Cisco 6130 with NI-2 Hardware Installation Guide
Ch 1: Product Overview
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Table of Contents

Product Overview
 Introduction to the Cisco 6130 with NI-2 System
 Cisco 6130 Chassis Overview
 Cisco 6120 POTS Splitter Overview
 Management Software

Product Overview

This chapter provides an overview of the Cisco 6130 with NI-2 system. This chapter contains the following sections:

Introduction to the Cisco 6130 with NI-2 System

The Cisco 6130 with NI-2 system is part of the Cisco DSL product family that provides end-to-end service by carrying data between a subscriber's home or office, a telephone central office (CO), and various networks. The Cisco 6130 with NI-2 system sends and receives subscriber data (often Internet service) over existing copper telephone lines, concentrating all traffic onto a single high-speed trunk for transport to the Internet or a corporate intranet. Asymmetric digital subscriber line (ADSL) and symmetrical digital subscriber line (SDSL) customer premises equipment (CPE) devices, which are connected to PCs or routers at the subscriber site, modulate data so that the data can travel over telephone lines to the Cisco 6130 digital subscriber line access multiplexer (DSLAM) at the CO.

The Cisco 6130 with NI-2 system may include the following components:

  • Cisco 6130 chassis.
  • Cisco 6120 chassis or third-party POTS splitter—A passive plain old telephone service (POTS) splitter.
  • Management software—Provisions and manages the Cisco 6130 system.
    • Cisco IOS—A command-line interface (CLI) that is available for network element provisioning.
    • Cisco DSL Manager (CDM)—A graphical user interface (GUI) designed to configure and manage the 6xxx series of Cisco IOS software-based DSL access multiplexers (DSLAMs). CDM provides the following areas of network management—fault, configuration, performance, and security. CDM runs with the Cisco Element Manager Framework (EMF); both are installed on Sun workstations.

Cisco EMF is based on an object model in which network elements or modules represent the managed entity. Each object is defined by a class and specific attributes. An object can represent a network element or a more abstract entity such as a link relationship, a network, or a container such as a site, shelf, or region.

Note    See the "Hardware Specifications" section for minimum software and network management release requirements per Cisco 6130 chassis component.

Features

The Cisco 6130 with NI-2 system includes the following features:

  • Supports both ADSL and SDSL
  • Carrierless amplitude and phase modulation (CAP) rate adaptive DSL (RADSL), ANSI T1.413 Discrete Multitone (DMT), and G.lite modem support
  • Small footprint that terminates up to 128 ADSL/SDSL subscriber lines
  • NEBS compliant, 23-inch chassis
  • Manageable through Cisco IOS or CDM
  • Supports subtending of as many as twelve Cisco 6130 chassis, for a maximum of 1664 subscribers
  • Supports the entire range of virtual channel identifier (VCI)/virtual path identifier (VPI) connections; none of the connections are limited by memory
  • ATM Forum UNI Versions 3.1 and 4.0 compliant
  • Nonblocking ATM switching architecture
  • Allows up to four ATM classes of service simultaneously
  • Supports NI-2 card cold redundancy and automatic protection switching (APS) link redundancy

Configurations

This guide details the installation steps for the following configurations:

  • Cisco 6130 with a POTS splitter
  • Cisco 6130 without a POTS splitter
  • Subtended network

Cisco 6130 with a POTS Splitter Configuration

The Cisco 6130 with a POTS splitter configuration supports up to 128 subscribers through directly connected modems using ADSL technology. To increase subscribership, you can add additional chassis to your system.

This configuration includes the following hardware components:

  • Cisco 6130—Maximum of two chassis are allowed per rack.
    • Quad-port DMT ATU-C line cards (4xDMTs).
    • Quad-port flexi ATU-C line cards (4xflexis)—Configure as CAP, DMT, or G.lite.
    • One or two NI-2 cards—DS3/2DS3 or OC-3c/OC-3c.
  • Cisco 6120 or a third-party POTS splitter.
    • DMT POTS cards (use in either the Cisco 6120 or the third-party POTS splitter).
  • Fan tray—A fan tray must be installed under each Cisco 6130 chassis.

Figure 1-1 shows the components for a Cisco 6130 chassis with a POTS splitter configuration.


Figure 1-1   Cisco 6130 with a POTS Splitter Configuration


Note    Either a Cisco 6120 or a third-party POTS splitter can be used in a Cisco 6130 with a POTS splitter configuration.

