commands directed at the SES-PXM processor module, the Portable AutoRoute (PAR) commands, and the service module commands. Applicable service module commands become available when you switch to a card by executing the cc command. Many commands apply to both the SES-PXM and the service modules.

SES and MGX 8850 User Interface Access

Three external ports exist for controlling the SES through the SES-PXM User Interface card (PXM-UI):

1. The control port (sometimes called the console port) to use the command line interface (CLI) on an ASCII terminal. The purpose of this port is:

Initial assignment of IP addresses to the Ethernet port, maintenance port, the inband ATM IP address, and the IP address of the statistics manager. The ATM IP address belongs to the link between the SES-PXM and the IGX 8400-series switch and applies to only the feeder application of the SES.

: Before you use the CiscoView or the Cisco WAN Manager (formerly StrataView Plus) network management applications, the IP addresses you intend for the switch must reside on the workstation in the etc/hosts file. Also, the text file config.sv on the workstation must contain the name of the switch you intend to be the gateway node, the network ID, the network name, and so on. See the Cisco WAN Manager documentation for the file system requirements on the workstation.

Low-level control or troubleshooting. (You can also use the CLI through a window in the Cisco WAN Manager application.)

2. The Ethernet port to use a workstation running a Cisco network management application such as the Cisco WAN Manager or CiscoView application. Typically, the workstation on a LAN is co-located with the SES feeder and IGX switch.

3. The maintenance port (sometimes called the modem port) to connect either a single workstation running an IP-based application or a terminal server that supports multiple workstations. The workstation must support SLIP. Typically, you use this port with a modem because the SES/IGX reside at a remote location. The typical applications are software and firmware download or tasks that require low-level access.

The maintenance port and Ethernet port support IP-based applications. Through these ports, the following applications run:

Telnet supports CLI command execution from any IP-based application window as well as a window in the Cisco WAN Manager application.
TFTP lets you download firmware and upload and download configuration information.
SNMP supports equipment management through the CiscoView application and connection management through the Cisco WAN Manager application.

SES and MGX 8850 Error Messages

In response to many SES conditions and CLI commands, the SES stores error messages in an error log. Not all messages indicate problems; some messages are only informational, while others help diagnose problems.

Messages are listed by the facility (hardware device, protocol, or a module or system software) that produces the messages. Within each facility, messages are listed by the severity level, from 1 through 7. Each message is followed by an explanation and a recommended action. Messages appear only when the system remains operational.

Message Structure

Messages similar to the following will appear in the error log:

04/27/1999-12:13:58 07 tTnInTsk01 CLI-7-CLITNLOG

cliTelnetd: client@171.71.25.240: telnet.01: disconnected

These messages are structured as follows:

mm/dd/yyyy-hh:mm:ss slot# taskname facility-severity-MNEMONIC description

where

mm/dd/yyyy-hh:mm:ss is the date and time of the error/event,slot# is the slot number to which the message applies, andtaskname is the name of the task to which the message applies.

The remaining parts of the messages, facility-severity-MNEMONIC description, contain the following information:

Facility codes —A facility code consists of two or more uppercase letters that indicate the reference facility to which the message refers. A facility can be a hardware device, a protocol, or a portion of the system software, such as BOOT for bootstrap module, for CLI for Command Line Interface, or CNTP for Control Point Software.

Severity Level—A severity level code is a single digit from 0 to 7 that reflects the severity of the condition from 1-fatal (platform needs reset) to 7-info (informational only). The lower the number, the more serious the situation.

Mnemonic Codes—The MNEMONIC code uniquely identifies the error message. All mnemonics are all uppercase character strings.

Description Text Strings—A description text string describes the condition. Sometimes it contains detailed information about the event, including terminal port numbers, network addresses, or addresses that correspond to locations in the system memory address space. Because these variable fields can change from message to message, they are represented by short strings in square brackets ([ ]). A decimal number, for example, is represented as [dec].

The SES (and MGX 8850) error messages are described in detail in the Cisco MGX 8850 System Error Messages, Release 1.1 document.

Configuring an SES IGX Feeder

This section provides the initial procedures for connecting an SES feeder to an IGX. It assumes that you have already installed the SES in a rack and connected power to it as described in the Cisco Service Expansion Shelf Hardware Installation Guide. (The procedures for adding ATM, or Frame Relay, or circuit emulation data connections are contained in the section, "Adding Service Module Connections".)

This section contains the following subsections:

Making the PXM-UI Interface Connections

During the initial configuration of an SES, you typically have to connect a terminal (or PC with terminal emulation software) to the PXM-UI backcard to issue commands to the SES. The PXM-UI backcard is illustrated in Figure E-4.

This section includes the following subsections:

Figure E-4: PXM-UI Faceplate

Attaching a Control Console

The control console can be attached to either the maintenance port or to the control port on the SES-PXM user interface backcard (PXM-UI).

When using an alpha-numeric (dumb) terminal to input CLI commands to the SES, the terminal must be connected directly (no modem) to the maintenance port DB25 connector on the PSM-UI faceplate. Use a conventional RS-232 cable with a DB25 connector at each end. A so-called "Null Modem" cable is not required. This port should never be Y-cabled.

When using a workstation to issue commands or transfer files to and from the shelf, the workstation can be attached through the RS-232 control port on the PXM-UI. Using this connection requires the workstation to communicate using TCP/IP and SLIP communication protocols.

Making External Clock Connections

If external equipment or a local digital central office is to provide synchronization to the SES, you can connect the external clock source to the PXM-UI back card. For a T1 clock input, connect the source to the RJ 45 connector labeled "T1 Clock." For a E1 clock input, use the SMC connector marked "E1 Clock."

Alarm Output Connection

Dry contact relay closures are available for forwarding SES alarms to an alarm system. Separate visual and audible alarm outputs are available for major and minor alarm outputs. The SES alarm outputs are available from a DB15 connector on the PXM-UI back card faceplate. Refer to
Appendix B, "Cable Specifications" in the Cisco Service Expansion Shelf Hardware Installation Guide for the pinouts on this connector. Use switchboard cable for running these connections.

Initial SES Bring-Up

This section describes how to start up the switch for the first time. It begins with a SES-PXM that has only boot-mode firmware. The descriptions tell you how to:

1. Establish communication with the switch.

2. Configure one or more boot-level IP addresses to make the switch available to the network.

3. Download SES-PXM firmware.

4. Configure a new, switch-level Ethernet IP address for the SES-PXM as needed or other SLIP or
IP addresses.

5. Specify a name for the switch.

6. Specify the time on the switch.

7. Optionally configure a time zone for the Western Hemisphere, or configure a time zone relative to Greenwich Mean Time if the switch resides outside the Western Hemisphere.

8. Download firmware to the service modules.

If the SES-PXM has no runtime (or "on-line") firmware image, begin with the boot-mode description in the section titled "Bringing Up a SES-PXM With No Runtime Firmware." If the SES-PXM has a runtime firmware image, go to the section titled "Configuring Node-Level Parameters."

Bringing Up a SES-PXM With No Runtime Firmware

The section describes the tasks for loading runtime firmware onto a SES-PXM that has only a boot loader.

Step 1 Establish communication with the switch by doing one of the following:

Connect a cable between your terminal or PC and the PXM-UI control port.
If you are using an ASCII terminal connected to the control port, the prompt for the next command is already present upon power-up. (If the display is skewed, make sure the terminal speed and PXM-UI port speeds are the same.)
If you are using a utility such as Hyper Terminal on a PC, the firmware may reside on either a floppy or the hard drive.

Step 2 Execute the command bootChange to configure boot-level IP parameters.

If the switch has a redundant SES-PXM, execute bootChange on each SES-PXM to configure unique, boot-level IP addresses. (During the subsequent switch-level configuration, you must configure another Ethernet IP address that applies to both SES-PXMs.) The following are the only parameters that are meaningful at this point, so press Return other parameters:

Mandatory "host name" is a name for the workstation. For the SES, enter the letter "c."

Ethernet IP address and subnet mask for the SES-PXM LAN port are mandatory (see "inet on Ethernet" in the following example). Follow the IP address with a colon and a net mask. The netmask is eight hexadecimal numbers with no embedded periods. Do not type spaces on either side of the colon.

If the workstation from which you download firmware is on a subnet other than the subnet of the SES-PXM, enter a gateway IP address ("gateway inet").

Note the three editing functions near the top of the following example. Of these, typing a period to the clear the current field is the most commonly used.


>bootChange
'.' = clear field;  '-' = go to previous field;  ^D = quit
boot device          : lnPci
processor number     : 0
host name            :c
file name            :
inet on ethernet (e) : 188.29.37.14:ffffff00
inet on backplane (b):
host inet (h)        :
gateway inet (g)     : 188.29.37.1 
user (u)             :
ftp password (pw) (blank = use rsh): 
flags (f)            : 0x0
target name (tn)     :
startup script (s)   :
other (o)            :

The SES-PXM now has a boot-level IP address. Remember to repeat the bootChange command on the redundant SES-PXM if the system has one.

Step 3 Enter reboot to reset the SES-PXM.

The SES-PXM is ready to receive a firmware image through the Ethernet port. Use the workstation for the next steps.

Step 4 At the workstation, you can optionally ping the SES-PXM using the IP address to confirm that the node is reachable.

Step 5 Establish communication with the SES-PXM according to the user-communication device type. For example, at the prompt on a UNIX workstation, you could enter:

>tip -9600 /dev/ttya

The device specification could also be ttyb.

Step 6 Enter the tftp command with the IP address set at the ASCII terminal. For example, if the console port is connected to the serial port of the workstation:

$tftp 162.29.38.101

Step 7 At the tftp prompt, enter binary mode:

>bin

Step 8 From the directory where the firmware resides, enter the put command and include the arguments that specify the firmware release number, the statement that this firmware applies to the active SES-PXM, and the release directory.

If necessary, refer to the release notes for new firmware release numbers. The entries are case-sensitive. For example:

>put pxm_release_number.fw POPEYE@PXM_ACTIVE.FW

where release_number is a decimal number in the form n.n.nn. Currently, the initial n typically is a "1." An example filename for SES-PXM firmware is "pxm_1.0.03." Note that the download automatically includes the firmware for the standby SES-PXM (if present). You can subsequently see POPEYE@PXM_STANDBY.FW in c:/FW.

Check the console to verify that the transfer completed and the checksum passed.

Step 9 Quit the tftp application, then go to the ASCII terminal connected to the control port:

>quit

Step 10 At the ASCII terminal, cd to FW directory on the hard drive.