A system configuration using quad-port line cards requires a POTS splitter capacity of 128 subscriber ports. Each Cisco 6120 POTS splitter supports up to 64 subscribers. Depending on the POTS splitter selected for your configuration (Cisco 6120 or third-party), the installation of an additional POTS splitter may be necessary.

Both a Cisco 6120 and a third-party POTS splitter can be used with the same Cisco 6130 chassis; however, Cisco does not supply the special cables required for this type of POTS configuration. For third-party POTS splitter port mapping and cable pinout specifications, consult the appropriate vendor documentation.

Cisco 6130 Without a POTS Splitter Configuration

The Cisco 6130 without a POTS splitter configuration supports up to 128 subscribers through directly connected modems using either ADSL or SDSL technology. To increase subscribership, you can add additional chassis to your system.

This configuration includes the following hardware components:

  • Cisco 6130—Maximum of two chassis are allowed per rack.
    • 4xDMTs.
    • 4xflexis—Configure as CAP, DMT, or G.lite.
    • Quad-port STU-C line cards (4xSDSLs).
    • One or two NI-2 card(s)—DS3/2DS3 or OC-3c/OC-3c.
  • Fan tray—A fan tray must be installed under each Cisco 6130 chassis.

In this configuration, the Cisco 6130 connects directly to the main distribution frame (MDF).

Figure 1-2 shows the components for a Cisco 6130 without a POTS splitter configuration.


Figure 1-2   Cisco 6130 Without a POTS Splitter Configuration


Subtended Network Configuration

A subtended network configuration

  • Services and aggregates the data from one or more remotely located Cisco 6130 chassis into a subtending host chassis to take advantage of the data network interface on the subtending host chassis
  • Provides additional benefits by reducing the number of ATM edge-switch ports that are required to terminate the chassis
  • Supports both a Cisco 6130 with a POTS splitter and a Cisco 6130 without a POTS splitter configuration
  • Supports NI-2 card cold redundancy in subtended node chassis if both the subtending host chassis and the subtended node chassis have primary and secondary NI-2 cards installed
Note    An NI-2 card failure on a node in a subtend tree or daisy-chain temporarily interrupts traffic to all subtended node chassis.
  • Supports APS link redundancy on subtended OC-3c interfaces if both the subtending host chassis and the subtended node chassis have primary and secondary NI-2 cards installed
Tip The term subtending refers to the host chassis, and subtended refers to the downstream chassis in a subtended network.

A subtended network configuration supports the following features:

  • The capacity to run data as fast as the speed of its subtended link. Uplink speed cannot exceed the OC-3c speed.
  • Four arbitration priorities, one for each quality of service (QoS) level. The supported QoS service levels are
    • Constant bit rate (CBR) for rate-limited services that require guaranteed bandwidth and bounded delay.
    • Variable bit rate real time (VBR-rt) for delay-sensitive voice and video services.
    • Variable bit rate nonreal time (VBR-nrt) for high-priority data services.
    • Unspecified bit rate (UBR) for low-priority data services.
  • Explicit forward congestion indication (EFCI) marking for available bit rate (ABR) service support.
  • Guaranteed frame rate (GFR).
  • Tree or daisy chain configurations for DS3 subtended Cisco 6130 chassis.
  • Daisy chain configurations for OC-3c subtended Cisco 6130 chassis.
  • Fair access to the trunk port for each subtended chassis.
  • A network trunk port that operates as fast as any subtended link.
  • NI-2 card cold redundancy and APS link redundancy. See the "Redundancy Overview" section for more information.

The NI-2 card provides three types of subtended network connections:

  • A DS3 ATM interface
  • A high-speed OC-3c optical ATM interface that supports single-mode fiber (SMF) intermediate range
  • A high-speed OC-3c optical ATM interface that supports multimode fiber (MMF) short range

The following sections detail the three types of subtending network connections.

Subtended Network Configuration with DS3/2DS3 NI-2 Cards

In a subtended network configuration using DS3/2DS3 NI-2 cards, you can subtend a Cisco 6130 chassis to four tiers, with up to twelve chassis, all connecting through one subtending host chassis to the ATM backbone.

Figure 1-3 shows typical DS3-configured Cisco 6130 systems subtended in a combined subtending tree topology with daisy chain. The subtending host chassis at the top of the subtending tree connects directly to the ATM switch. The middle two Cisco 6130 chassis in the lowest level are daisy chained. TRNK 1 refers to the single network trunk or to the Cisco 6130 subtended network interface. SBTD 2 and SBTD 3 refer to the two Cisco 6130 chassis subtended interfaces. You make network interface connections at the system I/O card that is installed on the Cisco 6130 backplane.


Figure 1-3   Subtended Network Configuration Using DS3/2DS3 NI-2 Cards


Note   You can subtend Cisco 6130 chassis with DS3/2DS3 NI-2 cards in a continuous daisy chain. However, this subtending scheme is not optimal for data throughput for Cisco 6130 chassis that use DS3/2DS3 NI-2 cards.

Cisco IOS software does not manage the primary Cisco 6130 chassis and all subtended Cisco 6130 chassis as a single large Cisco 6130 with NI-2 system. Each Cisco 6130 supports an independent Cisco IOS processor and Management Information Base (MIB).

Subtended Network Configuration with OC-3c/OC-3c NI-2 Cards

In a subtended network configuration using OC-3c/OC-3c NI-2 cards (SMF or MMF), you can subtend up to twelve OC-3c configured chassis in a daisy chain, all connecting through one subtending host chassis to the ATM backbone (see Figure 1-4).


Figure 1-4   Subtended Network Configuration Using OC-3c/OC-3c NI-2 Cards


Cisco 6130 Chassis Overview

The Cisco 6130 chassis uses a 32-slot multiport line card architecture capable of supporting up to 128 ADSL/SDSL ports that are connected either directly or through a POTS splitter.

Note   For hardware specifications for the Cisco 6130, see the "Cisco 6130 with NI-2 System Specifications" section.

The following sections detail these Cisco 6130 hardware components:

Cisco 6130 Card Compartment

The card compartment holds all circuitry that relates to the Cisco 6130 with NI-2 system operation. The card compartment contains 38 slots. Table 1-1 describes each card slot assignment for the Cisco 6130.

Table 1-1   Cisco 6130 Card Slot Assignments

Card Slot Card Assignment

1 to 8

4xDMTs, 4xflexis, or 4xSDSLs1

9

Blank faceplate2

10

NI-2 card (primary)

11

NI-2 card (secondary) or blank faceplate2

12

Blank faceplate2

13 to 20

4xDMT, 4xflexi, or 4xSDSLs1

21 to 28

4xDMT, 4xflexi, or 4xSDSLs1

29 and 30

Blank faceplates2

31 to 38

4xDMT, 4xflexi, or 4xSDSLs1
14xSDSLs can only be used in a Cisco 6130 without a POTS splitter configuration.

2Blank faceplates must be installed in all open slots of each chassis.
Note   You can purchase blank faceplates for empty Cisco 6130 card slots.

Figure 1-5 identifies the Cisco 6130 card slots. Each slot on a chassis is numbered along the top of the chassis. In this guide, the slot numbers are shown on the cards for easy reference and readability. These slots are referred to in subsequent sections of this chapter and elsewhere in this guide.

Note   Figure 1-5 shows the Cisco 6130 without the required front cover installed. The front cover must be installed while the Cisco 6130 with NI-2 system is in operation.

Figure 1-5   Cisco 6130 Card Slots


Cisco 6130 Backplane

Figure 1-6 shows the Cisco 6130 backplane.

Note   To determine if you have a Cisco 6130, locate the Cisco 6130 label on the upper right corner of either the chassis or the front cover of the chassis. Another way to determine if you have a Cisco 6130 is to locate the J49 connector on the backplane. The Cisco 6100 backplane does not have this connector.

Figure 1-6   Cisco 6130 Backplane


Table 1-2 describes the connectors and switches on the Cisco 6130 backplane.

Table 1-2   Cisco 6130 Backplane Connectors and Switches

Identifier Name Description

J45

Not in use.

J46

Not in use.

J47

Not in use.

J48

Not in use.

J49

Fan Tray Connection

26-pin SCSI connector used to connect the fan tray to the Cisco 6130 chassis.

J39, J40, J41, J42, J43, J44

Data

Six 50-pin Champ connectors used to transfer data between the Cisco 6130 chassis and the POTS splitter in a Cisco 6130 with a POTS splitter configuration. In a Cisco 6130 without a POTS splitter configuration, the connectors are used to transfer data between the Cisco 6130 chassis and the CPE equipment.