Step 11 List the contents to confirm that the firmware resides in the FW directory:

>cd "c:/FW"

>ll

Note these required quote marks are absent when you use the CLI after you reboot the SES-PXM with its runtime image (see "Configuring Node-Level Parameters").

Step 12 Enter the following:

>setPXMPrimary "version"

where version is the version number of the firmware. The name of a SES-PXM firmware file has the format pxm_version.fw. For example: in PXM_1.0.03.fw, version is 1.0.03.

Step 13 Reboot the system again:

>reboot

A login prompt appears on the ASCII terminal. The SES-PXM is now the same as a SES-PXM that Cisco ships with a runtime firmware image.

Configuring Node-Level Parameters

Except for adding a user and creating a password, all the tasks described in this section can be performed through the CiscoView application. For descriptions of the commands you enter at the CLI, see the Cisco MGX 8850 Wide Area Edge Switch Command Reference. A representation of the feeder application of the SES appears in Figure E-5.

Figure E-5: SES IGX Feeder Application

Resource Partitioning

A resource partition on a SES-PXM consists of a percentage of bandwidth, a VPI/VCI range, and the number of global logical connection numbers (GLCNs) available to a network control application. By default, all resources on a logical interface are available to any controller on a first-come, first-served basis. In this release of the SES IGX feeder application, Portable AutoRoute (PAR) is the only network control application. Future releases of the SES may include other network control applications, such as, Multi-Protocol Label Switching (MPLS) or a Private Network to Network Interface (PNNI) controller, and then the resources will have to be carefully partitioned.

Note The SES-PXM resources do not have to be partitioned for the SES IGX feeder application.

At the SES CLI prompt on the ASCII terminal:

Step 1 Enter the default login and password provided in the release notes.

The terminal displays the slot number of the SES-PXM you have logged into by default:

card number [1]:

Step 2 Press Return to enter the CLI of this SES-PXM.

At runtime, you could also enter the slot number of a service module or a standby SES-PXM. In this case, the CLI prompt shows:

NODENAME.1.1.PXM.a>

where NODENAME shows that the node has no name; the slot number of the SES-PXM is 1; and this SES-PXM is active. The general format of the CLI prompt is:

nodename.1.slot.cardtype.a>

where nodename is the name of the node; the shelf (node) number is always 1; slot is the card location; cardtype identifies the card; and the card state is active (a) or standby (s).

Step 3 Display the cards in the system:

NODENAME.1.1.PXM.a> dspcds

Step 4 Display any IP addresses in the system:

NODENAME.1.1.PXM.a> dspifip

Step 5 Change any IP addresses as needed:

NODENAME.1.1.PXM.a> cnfifip <interface> <IP_Addr> <Net_Mask> [BrocastAddr]

where interface is a number: 26 is the Ethernet (LAN AUI) port, 28 is the maintenance port (SLIP), or 37 for the ATM IP address (feeder application only). Note that BrocastAddr applies to only the Ethernet interface (number 26).

Note

Step 6 Execute the cnfname command to assign a name to the switch:

UNKNOWN.1.1.PXM.a> cnfname <node name>

where node name is a case-sensitive name up to eight characters. For example:

UNKNOWN.1.1.PXM.a> cnfname cisco22

Step 7 Execute the cnftime command to specify the time on the switch:

cisco22.1.1.PXM.a> cnftime <hh:mm:ss>

where hh is the hour of the day in the range 1-24; mm is the minute of the hour in the range 1-60; and ss is the number of seconds in the minute and has a range of 1-60.

Step 8 Optionally configure a time zone for the node. Use cnftmzn to specify a time zone in the Western Hemisphere. To configure a time zone outside the Western Hemisphere, first specify Greenwich Mean Time (GMT) with cnftmzn then specify the offset from GMT by using cnftmzngmt:

cisco22.1.1.PXM.a> cnftmzn <timezone>

where timezone is 1 for GMT, 2 for EST, 3 for CST, 4 for MST, 5 for PST.

cisco22.1.1.PXM.a> cnftmzngmt <timeoffsetGMT>

where timeoffsetGMT is the offset in hours from GMT. The range of possible values for timeoffsetGMT is -12 through +12.

Step 9 Execute the cnfstatsmgr command to specify the IP address of the workstation that runs the Cisco WAN Manager application.

Before it sends statistics, the SES must have the IP address of the workstation with this application. The syntax is:

>cnfstatsmgr <IP_Addr> where IP_Addr is the IP address of the workstation.

If the node has a redundant SES-PXM, it automatically receives the same IP addresses and configuration as the primary SES-PXM. With the IP addresses in place, you can configure the logical ports for the broadband interface through the CiscoView application or the CLI.

Step 10 Add one or more users by executing adduser once for each new user.

Note that the access privilege level is case-sensitive as the syntax description indicates. After you enter the privilege level, the system prompts for a new password for the user. (This password parameter does not appear in the help information for adduser.)

adduser <user_Id> <accessLevel>

user_Id is 1-12 alphanumeric characters.

accessLevel is the case-sensitive privilege level. It can be ANYUSER or within the range GROUP1-GROUP5. For example, to specify a privilege level 2, type GROUP2.

After you enter a user-name and privilege level, the system prompts for a password. The password is a string of 5-15 characters. If you press Return without entering a password, the system assigns the default password "newuser."

Step 11 Optionally change your password or another user's password by executing:

cnfpasswd [username]

username is the name of another user whose password you are changing. That user must have a privilege level that is lower than your privilege. To change your own password, enter cnfpasswd with no username.

Step 12 To specify the switch as a feeder, execute the cnfswfunc command:

cnfswfunc <-ndtype>

and follow -ndtype with "fdr."

Step 13 Configure as needed an external clock by executing cnfextclk.

Downloading Firmware to a Service Module

This section describes how to download firmware for a service module from a workstation. The descriptions apply whether you are upgrading the existing firmware or downloading because no runtime firmware resides on the hard drive.

Service modules do not retain runtime firmware. The hard drive on the SES-PXM may come with default firmware for the service modules, but the details of the customer order actually determine whether firmware is on the disk. If default firmware exists on the hard drive, the SES-PXM downloads it upon power-up or when you reset the card, otherwise you can download firmware from the workstation according to the instructions that follow.

Note that if you download firmware from a workstation to the hard drive, the SES-PXM does not automatically load the firmware to the card. You must reset the card (resetcd on the CLI) to download firmware from disk to the card. With the single execution of a command, you can load either generic firmware for all cards of a certain type or firmware destined to a specific slot.

To load service module firmware from a workstation to the hard drive on the SES-PXM:

Step 1 Start the tftp application:

$tftp <IP address>

then

>bin

Step 2 To download generic firmware for a type of service module to the SES-PXM hard drive:

>put cardtype.fw POPEYE@SM_1_0.FW

where cardtype is the firmware for a type of card; the shelf number always is 1; and the 0 represents the slot number for the purpose of generic download. An example of cardtype.fw is "frsm8t1e1_10.0.11.fw." Note the space between ".fw" and "POPEYE."

Step 3 To load slot-specific firmware at a particular card:

>put cardtype.fw POPEYE@SM_1_slot.FW

where cardtype is the firmware, and slot is the number of the card slot. Note the space between ".fw" and "POPEYE." Repeat this step for each slot as needed.

Note

With slot-specific firmware, the card does not come up if you do either of the following:

Specify the wrong firmware, where the firmware specified by cardtype does not match the targeted card at slot.
Insert a different card (which does not use the firmware specified for the slot).

An example command for downloading specific firmware for an FRSM-2CT3 in slot 3 is:

>put frsm2ct3_10.0.01.fw POPEYE@SM_1_3.FW

where "frsm2ct3_10.0.0" refers to the firmware for the FRSM-2CT3, and "3" is the slot.

Note

Step 4 When you have finished downloading firmware, enter quit to quit the tftp application.

Step 5 At the CLI on either the workstation or the ACSII terminal, display the firmware files. Note that the directory specification ll c:/FW has no quote marks.

cisco22.1.1.PXM.a> ll c:/FW

Step 6 If you want to download the firmware from the disk to a card, execute resetcd.

SES CLI Configuration of a Feeder

This section first describes how to use the CLI to configure physical and logical characteristics of the equipment, such as physical line, logical ports, and resource partitioning. The section then describes how to add daxcons and three-segment connections. To do these tasks, the requisite IP addresses must have been assigned. The descriptions tell you how to:

Specify that the application of the SES is a feeder to an IGX 8400-series switch.

At the card-level, optionally specify the total number of connections available to each network controller (PAR, and so on).

Activate a line on the broadband interface of the SES-PXM—only one line for an IGX feeder.

Optionally modify the characteristics of the line.

Create one or more logical ports on the line. Each port has associated bandwidth and VPI/VCI ranges. By default, each controller competes for all the resources you assign to the port.

Optionally specify the amount of resources a network controller has on a logical port rather than allow the controllers to compete for resources.

Add the SES shelf from the IGX side.

Configuring the OC-3 Uplink

The SES-PXM uses only an OC-3 uplink backcard as a feeder trunk.

Step 1 Execute the cnfswfunc command to specify the feeder application:

cnfswfunc <-vsvd enable(yes)/disable(no)> | <-ndtype>

Follow -ndtype with "fdr" or "routing." The default application is routing.You can configure one option each time you execute cnfswfunc.

Step 2 If the switch must support the paid feature of virtual source/virtual destination (VSVD) on ABR connections, execute cnfswfunc. The cnfswfunc syntax is:

cnfswfunc <-vsvd enable(yes)/disable(no)> | <-ndtype>

where you follow "-vsvd" with "e" or "d."

Step 3 Optionally, modify the resource partitioning for the whole card by executing the cnfcdrscprtn command. You can view resource partitioning through dspcdrscprtn.

cnfcdrscprtn <number_PAR_conns> <number_PNNI_conns> <number_TAG_conns>

number_PAR_conns is the number of connections in the range 0-32767 available to PAR.

number_PNNI_conns is the number of connections in the range 0-32767 available to PNNI.

number_TAG_conns is the number of connections in the range 0-32767 available to Tag.

For example, you could reserve 10,000 connections for each controller on the SES-PXM with:

cnfcdrscprtn 10000 10000 10000

Note In this release, there is no need to partition SES-PXM resources.

Step 4 Activate the uplink line by executing addln according to the following syntax:

addln -ds3 <slot.line> | -e3 <slot.line> | -sonet <slot.line>

where:

-ds3 indicates a T3 line
-e3 indicates an E3 line
-sonet indicates an OC-3 or OC-12 line
slot is always 1 for the SES-PXM whether the active SES-PXM is in slot 1 or 2
line has the range 1-4 but depends on the number of lines on the uplink card

You can activate only one SES-PXM line for the feeder application.