P9, P3

System I/O card

Two 2-mm HM1 modular connectors (male on the Cisco 6130 backplane and female on the system I/O card) used to connect the system I/O card.

P13

Power

A terminal block connector with four dual-power connections (-48V_A, -48V_B, and two -48RTN2).

P14, P15, P17

Not in use.

P18

Analog test input

A 2-position header for connecting external xDSL test equipment.
1HM = hard metric

2RTN = return (ground)

Cisco 6130 Cards

This section contains the following information about the types of Cisco 6130 cards:

Table 1-3 shows the configurations where the Cisco 6130 line cards can operate.

Table 1-3   Cisco 6130 Card and Configuration Compatibility

Line Card Cisco 6130 with a POTS Splitter Configuration Cisco 6130 Without a POTS Splitter Configuration

4xDMT

Yes

Yes

4xflexi1

Yes

Yes

4xSDSL2, 3

No

Yes
1The 4xflexi feature support for the Cisco 6130 is present in Release 12.1(2)DA or later.

2The 4xSDSL feature support for the Cisco 6130 is present in Release 12.1(2)DA or later.

34xSDSL does not support POTS.

The Cisco 6130 supports restricted line card intermixing. You can intermix only the 4xflexi (CAP mode) and the 4xflexi (DMT mode) in the same chassis half. The left half of the chassis comprises slots 1 to 8 and 21 to 28; the right half comprises slots 13 to 20 and 31 to 38. The line card intermixing configurations that are supported in a Cisco 6130 chassis are

  • 4xflexi (CAP mode) and 4xflexi (DMT mode)
  • 4xflexi (CAP mode) and 4xSDSL (used in a Cisco 6130 without POTS splitter configuration only)
  • 4xflexi (DMT mode) and 4xSDSL (used in a Cisco 6130 without POTS splitter configuration only)
Caution   Other line card intermixing configurations are not currently supported. Mixing incompatible line cards can cause unpredictable system behavior.

4xDMT Overview

The 4xDMT

  • Supports four ADSL modem connections.
  • Converts ADSL modulation from the line into digital data streams to and from the NI-2 card.
  • Negotiates the line rate with the CPE when it trains and bases the rate on line quality and distance.
    • Note   For line card intermixing information, see the "Cisco 6130 Cards" section 1-12.

If provisioned, the 4xDMT rate adapts to the maximum bit rate negotiable on the line. The maximum bit rate settings are provisioned in the management software.

Note   For hardware specifications for the 4xDMT, see the "4xDMT Specifications" section A-3.

The chassis can include up to 32 4xDMTs for a total of 128 ADSL modem connections.

Faceplate Features

The following fixtures are present on the front of the 4xDMT faceplate:

  • Locking lever and locking tab
  • LEDs
    • STATUS
    • ACTIVE
    • Four port (ATU-C1 through ATU-C4)
  • Extraction tab

Figure 1-7 shows a close-up of the 4xDMT faceplate.


Figure 1-7   4xDMT Faceplate


Table 1-4 describes the 4xDMT LED indicator functions.

Table 1-4   4xDMT LED Indicators

LED State Function

STATUS

Green slow blinking

The self-test is in progress.

Green fast blinking

The image download is in progress.

Green solid

The status is OK.

Red

The self-test or line card has failed.

Off

The ATU-C line card has a power failure.

ACTIVE

Green solid

The line card is activated.

Green blinking

A digital signal processor firmware download is in progress.

Off

The line card is not in service.

ATU-C 1

Green solid

Modem 1 is trained.

Green blinking

Training is in progress for modem 1.

Off

Modem 1 is idle.

ATU-C 2

Green solid

Modem 2 is trained.

Green blinking

Training is in progress for modem 2.

Off

Modem 2 is idle.

ATU-C 3

Green solid

Modem 3 is trained.

Green blinking

Training is in progress for modem 3.

Off

Modem 3 is idle.

ATU-C 4

Green solid

Modem 4 is trained.

Green blinking

Training is in progress for modem 4.

Off

Modem 4 is idle.

4xflexi Overview

The 4xflexi

  • Supports CAP, DMT, or G.lite line encoding.
  • Supports four ADSL modem connections.
  • Converts ADSL modulation from the line into digital data streams to and from the NI-2 card.
  • Negotiates the line rate with the CPE when it trains and bases the rate on line quality and distance.
    • Note   For line card intermixing information, see the "Cisco 6130 Cards" section 1-12.