Step 5 If necessary, you can configure line characteristics by using the cnfln command.

Step 6 Create logical ports for the physical line by executing addport once for each logical interface. (Related commands are cnfport, dspports, and delport.)

addport <port_num> <line_num> <pct_bw> <min_vpi> <max_vpi>

port_num is the number for the logical port. The range is 1-32 for standard connections, and 34 is the port number reserved for inband ATM PVCs for network management.

line_num is the physical line in the range 1-N. N is the number of lines on the card.

pct_bw is percentage of bandwidth. The range is 0-100. This parameter applies to both ingress and egress.

min_vpi is the minimum VPI value. The range is 0-4095.

max_vpi is the maximum VPI value. The range is 0-4095.

Step 7 Optionally use cnfportrscprtn to specify the resources that a controller has on a port:

cnfportrscprtn <port_no> <controller> <ingress_%BW> <egress_%BW>

<min_VPI> <max_VPI> <min_VCI> <max_VCI> <max_GLCNs>

port_no is the number for the logical port in the range 1-32 for user-connections or 34 for inband ATM PVCs for network managment.

controller is a string identifying the network controller—"PAR," "PNNI," or "TAG."

ingress_%BW is the percentage of ingress bandwidth—a number in the range 0-100.

egress_%BW is the percentage of egress bandwidth—a number in the range 0-100.

min_vpi is the minimum VPI Value—a number in the range 0-4095.

max_vpi is the maximum VPI Value—a number in the range 0-4095.

min_vci is the minimum VCI Value—a number in the range 0-65535.

max_vci is the maximum VCI Value—a number in the range 0-65535.

max_chans is the maximum GLCNS—a number in the range 0-32767.

Step 8 Execute cnfifastrk to configure the port as a trunk. To change the port usage after you execute cnfifastrk, first execute the uncnfifastrk command.

cnfifastrk <slot.port> <trunk>

slot.port is the slot and port number of the line you want to serve as the trunk. Note that, whether the active SES-PXM is in slot 1 or 2, always specify slot 1 in CLI syntax because this parameter is a logical value.
trunk is the switch application and can be either "fdr" for a feeder or "rtrk" for a stand-alone node. Specify "fdr."

Step 9 Log in to the IGX at the other end of the feeder trunk and use the addshelf command to add the SES as a feeder.

CiscoView Configuration of a Feeder

This section describes how to use the CiscoView application to create and optionally modify the characteristics of the logical ports on the SES uplink card. It provides another way of configuring the SES. To configure equipment on an SES, you must use Release 2.x or higher of CiscoView. No CiscoView screen representations appear in this appendix. For a description of CiscoView usage, see the CiscoView documentation. The task descriptions begin from the point where you have already specified all IP addresses and the top-level CiscoView window is on-screen. The task descriptions tell you how to:

Specify that the application of the SES is a feeder to a IGX 8400-series switch.
At the card level, optionally specify the number of connections available to a network controller.
Activate and optionally modify the characteristics of a line on the broadband interface of the SES-PXM—only one line for an IGX feeder.
Create 1-32 logical ports on the line. By default, each network controller can compete for all the resources you assign to the port.
Optionally specify the amount of resources each network controller has on a logical port rather than allow the controllers to compete for resources. (Note that for this release PAR is the only network controller using SES resources.)

Selecting an SES

To reach the target SES:

Step 1 Click on the File option at the top of the CiscoView - Main window, then click on the Open Device option.

Step 2 Enter the node name or IP address of the SES in the Device Select window. When the graphical representation of the switch shows the cards' faceplate features, you can begin configuration.

Step 3 You can configure features from either the front or back view of the switch. Optionally, select a side of the switch through the View option at the top of CiscoView - Main.

Note If you configure SES-PXM features at the back card, select the Configure Card options by clicking with the left mouse button on the SES-PXM back card but away from the connectors. If you successfully select the card features, an outline of the entire back card lights up. To select the Configure Line features, click on the back card near the connectors. If you select the line features, an outline around the connectors lights up. Similarly, in the front view, select either a port LED for line configuration or a nonspecific area of the SES-PXM front card for card configuration.

Specifying the Feeder Application

To specify that the SES operate as a feeder to an IGX 8400-series switch or to make ABR VSVD operational on this switch:

Step 1 Click with the left mouse button on the SES-PXM so that the card outline lights up.

Step 2 Click on the Configure option at the top of the CiscoView - Main window; then click on the highlighted "card" choice that appears under "Configure." The Configure Card box appears. Next to the "CATEGORY" label, the menu button shows "Card."

Step 3 Click on Card to display the node configuration options.

Step 4 Select PAR Configuration. The Configure PAR window opens.

Step 5 Click on the menu button next to the CATEGORY field to display the PAR topics.

Step 6 Select PAR SW Configuration. The PAR Configuration box shows the defaults of "false" for VSVD and "routing" for Node Type. Change the selection to "feeder." If VSVD has been purchased, select the true/false button and change the setting to "true."

Step 7 Select Modify at the bottom of the box.

Step 8 Select Cancel to exit the PAR Configuration box or select another PAR topic at the menu button next to the CATEGORY field.

Activating a Physical Line for the Uplink

To activate a line for the uplink:

Step 1 Click on the LED that corresponds to the SES-PXM line you want to activate. For the feeder application, only Port 1 is selectable. If you correctly select the LED of an inactive line, an outline of the LED lights up. If an outline of the card lights up, you have selected the card rather than the port.

Step 2 Click on the Configure option at the top the screen then the line option in the subsequent pull-down list. The Configure Line window appears and shows the selected line with its current characteristics.

Step 3 Change appropriate line characteristics as needed, then select the LineEnable button and change the state to "enable."

Step 4 Click on the Modify button to transmit any configuration changes and enable the line.

Configuring Logical Interfaces for the Feeder

To configure logical, broadband interfaces on the physical interface:

Step 1 Select the SES-PXM by clicking on the faceplate of the card. An outline of the card lights up.

Step 2 Select "Configure" then "card" at the top of the switch graphic. The Configure Card window appears with information on the current card.

Step 3 Click on the button next to the CATEGORY field, then select Broadband Interfaces. A matrix appears for configuring logical interfaces on the active lines. The maximum number of user-ports is 32.

Step 4 Select the Create button to add a logical interface. A text box appears that lets you enter:

A number in the range 1-32 for the new logical interface
The port number of the physical line to which you assign the logical interface
A percentage of the maximum bandwidth on the line for the new logical interface
A minimum VPI number for the new logical interface in the range 0-4095

A maximum VPI number for the new logical interface in the range 0-4095

Step 5 Type a value in each of the fields, then press the Apply button. The message "Addition of broadband interface is successful" appears, otherwise an error message appears. Example errors are entries out-of-range or values that conflict with existing configurations.

Note The Create window's message of successful addition of an interface is accurate, but new interfaces do not appear in the Configure Broadband Interfaces per Card window until you close and reopen this window.

Step 6 If necessary, specify additional interfaces in the matrix. You can leave the Create box open and write over residual text or reopen this box later.

Step 7 Select the Cancel button at the bottom of the window to exit.

If you subsequently want to delete or change a logical interface:

Step 1 Open the Broadband Interfaces window.

Step 2 On the row for the targeted logical interface, move the cursor to the Status column and hold the left mouse button down on the current status. A small menu opens with "add, "del," and "mod" choices.

Select "del" to delete the interface.

: or

Select "mod" to change a parameter.

Step 3 Select the Modify button at the bottom of the window. To see the result of any changes, close then reopen the Broadband Interfaces window.

Partitioning Resources on the Broadband Interface

Note in this release, since PAR is the network controller controlling the SES, there is no need to configure resources.

Configuring the Line as a Feeder Trunk

A line connected to the SES-PXM line module can function only as a feeder trunk in this release. In addition to configuring the use of the trunk at the SES, you must also configure the trunk at the far-end IGX.

To configure the trunk for the feeder application at the near-end:

Step 1 Open the Configure Card window.

Step 2 For the CATEGORY, select PAR Configuration.

Step 3 In the PAR Configuration window, select PAR Interface. In the PAR Interface window, the only configurable column is the PAR Interface Type.

Step 4 For the logical interface type—1 for the feeder trunk—hold the left mouse button down in the PAR Interface Type column for this logical interface. The choices are "feedertrunk" and "routing trunk."

Step 5 Select "feedertrunk," then click on the modify button at the bottom of the screen.

Step 6 Log in to the IGX at the other end of the feeder trunk and use the addshelf command to add the SES as a feeder.

Adding Service Module Connections

This section contains a general description of the sequence of tasks for configuring service modules (FRSM, AUSM, CESM) and the services they support and the available services (ATM, Frame Relay, or circuit emulation). It also contains details on how to configure resource partitions and add local connections and three-segment connections. Detailed descriptions of these tasks for individual service modules appear in subsequent sections.

Although many of the configuration and connection tasks can done with either Cisco WANManager (CWM) and CiscoView network management applications, this appendix uses the SES command line interface commands in its examples. Refer to the appropriate CWM 9.2.xx and CiscoView 2.xx documentation for information about using those applications with the SES.

Connections on a Feeder

The SES IGX feeder can support local connections (daxcons) and three-segment connections across the network. How you add connections depends on the technology of the service module, which card is the master or slave end of the connection, and whether the connection is a daxcon or part of a three-segment connection. The following rules govern connection addition in an SES feeder.

The descriptions of connection addition later in this section reflect these rules:

1. If the SES-PXM is an endpoint, it functions as the slave. The service module is the master end.

2. For a daxcon, you first add the connection at the slave end then add it at the master end. Further, when you start by adding a connection at the slave end, the system generates the remote (master) connection ID for you. The remote connection ID contains required information for adding the connection at the master end.

3. For a three-segment connection, you start the segment by adding a connection at the master end. In this case, you specify the connection ID of the slave end of the segment and subsequently use that information for adding the connection at the slave end.

4. If the remote termination is an SES PXM on the other side of a network cloud, specify the slot number as "0." (This requirement applies to only the feeder application of the SES.)

Modifying the Resource Partitioning

A resource partition on a card consists of a percentage of bandwidth, a DLCI or VPI/VCI range, and the number of logical connection numbers (LCNs) available to a network control application. On the SES-PXM, the connections are global logical connections (GLCNs). By default, all resources on a logical interface are available to any controller on a first-come, first-served basis. If necessary, you can modify the resources for a controller at the card level and logical port level. Port-level resource modification follows card-level modification, so the available port-level resources depend on whether and how much you change the card-level resource partitioning. You do not have to change the resource partitioning for the card before changing resource partitioning for a port.

The current network control application is Portable AutoRoute (PAR). Planning considerations should include the possibility of modifying the partitioning of resources for the interface. For example, the SES has the capacity to support a Cisco Multi-Protocol Label Switching (MPLS) controller or a Private Network to Network Interface (PNNI) controller.

Note There is no need to partition SES service module resources in this release of the SES IGX feeder.

Sequence of Configuration Tasks

In a new switch, the common approach is to configure the same aspect for all cards at once—adding logical ports, for example. In contrast, the likely sequence for installing a new or replacement card is to begin with the card-level features and continue until you have added every connection. The common tasks for a new switch are:

1. Activate physical lines.

2. Optionally configure the line if default parameters are not appropriate.

3. Create the logical ports then modify as needed the logical ports.

4. Optionally configure resource partitions for a logical port if the default partitioning does not support the intended operation of the port. (With this release of SES IGX feeder, there is no need to partition resources.)

5. Add connections then modify as needed individual connections.

Rules for Adding Connections

This section describes the rules for adding local connections, three-segment connections, and management connections. The SES can support

Local-only, digital access cross-connect (DAX) connections
Three-segment connections across an ATM or Frame Relay network

As a preface to the steps for adding connections, this section describes the applicable rules for these connections. Although the rules include references to CLI syntax, they also apply to the Cisco WAN Manager application.

Rules for Adding a DAX Connection

A DAX con is a connection whose endpoints for the entire connection exist on the same switch. The following apply to the SES:

1. On a feeder, a DAX con can exist between different service modules or the same service module.

2. A stand-alone node supports DAX cons with one or both endpoints on the SES-PXM in addition to DAX cons between service modules.

3. Either endpoint can be the master.

4. The first endpoint to add is the slave. The generic syntax is:

: addcon <local parameters>
: where local parameters are the port, DLCI or VPI and VCI, and mastership status. Slave is the default case, so you actually do not have to specify it. When you press Return, the system returns an identifier for this connection. The identifier includes the port and DLCI or VPI and VCI.
: Use the returned identifier to specify the slave endpoint when you subsequently add the connection at the master end. The slave endpoint is specified as the remote parameters in item 5.

5. To complete the DAX con, add the master endpoint. The generic syntax is

: addcon <local parameters> <remote parameters>
: where local parameters are the port, DLCI or VPI and VCI, and mastership status (master in this case). The remote parameters are the items in the connection identifier that the system returned when you added the slave endpoint.

6. If the endpoint is a SES-PXM port in a stand-alone node, specify the slot as 0. The addcon command is the only command in which you specify the slot number for the SES-PXM as 0.

Rules for Adding Three-Segment Connections

A three-segment connection consists of a local segment on each SES at the edges of the network cloud and a middle segment across the network cloud. Figure E-6 illustrates a 3-segment Frame Relay connection. The SES requirements are:

1. For SES feeders, the backbone must consist of IGX 8400-series or BPX 8600-series switches.

2. On a feeder, the local segment exists between a service module and the SES-PXM.

3. On a stand-alone node, the local segment can be between a service module and the uplink port on the SES-PXM.

4. For the local segment, add the connection at only the master endpoint. The generic syntax is:

: addcon <local parameters> <remote parameters>
: where local parameters are the port, DLCI or VPI and VCI, and mastership status (master in this case). The remote parameters are the current nodename, slot, port, and VPI and VCI of the slave end. For the SES-PXM endpoints, specify the slot number as 0. The addcon command is the only command in which you specify the slot number for the SES-PXM as 0.

Figure E-6: Frame Relay Connection Through an SES/IGX/BPX Network

ATM Universal Service Module Connections

The eight-port ATM Universal Service Module (MGX-AUSM/B-8T1 and MGX-AUSM/B-E1) is a multipurpose card set with eight T1 or E1 lines that support:

ATM UNI with high port-density for the CPE—with AUSMs in all 24 service module slots, an SES can support up to 192 individual T1 or E1 lines. An individual card set can support 1000 data connections and 16 management connections.

Inverse multiplexing for ATM (IMA) that complies with ATM Forum v3.0, v3.1, and v4.0 —the 8-port AUSM can provide N x T1 or N x E1 logical ports up to maximum rates of 12 Mbps for T1 or 16 Mbps for E1.

Classes of service—CBR, VBR, ABR, and UBR with per-VC queuing on ingress and multiple class-of-service queues on egress.

Statistics collection.

Virtual path connections (VPCs).

Network synchronization derived from one of its lines.

BERT functionality with loopback pattern generation and verification on individual lines.

Automatic card-restore.

SNMP and TFTP to support card and connection management.

Resource partitions for individual network control applications (not needed in this release).

Using the CLI to Configure the Card, Lines, and Ports

You can activate and configure the card, the lines, and the ports on the AUSM-series cards through the CiscoView application or the CLI. To perform connection-related tasks, use the Cisco WAN Manager application or the CLI. Refer to the documentation for these applications for task descriptions. Use the commands described in this section to:

Optionally modify resource partitioning at the card-level
Activate and configure a line
Create and configure a logical port
Optionally modify resource partitioning at the port-level
Configure usage parameters
Configure queue depths
Configure the ForeSight feature
Configure a line as a clock source

On the SES CLI of the AUSM:

Step 1 If necessary, modify the resource partitioning for the whole card by executing the cnfcdrscprtn command. You can view resource partitioning through dspcdrscprtn.

cnfcdrscprtn <number_PAR_conns | number_PNNI_conns | number_TAG_conns>

number_PAR_conns is the number of connections in the range 0-1000 for PAR.
number_PNNI_conns is the number of connections in the range 0-1000 for PNNI.
number_TAG_conns is the number of connections in the range 0-1000 for MPLS.

For example, you could reserve 300 connections for each controller on the AUSM with:

cnfcdrscprtn 300 300 300

Step 2 Activate a physical line by using addln for each of the eight lines as needed:

addln <line_number>

Step 3 Optionally, use the cnfln command to specify line coding, line length, and clock source:

cnfln <line_num> <line_code> <line_len> <clk_src> [E1-signaling]

Step 4 Execute upport to activate the logical operation of the line:

upport <port_number>, where port_number is in the range 1-8.

Step 5 If necessary, execute cnfportq to modify the egress queues:

cnfportq <port_num> <q_num> <q_algo> <q_depth> <clp_high> <clp_low> <efci_thres>

port_num	is the logical port number in the range 1-8.
q_num	is the queue number in the range 1-16. 0 is the default for addchan. 1=CBR 2=VBR 3=ABR 4=UBR
q_algo	is a number to specify the queue algorithm: 0=disable queue 1=high priority—always serve 2=best available 3=minimum guaranteed bandwidth 4=minimum guaranteed bandwidth with maximum rate shaping 5=CBR with smoothing
q_depth	is the maximum queue depth in the range 1-16000 cells
clp_high	clp high is the high Cell Loss Priority in the range 1-16000 cells
clp_low	clp low is the low Cell Loss Priority in the range 1-16000 cells
efci_thres	efci threshold is the EFCI threshold in the range 1-16000 cells

Step 6 If necessary, configure resources at the port level by executing cnfportrscprtn. Use dspportrscprtn to see the current resource partitioning.

cnfportrscprtn <port_num> <controller> <ingress_%BW> <egress_%BW> <number_of_cons> <VPImin/VPImax> [VCImin/VCImax]

port_num is the port number in the range 1-8.
controller is a number representing the controller: 1=PAR, 2=PNNI, and 3=MPLS.
ingress_%BW is the percentage of ingress bandwidth in the range 0-100.
egress_%BW is the percentage of egress bandwidth in the range 0-100.
number_of_cons is the maximum number of connections on the port.
VPImin/VPImax is the minimum and maximum VPI numbers.
VCImin/VCImax is the optional specification for VCI range.

Using the CLI to Configure Inverse Multiplexing

The command sequence for configuring the IMA feature:

Step 1 addln on all constituent links.

Step 2 cnfln if necessary.

Step 3 addimagrp (or addaimgrp) to create the IMA group by using the following syntax:

addimagrp <group_num> <port_type> <list_of_links> <minNumLink>

group_num	is a number for IMA group. The range is 1-8.
port_type	is the port type: 1=UNI, 2=NN1.
list_of_links	is the list of links to be included in the group. Separate each link number by a period.
minNumLink	is the minimum number of links in the range 1-8 to form a group.

For example: the following creates IMA group 1 with lines 3, 4, and 5. The minimum is 3.

addimagrp 1 3.4.5 3

IMA-related commands are dspimagrp, dspimagrpcnt, dspimagrps, dspimainfo, and dspimalncnt. Refer to the Cisco MGX 8850 Wide Area Edge Switch Command Reference for descriptions.

Adding and Configuring Connections on the AUSM/B

You can add and modify connections through the Cisco WAN Manager or the CLI. Refer to applicable documentation if you use the WAN Manager application. This section describes how to add an ATM connection through the CLI according to the rules for adding a standard connection or a management connection in the form of either a DAX con or a three-segment connection. See "Rules for Adding Connections" earlier in this chapter.

On the CLI of the AUSM/B:

Step 1 Execute the addcon command.

When you add a connection with addcon, the system automatically assigns the next available channel number, so addcon does not require it. However, some related commands require a channel number—cnfchanfst, cnfchanq, and cnfupcabr, for example. To see the channel number after you add a connection, use dspcons.

The addcon syntax is:

addcon <port_number> <vpi> <vci> <ConType> <SrvType> [Controller_Type] [mastership] [remoteConnID]

port number	port number is in the range 1-8.
vpi	vpi has a value in the range 0-255.
vci	vci can be in the range 0-65535 for a VCC or * for a VPC.
Conn type	is the connection type: 0=VCC, and non-0 is the local ID of a VPC in the range 1-1000.
Service Type	is the service type: 1=CBR, 2=VBR, 3=ABR, and 4=UBR.
mastership	is the mastership status of the endpoint. 1=master, and 2=slave. The default is slave, so you actually do not need to type a 2.
Controller_Type	is the optional controller specification. 1=PAR (the default}. 2=SPVC (PNNI).
connID	is entered at only the master end and consists of the node name, slot number, port number, vci, and vpi of the slave end.