If provisioned, the 4xflexi rate adapts to the maximum bit rate negotiable on the line. The maximum bit rate settings are provisioned in the management software.

Note   For hardware specifications for the 4xflexi, see the "4xflexi Specifications" section A-3.

The Cisco 6130 system can include up to 32 4xflexis for a total of 128 ADSL modem connections.

Edge Connector Key

The edge connector key, located on the rear of the 4xflexi, connects the 4xflexi to the backplane of the chassis. There are two edge connector keys available for the 4xflexi: one has six notches and one has seven notches. You can use both versions in the Cisco 6130 with NI-2 system. Figure 1-8 shows the edge connector key with seven notches.

Note   The 4xSDSL card also features the edge connector key.

Figure 1-8   Edge Connector Key


Faceplate Features

The following fixtures are present on the front of the 4xflexi faceplate:

  • Locking lever and locking tab
  • LEDs
    • STATUS
    • ACTIVE
    • CAP
    • DMT
    • G.LITE
    • Four port (A1 through A4)
  • Extraction tab

Figure 1-9 shows a close-up of the 4xflexi faceplate.


Figure 1-9   4xflexi Faceplate


Table 1-5 describes the 4xflexi LED indicator functions.

Table 1-5   4xflexi LED Indicators

LED State Function

STATUS

Green slow blinking

The self-test is in progress.

Green fast blinking

The image download is in progress.

Green solid

The status is OK.

Red

The self-test or line card has failed.

Off

The ATU-C line card has a power failure.

ACTIVE

Green solid

The line card is activated.

Off

The line card is not in service.

CAP

Green solid

The line card is in CAP mode.

Off

The line card is not in CAP mode.

DMT

Green solid

The line card is in DMT mode.

Off

The line card is not in DMT mode.

G.LITE

Green solid

The line card is in G.lite mode.

Off

The line card is not in G.lite mode.

A1

Green solid

Modem 1 is trained.

Green blinking

Training is in progress for modem 1.

Off

Modem 1 is idle.

A2

Green solid

Modem 2 is trained.

Green blinking

Training is in progress for modem 2.

Off

Modem 2 is idle.

A3

Green solid

Modem 3 is trained.

Green blinking

Training is in progress for modem 3.

Off

Modem 3 is idle.

A4

Green solid

Modem 4 is trained.

Green blinking

Training is in progress for modem 4.

Off

Modem 4 is idle.

4xSDSL Overview

The 4xSDSL

  • Supports 2B1Q line encoding.
  • Is designed for use in a Cisco 6130 without a POTS splitter configuration.
  • Supports four SDSL modem connections.
  • Converts SDSL modulation from the line into digital data streams to and from the NI-2 card.
    • Note   For line card intermixing information, see the "Cisco 6130 Cards" section 1-12.

The negotiated bit rate is the lower of the following rates:

  • The provisioned bit rate set for the 4xSDSL in the management software
  • The assigned bit rate at the CPE
    • Note   For hardware specifications for the 4xSDSL, see the "4xSDSL Specifications" section A-4.

The chassis can include up to 32 4xSDSLs for a total of 128 SDSL modems.

Edge Connector Key

The edge connector key, located on the rear of the 4xSDSL, connects the 4xSDSL to the backplane of the chassis. There are two edge connector keys available for the 4xSDSL: one has six notches, and the other has seven notches. You can use both versions in the Cisco 6130 with NI-2 system. Figure 1-8 shows the edge connector key with seven notches.

Faceplate Features

The following fixtures are present on the front of the 4xSDSL faceplate:

  • Locking lever and locking tab
  • LEDs
    • STATUS
    • ACTIVE
    • Four port (STU-C1 through STU-C4)
  • Extraction tab

Figure 1-10 shows a close-up of the 4xSDSL faceplate.


Figure 1-10   4xSDSL Faceplate


Table 1-6 describes the 4xSDSL LED indicator functions.

Table 1-6   4xSDSL LED Indicators

LED State Function

STATUS

Green slow blinking

The self-test is in progress.

Green fast blinking

The image download is in progress.

Green solid

The status is OK.

Red

The self-test or line card has failed.

Off

The ATU-C line card has a power failure.

ACTIVE

Green solid

The line card is activated.

Off

The line card is not in service.

STU-C 1

Green solid

Modem 1 is trained.

Green blinking

Training is in progress for modem 1.

Off

Modem 1 is idle.

STU-C 2

Green solid

Modem 2 is trained.

Green blinking

Training is in progress for modem 2.

Off

Modem 2 is idle.

STU-C 3

Green solid

Modem 3 is trained.

Green blinking

Training is in progress for modem 3.

Off

Modem 3 is idle.

STU-C 4

Green solid

Modem 4 is trained.

Green blinking

Training is in progress for modem 4.

Off

Modem 4 is idle.

DS3/2DS3 NI-2 Card Overview

The DS3/2DS3 NI-2 card

  • Connects to the xTU-C line cards through point-to-point serial data buses on the backplane
  • Controls timing and redundancy
  • Provides CO facility alarm relay contact interfaces and an alarm cut-off (ACO) button
  • Provides visual and audible operating status alerts
  • Contains the ATM switch fabric
  • Provides the network DS3 WAN trunk interface through BNC connectors located on the system I/O card
  • Provides two DS3 subtend interfaces through BNC connectors located on the system I/O card
  • Supports the aggregation of up to 12 subtended node chassis that are configured for DS3 operation in a tree topology
  • Supports NI-2 card cold redundancy
  • Provides Cisco IOS-based ATM Quality of Service (QoS).

The DS3/2DS3 NI-2 card functions are managed by Cisco IOS software. The Cisco IOS software operates and integrates controller, network trunk, and subtending functions from this single card, which occupies slot 10, slot 11, or both in a Cisco 6130 chassis.

Note   For DS3/2DS3 NI-2 card hardware specifications, see the "DS3/2DS3 NI-2 Card Specifications" section on.
Faceplate Features

Figure 1-11 shows a close-up of the DS3/2DS3 NI-2 card faceplate.


Figure 1-11   DS3/2DS3 NI-2 Card Faceplate


The following fixtures are present on the front of the DS3/2DS3 NI-2 card faceplate, as noted in Figure 1-11:

  • Two locking levers with locking tabs.
  • An ACO button and a maintenance RESET port located at the top of the faceplate.
  • Three interface status LED groups, Trunk 1 (TRNK 1), Subtend 2 (SBTD 2), and Subtend 3 (SBTD 3), located on the left side of the card faceplate. These interface status LED groups monitor the trunk and subtend connections on the system I/O card or I/O module.

Table 1-7 describes the interface status LED group indicators and their functions.

Table 1-7   Interface Status LED Group Indicators

LED State Function

TEST

Amber solid

Cisco IOS detects that an obtrusive test (loopback) is active on this interface.

Off

Cisco IOS does not detect obtrusive test activity.

RX STAT

Amber solid

The receiver detects a physical layer problem.

Off

The receiver does not detect a physical layer problem.

TX STAT

Amber solid

The transmitter detects a physical layer problem.

Off

The transmitter does not detect a physical layer problem.

RCLK

Green solid

Hardware detects an incoming clock signal.

Off

Hardware does not detect an incoming clock signal.
  • Three alarm status LED groups located on the right side of the NI-2 card faceplate.
    • System alarm LED group
    • Card status LED group
    • Fan alarm LED group

Table 1-8 describes the alarm status LED group indicators and their functions.

Table 1-8   Alarm Status LED Group Indicators

LED Group LED State Function

System Alarm

CRITICAL

Red

When this LED is lit, a critical alarm is active.

MAJOR

Red

When this LED is lit, a major alarm is active.

MINOR

Amber

When this LED is lit, a minor alarm is active.

Card Status

POWER

Green

When this LED is lit, the NI-2 card has power.

STATUS

Green

This LED indicates the operational status of the NI-2 card:

  • When the LED is lit, there are no internal faults or problems.
  • When the LED is not lit, the NI-2 card has not booted properly, or a problem is preventing normal operation.

ACTIVE

Green

When lit, this LED indicates which NI-2 card is operating as the active network interface in the chassis.

Fan Alarm

FAN 1

This LED on the NI-2 card is inactive and always off. The fan status LED indicators are on the fan tray.