Step 2 To configure usage parameter control (UPC) for the connection (channel), use cnfupccbr, cnfupcvbr, cnfupcabr, or cnfupcubr. Use dspcons to obtain the channel number.

cnfupccbr <port.vpi.vci> <enable/disable> <pcr[0+1]> <cdvt[0+1]> <IngPcUtil> <EgSrvRate> <EgPcUtil>

port.vpi.vci	identifies the connection.
enable/disable	is the UPC enable: 1=disable, 2=enable.
pcr[0+1]	is the peak cell rate. Without IMA, the range is as follows: T1, 10-3622 cells per second E1, 10-4528 cells per second clear E1, 10-4830 cells per second For IMA, multiply the line rate by the number of links.
cdvt[0+1]	is the cell delay variation tolerance for cells with CLP=0 and CLP=1. The range is 1-250000 micro seconds.
IngPcUtil	is the percent utilization on the ingress. The range is 1-127. The default is 0.
EgSrvRate	is the egress service rate. Without IMA, the range is as follows: T1, 10-3622 cells per second E1, 10-4528 cells per second clear E1, 10-4830 cells per second For IMA, multiply the line rate by the number of links
EgrPcUtil	is the percent utilization on the egress. The range is 1-127. The default is 0.

cnfupcvbr has the same syntax and parameters as cnfupcabr <port.vpi.vci> <enable> <pcr[0+1]> <cdvt[0+1]> <scr> <scr_police> <mbs> <IngPcUtil> <EgSrvRate> <EgPcUtil> <clp_tag>

port.vpi.vci	identifies the connection.
enable	is the enabled/disable for UPC: 1=Disable, 2=Enable.
pcr	is the peak cell rate. Without IMA, the range is as follows: T1, 10-3622 cells per second E1, 10-4528 cells per second clear E1, 10-4830 cells per second For IMA, multiply the line rate by the number of links.
cdvt	cdvt[0+1] is the cell delay variation tolerance for cells with CLP=[0+1]. The range is 1-250000 micro seconds.
scr	is the peak cell rate. Without IMA, the range is as follows: T1, 10-3622 cells per second E1, 10-4528 cells per second clear E1, 10-4830 cells per second For IMA, multiply the line rate by the number of links.
scr_police	specifies the type of scr policing: 1= CLP[0] cells, 2=CLP[0+1] cells, and 3=no SCR policing.
mbs	is the maximum burst size: the range is 1-5000 cells.
IngPcUtil	is the percent utilization on the egress. The range is 1-127. Default=0.
EgSrvRate	is the egress service rate. Without IMA, the range is as follows: T1, 10-3622 E1, 10-4528 clear E1, 10-4830 For IMA, multiply the line rate by the number of links
EgrPcUtil	is the percent utilization on the ingress. The range is 1-127. Default=0.
clp_tag	is the enable for CLP tagging: 1=disable, 2=enable.

cnfupcubr <port.vpi.vci> <enable> <pcr[0+1]> <cdvt[0+1]> <IngPc> <util> <clp_tag>

port.vpi.vci	identifies the connection.
enable	is the enabled/disable for UPC: 1=Disable, 2=Enable.
pcr	is the peak cell rate. Without IMA, the range is as follows: T1, 10-3622 E1, 10-4528 clear E1, 10-4830 For IMA, multiply the line rate by the number of links.
cdvt	cdvt[0+1] is the cell delay variation tolerance for cells with CLP=[0+1]. The range is 1-250000 micro seconds.
scr	is the peak cell rate. Without IMA, the range is as follows: T1, 10-3622 E1, 10-4528 clear E1, 10-4830 For IMA, multiply the line rate by the number of links.
scr_police	specifies the type of scr policing: 1= CLP[0] Cells, 2=CLP[0+1] cells, and 3=no SCR policing.
mbs	is the maximum burst size: the range is 1-5000 cells.
IngPc	is the percent utilization on the ingress. The range is 1-127. Default=0.
clp_tag	is the enable for CLP tagging: 1=disable, 2=enable.

Step 3 If the system has the ForeSight feature, use cnfchanfst to configure it.

cnfchanfst <port.vpi.vci> <enable> <fgcra_enable> <ibs> <pcr> <mcr> <icr>

port.vpi.vci	identifies the connection.
enable	is the enabled/disable for the ForeSight feature: 1=disable, 2=enable.
fgcra_enable	is the enabled/disable for the frame-based generic cell rate algorithm: 1=disable, 2=enable.
ibs	is the initial burst size in the range 0-5000 cells.
pcr	is the peak cell rate for the connection. Without IMA, the range is as follows: T1, 10-3622 E1, 10-4528 clear E1, 10-4830 For IMA, multiply the line rate by the number of links.
mcr	is the minimum cell rate for the connection. Without IMA, the range is as follows: T1, 0-3622 E1, 0-4528 clear E1, 0-4830 For IMA, multiply the line rate by the number of links.
icr	is the initial cell rate. Without IMA, the range is as follows: T1, 0-3622 E1, 0-4528 clear E1, 0-4830 For IMA, multiply the line rate by the number of links.

Step 4 If necessary, change the queue depths by using cnfchanq.

cnfchanq <port.vpi.vci> <discard_option> <vc_q_depth> <clp_thresh_high> <clp_thresh_low | epd_threshold> <efci_thresh>

port.vpi.vci	identifies the connection.
discard_option	is either 1 for clp hysteresis or 2 for frame-based.
vc_q_depth	is the ingress queue depth in the range 1-16000 cells.
clp_thresh_high	is the CLP high threshold in the range 1-16000 cells.
clp_thresh_low or epd_threshold	is the CLP low threshold in the range 1-16000 cells for CLP hysteresis-based discard. or is the EPD threshold in the range 1-16000 cells frame-based discard.
efci_thresh	is the EFCI threshold in the range 1-16000 cells.

Adding the Middle Segment of the Connection

For the middle segment, be sure to use the same connection type as the local segments on the SES (CBR, VBR, ABR, or UBR). The parameters directly map from those specified at the connection endpoint.

Frame Relay Service Module Connections

This section describes the features available on each of the Frame Service Modules (FRSMs). For descriptions of how to set up these cards and add connections, see the subsequent section titled "Configuring Frame Relay Service." The section consists of:

Brief descriptions of each model of the FRSM
Lists of features shared by all FRSMs
Lists of features for each model of the FRSM
Brief descriptions of the services

The models of the FRSM include eight-port T1 and E1 cards and high-speed modules. The higher speed modules support unchannelized E3 and HSSI as well as channelized and unchannelized T3.

The primary function of all FRSM models is to convert between the Frame Relay-formatted data and ATM/AAL5 cell-formatted data. For individual connections, you can configure the card to perform network interworking (NIW), service interworking (SIW), ATM to Frame Relay UNI (FUNI), or frame forwarding. An FRSM converts the header format and translates the address for:

Frame Relay port number and DLCI
ATM-Frame UNI (FUNI) port number and frame address or frame forwarding port
ATM virtual connection identifiers (VPI/VCIs)

Very High Speed Frame Service Modules

The Very High Speed Frame Service Modules (FRSM-VHS) support Frame Relay services on T3, E3, and HSSI interfaces. Up to 10 FRSM-VHS cards in any combination can operate in the switch. They should occupy upper slots whenever possible. The FRSM-VHS group on an SES consists of the:

MGX-FRSM-2CT3, which provides channelized Frame Relay service for up to 1000 user connections over two T3 lines on the BNC-2T3 back card (or line module).
MGX-FRSM-2T3E3, which provides unchannelized (clear-channel) Frame Relay service for up to 1000 user connections over two T3 lines (44.736 Mbps each) or two E3 lines (34.368 Mbps each) on a BNC-2T3 or BNC-2E3 back card. The MGX-FRSM-2T3E3 can also support subrate T3 or E3 for tiered DS3 on each physical port.
MGX-FRSM-HS2, which provides unchannelized Frame Relay service for up to 1000 user-connections over two HSSI lines on the SCSI2-2HSSI back card. The maximum rate for the card is 70 Mbps. Each port can operate either as DTE or DCE with incremental rates of NxT1 or NxE1 up to 52 Mbps.

Eight-Port Channelized and Unchannelized Frame Service Module

The AX-FRSM-8T1 and AX-FRSM-8E1 provide unchannelized Frame Relay service for up to 1000 user-connections on 8 T1 or E1 lines. The AX-FRSM-8T1c and AX-FRSM-8E1c provide channelized Frame Relay service for up to 1000 connections.

Frame Service Module Features

This section first lists the features common to all FRSM models then lists the features of each model. All FRSMs support:

Frame Relay-to-ATM Network Interworking (NIW) as defined in FRF.5.
Frame Relay-to-ATM Service Interworking (SIW) with or without translation as in FRF.8.
Frame forwarding.
ATM Frame-UNI.
Maximum frame sizes of 4510 bytes for Frame Relay and 4096 bytes for ATM-FUNI.
Per-virtual-circuit (VC) queuing in the ingress direction (towards the Cellbus). Traffic arriving at the network on a connection has a dynamically assigned buffer at the entrance to the switch. Buffer size depends on the amount of traffic and the service-level agreement (SLA).
Advanced buffer management. When a frame arrives, the depth of the queue for the LCN is compared against the peak queue depth scaled down by a specified factor. The scale-down factor depends on the amount of congestion in the free buffer pool. As the free buffer pool begins to empty, the scale-down factor is increased, preventing an excessive number of buffers from being held up by any single LCN.
Multiple, priority-level queuing to support class of service on the egress. The FRSM services egress queues according to a weighted priority. The priority depends on the percentage of logical port bandwidth needed by all connections of a particular type on a port. The FRSM supports a:

High-priority queue
Real-time Variable Bit Rate (rt-VBR) queue
Common queue for non-real-time Variable Bit Rate (nrt-VBR) and ABR connections
UBR queue

Initial burst per channel. After a period of silence, the FRSM sends a configurable number of bytes at a peak service rate.
The ForeSight option. This Cisco mechanism for managing congestion and optimizing bandwidth continuously monitors the utilization of ATM trunks. It proactively adjusts the bandwidth for connections to avoid queuing delays and cell discards.
Consolidated Link Layer Management (CLLM), an out-of-band mechanism to transport congestion related information to the far end.
Dual leaky bucket policing. Within the basic parameters such as committed burst, excess burst, and CIR, incoming frames go into two buckets: those to be checked for compliance with the committed burst rate and those to be checked for compliance with the excess burst rate. Frames that overflow the first bucket go into the second bucket. The buckets "leak" by a certain amount to allow for policing without disruption or delay of service.
Standards-based management tools. Each FRSM supports SNMP, TFTP for configuration and statistics collection, and a command line interface. The Cisco WAN Manager application provides full graphical user interface support for connection management. The CiscoView application provides equipment management.
MGX 8800-series and SES network management functions, including image download, configuration upload, statistics, telnet, UI, SNMP, trap, and MIBs.
OAM features: OAM F5 AIS, RDI, end-to-end or segment loopback as well as LMI and Enhanced LMI (ANNEX A, ANNEX D, Strata LMI).
Hot swappable redundancy (see sections for individual implementations).
CLLM (router ForeSight and NNI ForeSight operation).
Resource partitioning at the card level or port level (not needed in this release).