FAN 2

This LED on the NI-2 card is inactive and always off. The fan status LED indicators are on the fan tray.
  • Three operating system interface and internet ports located on the right side of the NI-2 card faceplate.
    • CNSL—An RJ-45 receptacle that provides a serial connection to a system console.
    • AUX—An RJ-45 receptacle that provides connection to an auxiliary device (such as a modem) used to remotely configure the system.
    • ENET—An RJ-45 10BaseT receptacle that complies with Ethernet standards and that provides connection to a system Ethernet. The ENET interface has two LEDs: ACT to indicate activity status and LNK to indicate link status. Table 1-9 describes the ENET interface LED indicators and their functions.

Table 1-9   ENET Interface LED Indicators

LED State Function

ACT

Green solid or blinking

When the LED is lit or blinking, the Ethernet interface is active.

Off

When the LED is unlit, the Ethernet interface is inactive.

LNK

Green solid

When the LED is lit, the Ethernet link is active.

OC-3c/OC-3c NI-2 Card Overview

The OC-3c/OC-3c NI-2 card

  • Connects to the xTU-C line cards through point-to-point serial data buses on the backplane
  • Controls timing and redundancy
  • Provides CO facility alarm relay contact interfaces and an ACO button
  • Provides visual and audible operating status alerts
  • Contains the ATM switch fabric
  • Provides the network OC-3c WAN trunk interface through connectors located on the NI-2 card faceplate. The following two versions of the OC-3c/OC-3c NI-2 card are available to support the WAN trunk interface:
    • SMF intermediate range
    • MMF short range
  • Provides an OC-3c subtend interface through optical connectors located on the NI-2 card faceplate.
  • Supports the aggregation of up to 12 subtended node chassis that are configured for OC-3c operation in a daisy-chain topology
  • Supports NI-2 card cold redundancy
  • Supports APS link redundancy
  • Provides Cisco IOS-based ATM Quality of Service (QoS)
    • Note   For OC-3c/OC-3c NI-2 card hardware specifications, see the "OC-3c/OC-3c NI-2 Card Specifications" section.
Faceplate Features

Figure 1-12 shows a close-up of the OC-3c/OC-3c NI-2 card faceplate.


Figure 1-12   OC-3c/OC-3c NI-2 Card Faceplate


1

Ejector lever.

 7

Model number
2

Locking tab.

 8

System alarm LED group.
3

ACO button.

 9

Card status LED group.
4

Maintenance RESET port.

 10

Fan alarm LED group.
5

Interface status LED groups: Trunk 1 (TRNK 1) and Subtend 2 (SBTD 2). These groups show the status of the trunk and subtend connections.

 11

CNSL—An RJ-45 receptacle that provides a serial connection to a system console.
6

Two optical interface connector pairs: Trunk 1 (TRNK 1) and Subtend 2 (SBTD 2)

  • TRNK 1—This connector pair is for network trunk interface TX and RX data optical cables. On a subtended node chassis, these network trunk interface TX and RX cables connect to SBTD 2 on the subtending host chassis.
  • SBTD 2—This connector pair is for subtended node chassis TX and RX data optical cables.
 12

AUX—An RJ-45 receptacle that provides connection to an auxiliary device (such as a modem) used to remotely configure the system.

 

 

 13

ENET—An RJ-45 10BaseT receptacle that complies with Ethernet standards and that provides connection to a system Ethernet.

Table 1-10 describes the LED group indicators and their functions.

Table 1-10   OC-3c/OC-3c NI-2 Card LED Group Indicators

LED Group LED State Function

Interface status LED (in Figure 1-12)

TEST

Amber solid

Cisco IOS detects that an obtrusive test (loopback) is active on this interface.

Off

Cisco IOS does not detect obtrusive test activity.

RX STAT

Amber solid

The receiver detects a physical layer problem.

Off

The receiver does not detect a physical layer problem.

TX STAT

Amber solid

The transmitter detects a physical layer problem.

Off

The transmitter does not detect a physical layer problem.

RCLK

Green solid

Hardware detects an incoming clock signal.

Off

Hardware does not detect an incoming clock signal.

System alarm (in Figure 1-12)

CRITICAL

Red

A critical alarm is active.

MAJOR

Red

A major alarm is active.

MINOR

Amber

A minor alarm is active.

Card status (in Figure 1-12)

POWER

Green

The NI-2 card has power.

STATUS

Green

The operational status of the NI-2 card.

  • On—There are no internal faults or problems.
  • Off—The NI-2 card has not booted properly, or a problem is preventing normal operation.