MGX-FRSM-2CT3 Features

The specific features are:

Up to 1000 user-connections
Two T3 lines
Up to 256 logical ports
Logical port speed from DS0 56 Kbps through DS1 1.536 Mbps
Support for five Class of Service (CoS) queues (high priority, rt-VBR, nrt-VBR, ABR, UBR)
1:1 redundancy through Y-cable redundancy (no Service Resource Module required)

MGX-FRSM-2T3E3 Features

The specific features are:

Up to 1000 user-connections
Two T3 or E3 lines coinciding with two logical ports
ADC Kentrox and Digital Link methods for supporting fractional T3 or E3 ports
Maximum possible number of DLCIs per port by using the Q.922 two-octet header format
Support for five Class of Service (CoS) queues (high priority, rt-VBR, nrt-VBR, ABR, UBR)
1:1 redundancy through Y-cable redundancy (no Service Resource Module required)
Fractional T3 speeds available through either the Digital Link or ADC Kentrox method

MGX-FRSM-HS2 Features

The specific features are:

Up to 1000 user-connections
Maximum 2 logical ports
Two HSSI lines with configurable line speeds in multiples of 56 Kbps or 64 Kbps
Selectable DTE or DCE mode for each port
In DCE mode, per port clock speeds of NxT1 and NxE1 up to 52 Mbps
Various DTE/DCE loopback operations
Maximum possible number of DLCIs per port by using the Q.922 two-octet header format.
1:1 redundancy through a Y-cable

Eight-Port FRSM Features

The specific features are:

Up to 1000 user-connections.
Fractional FRSMs support a single 56-Kbps or multiple 64-Kbps user-ports (FR-UNI, FR-NNI, FUNI, and frame forwarding) per T1 or E1 line. Channelized FRSMs (AX-FRSM-8T1c and AX-FRSM-8E1c) support multiple 56 Kbps or N x 64 Kbps user-ports per line up to the physical line bandwidth limit.

If the FRSM uses an SMB-8E1 back card, 1:1 redundancy is available through Y-cabling .

Frame Relay-to-ATM Network Interworking

FR-ATM network interworking (NIW), illustrated in Figure E-7, supports a permanent virtual connection (PVC) between two Frame Relay users over a Cisco network or a multi-vendor network. The traffic crosses the network as ATM cells. To specify NIW for a connection, add the connection with a channel type of "network interworking."

Figure E-7: SES/IGX/BPX Network with NIW Connections

In addition to frame-to-cell and DLCI-to-VPI/VCI conversion, the NIW feature maps cell loss priority (CLP) and congestion information from Frame Relay-to-ATM formats. Subsequent sections contain the details. You can modify the CLP and congestion indicators for individual connections.

Congestion Indication for NIW Connections

You can modify the CLP and congestion parameters for individual connections. On the CLI., use the cnfchanmap command. In the Frame Relay-to-ATM direction, you can configure each Frame Relay-ATM NIW connection for one of the following CLP-to-DE mapping schemes:

DE bit in the Frame Relay frame is mapped to the CLP bit of every ATM cell generated by the segmentation process.
CLP is always 0.
CLP is always 1.

In the ATM-to-Frame Relay direction, you can configure each Frame Relay/ATM NIW connection for one of the following CLP-to-DE mapping schemes:

If at least one ATM cell from a frame has CLP=1, the DE field of the Frame Relay frame is set.
No mapping from CLP to DE.

Congestion on the Frame Relay/ATM network interworking connection is flagged by the EFCI bit. The EFCI setting depends on the direction of the traffic. In the Frame Relay-to-ATM direction, EFCI is always set to 0. In the ATM-to-Frame Relay direction, the FECN bit of the Frame Relay frame is set if the EFCI field in the last received ATM cell of a segmented frame is set.

PVC Status Management

The management of ATM layer and FR PVC status management can operate independently. The PVC status from the ATM layer is used when determining the status of the FR PVC. However, no direct actions of mapping LMI A bit to OAM AIS is performed.

Frame Relay-to-ATM Service Interworking

By specifying a service interworking (SIW) channel type when you add a Frame Relay PVC to an FRSM, all data is subject to SIW translation and mapping in both the Frame Relay-to-ATM and ATM-to-Frame Relay directions. Figure E-8 is an illustration of typical SIW connections.

Figure E-8: SES/IGX/BPX Network with SIW Connections

In addition to frame-to-cell and DLCI-to-VPI/VCI conversion, SIW maps cell loss priority and congestion data between the Frame Relay and ATM formats and is FRF.8-compliant. It provides full support for routed and bridged PDUs, transparent and translation modes, and VP translation.

Cell Loss Priority

In addition to frame-to-cell and DLCI-to-VPI/VCI conversion, the SIW feature maps cell loss priority (CLP) and congestion information from Frame Relay-to-ATM formats.

You can modify the CLP and congestion parameters for individual connections. On the CLI., use the cnfchanmap command. In the Frame Relay-to-ATM direction, you can specify one of the following discard eligibility (DE)-to-cell loss priority (CLP) schemes for an individual SIW connection:

DE bit in the Frame Relay frame is mapped to the CLP bit of every ATM cell generated by frame segmentation.
CLP is always 0.
CLP is always 1.

In the ATM-to-Frame Relay direction, you can specify a CLP-to-DE mapping scheme for an individual connection:

If one or more ATM cells belonging to a frame has CLP=1, the DE field of the Frame Relay frame is set.
DE is always 0.
DE is always 1.

Congestion Indication

This section describes congestion indictors. You can modify the CLP and congestion indicators for individual connections. On the CLI, use the cnfchanmap command. In the Frame Relay-to-ATM direction, you can configure a Frame Relay-to-ATM SIW connection for one of the following Forward Explicit Congestion Notification (FECN)-to-Explicit Forward Congestion Indicator (EFCI) schemes:

FECN bit in the Frame Relay frame is mapped to the EFCI bit of every ATM cell generated by the segmentation process of the frame.
EFCI is always 0.
EFCI is always 1.

In the ATM-to-Frame Relay direction, service interworking connections use the following EFCI to FECN/BECN mapping schemes:

If the EFCI bit in the last ATM cell of a segmented frame received is set to 1, the FECN of the Frame Relay frame is set to 1.
BECN is always set to 0.

Command and Response Mapping

The FRSM provides command and response mapping in both directions:

In the Frame Relay-to-ATM direction, the FRSM maps the C/R bit of the received Frame Relay frame to the CPCS-UU least significant bit of the AAL5 CPCS PDU.
In the ATM-to-Frame Relay direction, the FRSM maps the least significant bit of the CPCS-UU to the C/R bit of the Frame Relay frame.

Translation and Transparent Modes

Each service interworking (SIW) connection can exist in either translation or transparent mode. In translation mode, the FRSM translates protocols between the FR NLPID encapsulation (RFC 1490) and the ATM LCC encapsulation (RFC 1483). In transparent mode, the FRSM does not translate. Translation mode support includes address resolution by transforming address resolution protocol (ARP, RFC 826) and inverse ARP (inARP, RFC 1293) between the Frame Relay and ATM formats.

Frame Forwarding

You can configure an individual port for frame forwarding. Frame forwarding is the same as standard Frame Relay except that the FRSM:

Does not interpret the two-byte Q.922 header.
Maps all received frames to a specific connection if it exists, otherwise it discards the frames.
Does not map between DE and CLP or between FECN and EFI.
Does not support statistics for "Illegal header count" or "Invalid DLCI."
Does generate statistics for "Discarded frame count due to no connection."

ATM/Frame-to-User Network Interface

All FRSMs support the ATM Frame User-to-Network Interface (FUNI). When a frame arrives from the FUNI interface, the FRSM removes the 2-byte FUNI header and segments the frame into ATM cells by using AAL5. In the reverse direction, the FRSM assembles ATM cells from the network into a frame by using AAL5, adds a FUNI header to the frame, and sends it to the FUNI port.

Loss Priority Indication

The FRSM maps the loss priority indication for both directions:

In the FUNI to ATM direction, the FRSM maps the CLP bit in the FUNI header to the CLP bit of every ATM cell that it generates for the FUNI frame.
In the ATM-to-FUNI direction, the FRSM always sets the CLP bit in the FUNI header to 0.

Congestion Indication

The FRSM maps congestion indication in both directions:

In the FUNI-to-ATM direction, it sets EFCI to 0 for every ATM cell it generates by segmentation.
In the ATM-to-FUNI direction, it sets the CN bit in the FUNI header to 1 if the EFCI field in the last ATM cell of a received, segmented frame is 1. The two reserve bits (the same positions as C/R and BECN in Frame Relay header) are always 0.

Configuring Frame Relay Service

This section first describes how to configure the FRSM card, lines, and ports, then describes how to add connections. The descriptions are for the CLI execution of the tasks. You can also configure the FRSM card, lines, and ports by using the CiscoView application. Refer to the CiscoView documentation for the directions. Also, the easiest way to add connections is by using the Cisco WAN Manager application. For full details of how to set up a connection through the WAN Manager GUI, refer to the Cisco WAN Manager Operations manual.

Configuring the FRSM Cards, Lines, and Ports

This section describes how to configure card-level parameters, physical lines, and logical ports on the FRSM-series cards.

Step 1 If necessary, modify the resource partitioning for the whole card by executing the cnfcdrscprtn command. You can view resource partitioning through dspcdrscprtn.

cnfcdrscprtn <number_PAR_conns | number_PNNI_conns | number_TAG_conns>

number_PAR_conns is the number of connections in the range 0-1000 available to the PAR controller.

number_PNNI_conns is the number of connections in the range 0-1000 available to a PNNI controller.

number_TAG_conns is the number of connections in the range 0-1000 available to the Tag controller.

For example, you could reserve 300 connections for each controller on the FRSM with:

cnfcdrscprtn 300 300 300

Step 2 If the physical line is not yet active, use the addln command to activate it. The only argument addln takes is the line number.

Step 3 If necessary, modify the lines by using cnfln on the MGX-FRSM-2CT3, MGX-FRSM HSSI cards, AX-FRSM-8T1 or AX-FRSM-8E1. Use cnfds3ln on the MGX-FRSM-2CT3 and MGX-FRSM-2T3E3. The cnfln and cnfds3ln commands affect different aspects of the MGX-FRSM-2CT3.

Step 4 If the logical port does not exist or is not the appropriate type (Frame Relay, FUNI, or frame forwarding), execute addport to create the appropriate type of port. If the logical port already exists, go to the step for adding a connection using the addcon command (or addchan if you must use NSAP addressing format). The parameters for addport depend on the type of FRSM:

For unchannelized VHS cards (MGX-FRSM-2T3E3, MGX-FRSM-HS2):

addport port_num line_num port_type

port_num is the logical port number in the range 1-2. The mapping between a logical port and a line is one-to-one for these cards. Note that the maximum committed information rate (CIR) on each line for these cards is 0-44210000 bps for MGX-FRSM-2T3, 0-34010000 bps for MGX-FRSM-2E3, and 0-51840000 bps for MGX-FRSM-HS2. Specify CIR with addcon (or addchan if necessary).
line_num is the physical line number in the range 1-2.
port_type is a number representing the mode of operation for the logical port:
1 for Frame Relay; 2 for FUNI mode-1a; and 3 for frame forwarding.

For the channelized VHS card (MGX-FRSM-2CT3):

addport port_num line_num ds0_speed begin_slot num_slot port_ type

port_num is the logical port number in the range 1-256. When you subsequently add a connection through the preferred command addcon or the addchan command (which requires NSAP format), you must indicate a logical port by using this singular port_num regardless of the number of DS0s. (You can add 1-24 DS0s to a single port_num through the other addport parameters.)
line_num is the DS1 number in the range 1-56 to which you assign the DS0 when both lines are active. If you activate only one line, the range is 1-28. You can assign up to 24 contiguous DS0s to one DS1. Each physical line supports up to 28 DS1s. The number of DS0s cannot span more than DS1.
ds0_speed is a number representing the DS0 speed: 1 for 56 Kbps or
2 for 64 Kbps.
begin_slot is the beginning DS0 timeslot in 1 base. For example, on port number 50, you could make begin_slot=9 then specify num_slot to be in the range 1-16.
num_slot is the number of DS0s in the associated DS1. Note that the number of DS0s cannot be such that the logical port spans more than DS1.
port_type is a number representing the mode of operation for the logical port:
1 for Frame Relay; 2 for FUNI mode-1a; and 3 for frame forwarding.

For AX-FRSM-8T1 and AX-FRSM-8E1:

addport port_num line_num ds0_speed begin_slot num_slot port_type

port_num is the logical port number in the range of either 1-192 for T1 or 1-248 for E1. When you subsequently add a connection through the preferred command addcon or the addchan command (which requires NSAP format), you must indicate a logical port by using this singular port_num regardless of the number of DS0s. (You can add 1-24 DS0s to a single line through the other addport parameters.)
line_num is the physical line number in the range 1-8.
ds0_speed is a number representing the DS0 speed: 1 for 56 Kbps or
2 for 64 Kbps.
begin_slot is the beginning DS0 timeslot in 1 base. For example, on port number 50, you could make begin_slot=9 then specify num_slot to be in the range 1-16.begin_slot is the beginning timeslot in 1 base.
num_slot is the consecutive DS0s that each connection on port_num has.
port_type is a number representing the mode of operation for the logical port:
1 for Frame Relay; 2 for FUNI mode-1a; and 3 for frame forwarding.

Step 5 Configure resources for the port as needed by executing cnfportrscprtn. To see the partitioning, use dspportrscprtn. The description has a high and low-bandwidth version:

cnfportrscprtn <port_num> <controller> <percent BW> <low DLCI> <high DLCI> <max LCN>

For FRSM-VHS cards:

port_num is the port number in the range 1-2 for MGX-FRSM-2T3E3 and MGX-FRSM-HS2 or 1-256 for MGX-FRSM-2CT3.
controller is a number representing the controller: 1=PAR, 2=PNNI, and 3=Tag.
percent BW is the percentage of the bandwidth in the range 0-100 and applies to both egress and ingress.
low DLCI is in the range 0-1023.
high DLCI is in the range 0-1023.
max LCN is the maximum number of logical connections available to the controller on this port. The ranges are 1-4000 for MGX-FRSM-2CT3 and 1-2000 for MGX-FRSM-2T3E3 and MGX-FRSM-HS2.

For AX-FRSM-8T1 or AX-FRSM-8E1:

port_num is the logical port number in the range 1-192 for T1 or 1-248 for E1.
controller-name is PAR, PNNI, or TAG.
percent BW is the percentage of the bandwidth in the range 0-100 and applies to both egress and ingress.
low DLCI is in the range 0-1023.
high DLCI is in the range 0-1023.
max LCN is the maximum number of logical connections available to the controller on this port. The range is 1-1000.

Adding a Frame Relay Connection

This section describes how to add a Frame Relay connection according to the rules for adding a standard connection or a management connection in the form of either a DAX con or a three-segment connection. See "Rules for Adding Connections" earlier in this chapter.

Step 1 Add a connection by using addcon. If the application requires the NSAP form for the endpoint, use addchan as described in the command reference.

The system automatically assigns the next available channel number, so the addcon command does not require it. However, some related commands require a channel number. To see the channel number after you add a connection, use dspcons.

On the FRSM-VHS cards (2CT3, 2T3E3, or HS2):

addcon <port> <DLCI> <cir> <chan_type> <egress_service_type> [CAC] <controller_type> <mastership> [connID] <controllerID>

port is the logical port number on the MGX-FRSM-2CT3 in the range 1-256. On the MGX-FRSM-2T3E3 and MGX-FRSM-HS2, the range is 1-2. (See addport step if necessary.)
DLCI is the DLCI number in the range 0-1023 (2CT3/2T3/2E3/HS2).
cir is the committed information rate in one of the following ranges:
for 2CT3, 0-1536000 bps; for 2T3, 0-44210000 bps; 2E3, 0-34010000 bps; and
for HS2, 0-51840000 bps.

chan_type specifies the type of connection: 1=NIW, 2=SIW-transparent mode;
3=SIW with translation; 4=FUNI, and 5=frame forwarding.

egress_service_type is a number that specifies the type of queue on the egress:
1=high priority; 2=real-time VBR, 3=nonreal-time VBR; 4=ABR; and 5=UBR.

CAC optionally enables connection admission control; 1=enable. 2=disable (default). With CAC enabled, the system adds the resource consumption represented by adding the connection to the total resources consumed on a logical port.

controller_type is the controller type for signaling connections: 1 (the default) specifies a PVC and applies to PAR. 2 specifies a SPVC and applies to PNNI.

mastership indicates if this end of the connection is master or slave: 1=master, 2=slave.

connID is the connection identifier at the remote end. It appears in the syntax as an optional parameter because it is mandatory only when you add the connection at the master end. See "Rules for Adding Connections" at the beginning of this chapter. connID can have one the following formats according to the slave endpoint:

Nodename.SlotNo.PortNo.DLCI

Nodename.SlotNo.PortNo.ControllerId.DLCI

Nodename.SlotNo.PortNo.VPI.VCI for ATM endpoint

controllerID is a number indicating the type of network control application:
1=PAR, 2=PNNI, 3=MPLS

For AX-FRSM-8T1 and AX-FRSM-8E1:

addcon <port> <DLCI> <cir> <chan_type> [CAC] <controller_type> <mastership> <connID> <controllerID>

port is the logical port number in the range 1-192 for T1 or 1-248 for E1. (See addport step if necessary.)
DLCI is the DLCI number in the range 0-1023.
cir is the committed information rate in one of the following ranges:
for T1, 0-1536000 bps for T1; for E1, 0-2048000 bps.
chan_type specifies the type of connection: 1=NIW, 2=SIW-transparent mode;
3=SIW with translation; 4=FUNI, and 5=frame forwarding.
CAC optionally enables connection admission control: 1=enable. 2=disable (default).
controller_type is the controller type for signaling: 1=PVC (PAR), the default, 2=SPVC (PNNI).
mastership indicates if this end of the connection is master or slave: 1=master, 2=slave.
connID is the connection identifier at the remote end and can have one the following formats according to the type of card at the slave endpoint:

NodeName.SlotNo.PortNo.DLCI

NodeName.SlotNo.PortNo.ControllerId.DLCI

NodeName.SlotNo.PortNo.VPI.VCI for ATM endpoint

: If the remote end is a SES-PXM, the port number can be in the range 1-32 for user connections or 34 for inband management connections (stand-alone node only).

controllerID is a number indicating the type of network control application:
1=PAR, 2=PNNI, 3=TAG.

Step 2 If necessary, modify the CLP and congestion indicator fields by using cnfchanmap:

cnfchanmap <chan_num> <chanType> <FECN/EFCI> <DE to CLP> <CLP to DE>

chan_num	is the channel (connection) number. The ranges are: 2CT3, 16-4015 2T3, 2E3, HSSI, 16-2015 T1, E1, 16-1015
chanType	is a number in the range 1-5 indicating the service type for the connection. 1=NIW 2=SIW in transparent mode 3=SIW in translation mode 4=FUNI 5=frame forwarding
FECN/EFCI	is a number in the range 1-2 that specifies the mapping between FECN and EFCI fields. 1=map EFCI (SIW only) 2=set EFCI to 0
DE to CLP	is a number in the range 1-3 that specifies the DE to CLP mapping. 1=map DE to CLP 2=set CLP to 0 3=set CLP to 1
CLP to DE	is a number in the range 1-4 that specifies the CLP to DE mapping. 1=map CLP to DE 2=set DE to 0 3=set DE to 1 4=ignore CLP (NIW only)

Establishing the Middle Segment of the Frame Relay Connection

For a three-segment connection, you must establish a middle segment across the IGX/BPX network. Execute addcon at one of the IGX 8400 series nodes, as follows.

For slot and port number, specify slot and port of the IGX UXM connected to SES.
For VPI and VCI, specify the VPI and VCI at the endpoint on the SES-PXM.
For Nodename, use the name of the IGX 8400-series switch at the far end of the connection.
For Remote Channel, specify the slot and port number of the UXM port attached to the
SES at the far end. Specify the VPI as the slot number of the remote SES FRSM connected to the IGX 8400-series switch, and specify VCI as the LCN of the Frame Relay connection at the remote SES.
Specify the type of connection. Enter ATFST if the ForeSight feature is operating and ATFR if this feature is not operating.

Specify the other addcon bandwidth parameters such as MCR, PCR, %Util, and so on.

Minimum Cell Rate (MCR) is only used with the ForeSight feature (ATFST connections).
MCR and Peak Cell Rated (PCR) should be specified according to the following formulae.
MCR=CIR *3/800 cells per second.
PCR=AR * 3/800 cells per second but less than or equal to 6000.
AR=Frame Relay port speed in bps.

For example:

AR equals 64K, PCR=237, or
AR speed equals 256K, PCR=950, or
AR speed equals 1536K, PCR=5703

For example,

The preceding MCR and PCR formulae are predicated on a relatively small frame size of 100 octets, and even smaller frame sizes can result in worse-case scenarios. For example:

For a frame size of 64 octects the PCR formula becomes:	PCR=AR * 2/512 cells per sec
For a frame size of 43 octects the PCR formula becomes:	PCR=AR * 2/344 cells per sec

% Util should be set to the same value as that used for the Frame Relay segments of the connection.

Circuit Emulation Service Module Connections

The main function of the eight-port Circuit Emulation Service Module (MGX-CESM-8T1 and MGX-CESM-8E1) is to provide a constant bit rate (CBR) circuit emulation service by converting data streams into CBR AAL1 cells for transport across an ATM network. The CESM supports the CES-IS specifications of the ATM Forum.

The eight-port CESM lets you configure individual physical ports for structured or unstructured data transfer. The card sets consist of an MGX-CESM-8T1 or MGX-CESM-8E1 front card and one of the following back cards:

RJ48-8T1-LM

R-RJ48-8T1-LM

RJ48-8E1-LM

R-RJ48-8E1-LM

SMB-8E1-LM

Structured Data Transfer

If you configure an individual port for s tructured data transfer, the eight-port CESM supports:

Synchronous timing.
Superframe or Extended Superframe for T1.
N x 64 Kbps, fractional DS1/E1 service (contiguous time slots only). You can map a N x 64-Kbps channel to any VC.
CAS robbed bit for T1 (ABCD for ESF and SF frames) and CAS for E1 (channel 16).
CCS channel as a transparent data channel.
A choice of partially filled cells.
Idle detection and suppression for 64-Kbps CAS connections.
Loopback diagnostics on a line or a connection (addlnloop, tstcon, and tstdelay commands).

Unstructured Data Transfer

If you configure an individual port for u nstructured data transfer, the eight-port CESM supports:

Synchronous or asynchronous timing at T1 (1.544 Mbps) or E1 (2.048 Mbps) rates. For asynchronous timing, you can select its basis as either SRTS and adaptive clock recovery.
The special port type framingOnVcDisconnect. This port type prevents a remote-end CPE from going to LOF by placing a line in remote loopback mode when the CESM determines that a connection deletion or suspension occurred at the network-side ATM interface.
Ability to detect and display a yellow alarm for the ESF framing on a T1 line.
Loopback diagnostics on a line or a connection (addlnloop, tstcon, and tstdelay commands).

Configuring Service on an Eight-Port CESM

This section describes the steps for setting up a CESM and adding connections. The maximum number of connections is 248 on the MGX-CESM/B-8E1 and 192 on the MGX-CESM/B-T1. Use either the CLI or the Cisco WAN Manager application to set up a CESM and add connections. The following list shows the fundamental tasks and applicable CLI commands:

Optionally configure redundancy a the card level (addred and possibly addlink on the SES-PXM)
Optionally modify resource partitions at the card level (cnfcdrscprtn)
Activate a physical line (addln) and optionally configure the line (cnfln)
Create logical ports for structured data transport on a physical line (addport)
Optionally modify resource partitions at the port level (cnfportrscprtn)
Add connections by using addcon (or addchan if NSAP addressing is necessary)

For CESM-related commands, see the list of service module commands at the beginning of the Cisco MGX 8850 Wide Area Edge Switch Command Reference. Also, each command description in the command reference lists related commands. For example, it shows display commands that relate to addition commands.

Configuring the Card, Lines, and Ports

This section describes how to configure card, line, and port-level parameters for a CESM through the CLI. If you use the CiscoView application, refer to the CiscoView documentation. On the CLI, the command sequence is:

Step 1 addln <line number>

where line number is in the range 1-8. You can modify line characteristics with cnfln.

Step 2 Optionally execute cnfln to modify line characteristics from the defaults. (Use dspln or dsplns to check). The syntax for cnfln is:

cnfln <line_num> <line_code> <line_len> <clk_src> [E1-signaling]

line_num is a line number in the range 1-8.
line_code is a number that specifies the line coding: 2=B8ZS (T1), 3=HDB3 (E1), and
4=AMI (T1/E1)
line_len is the line length: 10-15 for T1, 8 for E1 with SMB line module, 9 for E1 with RJ48 line module
clk_src is a number specifying the clock source: 1 for loop clock, 2 for local clock
E1-signalling specifies the E1 signaling. The possible entries are:

CAS, which specifies CAS and no CRC
CAS_CRC, which specifies CAS with CRC
CCS, which specifies CCS and no CRC
CCS_CRC, which specifies CCS with CRC
CLEAR: CLEAR channel

Step 3 Create a logical port with addport if the application requires N x 64-Kbps channels:

addport <port_num> <line_num> <begin_slot> <num_slot> <port_type>

port_num is the logical port number in the range 1-192 for T1 or 1-248 for E1
line_num is the number of the physical line in the range 1-8.
begin_slot is the beginning timeslot number in the frame: for T1, 1-24. For E1 2-32 with CCS signaling or 2-16 and 17-32 with CAS signaling.
num_slot is the number of timeslots in the frame for the current port (port_num).
port_type is: 1=structured, 2=unstructured, 3=framing on VC disconnect.

Step 4 Configure resources at the port level as needed by executing cnfportrscprtn:

cnfportrscprtn <port_num> <controller_name>

port_num is the logical port number in the range 1-192 for T1 or 1-248 for E1.
controller_name is the name of the network control application. Enter one of the following strings: PAR, PNNI, or MPLS.

Adding and Modifying CESM Connections

Use either the Cisco WAN Manager application or the CLI to add or modify connections. If you use the WAN Manager application, refer to the Cisco WAN Manager Operations Guide.

The preferred command is addcon. If the application requires NSAP addressing, use addchan to add the connection and cnfchan if you need to modify it. Refer to the command reference for the syntax. On the CESM CLI:

Step 1 Add a connection through the preferred command addcon. (Alternatively, you can use addchan if your application requires the NSAP format of endpoint specification.)

Execute addcon at both ends of the connection—unless the remote endpoint is on port 34 of a SES-PXM (see the note at the end of this step). The maximum number of connections for the MGX-CESM-8T1 is 248 and 192 for the MGX-CESM-8E1. Note that, because you can add only one connection per port, addcon does not request a connection number.

The syntax for addcon is:

addcon <port_num> <sig_type> <partial_fill> <cond_data> <cond_signalling> [controller_type] [mastership] [remoteConnId]

port_num is the logical port number. This port must already exist (see addport).
sig_type is a number indicating the type of signaling: 1 specifies basic signaling,
2 specifies E1 CAS, 3 specifies ds1SFCAS (DS1 Superframe CAS), and 4 specifies ds1ESFCAS (DS1 Extended Superframe CAS).
partial_fill is a number representing the number of bytes in a cell. It can be either 0 to specify that the cell must contain 48 bytes or a non-0 value that fixes the number of bytes in each cell. For structured E1, the partial_fill range is 20-47 bytes. For structured T1, the range is 25-47 bytes. Unstructured T1 or E1 can be 33-47 bytes.
cond_data is the conditioning data in case of loss of signal (LOS). It is always 255 for unstructured data transfer or 0-255 for structured data transfer. For a voice connection, the larger the cond_data value, the louder the hiss heard in case of LOS.
cond_signalling is the string of condition signaling bits that you specify with a decimal number in the range 0-15, where, for example, 15=1111, and 0=0000. These bits represent the ABCD signaling to the line or network when an underflow occurs.
mastership indicates whether this endpoint is the master or slave. 1=master.
2=slave (default).
remoteConnId is the identification for the connection at the slave end. The format is nodename.slot_number.port_number.vpi.vci.

Step 2 Optionally, you can use cnfcon to modify an individual connection. This command requires a channel number. If you add a connection by using addcon, you do not need to specify a channel number because the system automatically uses the next available number. To obtain the channel number for cnfcon, execute dspcons.

cnfcon <port_num> <CDVT> <CLIP> <bufsize> <cbrclkmode> <isenable> <exttrigis>

port_num is the port number.
CDVT is a tolerable variation for the arrival time of cells. For T1, the range is 125-24000 micro seconds. For E1, the range is 125-26000 micro seconds. Both require 125-microsecond increments.
CLIP is CellLossIntegrationPeriod, an amount of time a connection can be in an error condition before an alarm is declared. The range is 1000-65535 milli seconds.
bufsize is the egress buffer size in bytes. These buffers are used for tolerating variations in the cell delay. The size can be automatically computed, or you can enter a specific size in bytes.
cbrclkmode is the clock mode for a circuit emulation connection. The values are 1-3. 1 is synchronous. 2 is SRT. 3 is adaptive. SRT and adaptive are asynchronous clocking schemes.
isenable is a flag to enable the idle code (ABCD signalling bits) based cell suppression feature on a connection. If you enable this feature, idle suppression logic is activated so that suppression begins when valid idle ABCD bits are detected. This feature is valid for only single DS0 connections. Possible values are 1 to enable and 2 to disable.
exttrigis is an enable for an external idle suppression trigger. With this feature enabled, the logic forcefully suppresses cells on a single DS0 connection. Enter a 1 to disable idle suppression or a 2 to enable idle suppression.

Step 3 Optionally, you can configure connection parameters for the network segment of a three-segment connection:

cnfswparms <chan_num> <mastership> <vpcflag> <conn_service_type> (=cos)
<route_priority> <max_cost> <restrict_trunk_type> <pcr> <mcr> <pct_util>

chan_number is the connection in the range 32-279.
mastership specifies the current endpoint as master or slave. 1=master. 2=slave (default)
vpcflag indicates whether the connection is a VPC or a VCC: 1=VPC, and 2=VCC.
conn_service_type selects the type of service for the connection: 1=cbr, 2=vbr, 3 is not used, 4=ubr, 5=atfr, 6=abrstd, and 7=abrfst.
route_priority is the priority of the connection for re-routing. The range is 1-15 and is meaningful only in relation to the priority of other connections.
max_cost is a number establishing the maximum cost of the connection route. The range is 1-255 and is meaningful only in relation to the cost of other connections.
restrict_trunk_type is a number that specifies the type of trunk this connection can traverse. The numbers are 1 for no restriction, 2 for terrestrial trunk only, and 3 for satellite trunk only.
pcr is the peak cell rate.
mcr is the minimum cell rate. The range is 1-65535 cells per second.
pct_util is the percent utilization in the range 1-100.

Table of Contents

Resource Partitioning

Partitioning Resources on the Broadband Interface

Modifying the Resource Partitioning

PVC Status Management

Command and Response Mapping

Loss Priority Indication

Congestion Indication