ACTIVE

Green

The NI-2 card is operating as the active NI-2 card in the chassis.

Fan alarm (10 in Figure 1-12)

FAN 1

Red

The fan module or fan tray is not operational and is in alarm mode.

FAN 2

This LED on the NI-2 card is inactive and is always off.

ENET interface LED (13 in Figure 1-12)

ACT

Green solid or blinking

The Ethernet interface is active.

Off

The Ethernet interface is inactive.

LNK

Green solid

The Ethernet link is connected and enabled.

Network Clocking Overview

The NI-2 card receives its network timing signal from any one of the following sources:

  • A building integrated timing supply (BITS) clock. When a BITS clock serves as the network timing signal source, the Cisco 6130 chassis receives a clock signal through designated pins on the system I/O card and distributes the signal through the chassis backplane.
  • An internal clock.
  • A DS3 or OC-3c network trunk interface. An NI-2 card synchronizes with the network timing source and provides a clock reference signal to line cards in the chassis and to subtended node chassis.

The active NI-2 card supplies a redundant pair of clock signals to all cards in the chassis. This same clock reference can be propagated to subtend systems via the trunk and subtended interface ports. This is done by configuring the subtending port of the root system to source the network-derived clock. The trunk port of the subtended system is configured as the network clock source for that chassis. This chain continues down the subtended tree.

Redundancy Overview

Redundancy is available for the Cisco 6130 system. The following forms of redundancy are available:

  • NI-2 card cold redundancy, which allows a standby NI-2 card to take over system operations in the event of a complete failure of the active NI-2 card.
  • APS link redundancy, which provides recovery from a cut fiber or the failure of an OC-3c optical transmitter or optical receiver interface on an NI-2 card. APS link redundancy is available on OC-3c/2DS3 NI-2 card trunk interfaces and OC-3c/OC-3c NI-2 card trunk and subtend interfaces.
Note    Line card redundancy is not currently supported.
NI-2 Card Cold Redundancy

NI-2 card cold redundancy requires that two NI-2 cards be installed in the chassis. The primary card is installed in slot 10 of the chassis, and the secondary card is installed in slot 11. Either the primary or the secondary NI-2 card can serve as the active NI-2 card. The interface types must be the same for both the primary and secondary NI-2 cards.

In a Cisco 6130 system, NI-2 card cold redundancy is supported by DS3/2DS3, OC-3c/OC-3c SMF, and OC-3c/OC-3c MMF NI-2 cards.

During steady-state operations, one NI-2 card functions as the active unit, and the other functions as the standby unit. The active NI-2 card displays a green ACTIVE LED. In an active state, the NI-2 card

  • Has full Ethernet, auxiliary port, and console access
  • Communicates with line cards
  • Has full access to the environmental monitoring subsystem
  • Has access to the optical interfaces on the standby NI-2 card
  • Allows remote access to the file system of the standby NI-2 card

The standby NI-2 card plays a minimal role during steady-state operations. In a standby state, the NI-2 card

  • Receives configuration changes from the active NI-2 card (when the cards are configured for synchronization)
  • Has no Ethernet, auxiliary port, or console access
  • Does not communicate with line cards
  • Has no access to the environmental monitoring subsystem
  • Generates only APS alarms, which are reported via the active card

For management purposes, the primary and secondary NI-2 cards appear as one element. The cards share one IP address.

Note   For information on NI-2 card cold redundancy switchover conditions, refer to the Upgrading DSLAMs for NI-2 Card and APS Link Redundancy document.
APS Link Redundancy

APS link redundancy provides recovery from a cut fiber or the failure of an OC-3c optical transmitter or receiver interface on an NI-2 card. In a Cisco 6130 system, APS link redundancy is available on OC-3c/OC-3c NI-2 card trunk and subtend interfaces.

The working link is the fiber connection between the primary NI-2 card installed in slot 10 of the chassis and the ATM switch. The protection link is the fiber connection between the secondary NI-2 card installed in slot 11 of the chassis and the ATM switch. When the fiber or optical ports on the active NI-2 card fail, that card remains active but is able to use the fiber or optical ports on the standby NI-2 card.

APS protocol information is carried over the protection link connected to the secondary NI-2 card in slot 11. The standby NI-2 card continually reports synchronous optical network (SONET) state information to the active NI-2 card.

APS link redundancy is nonrevertive. For example, after a switchover from the working to the protective link occurs, the active NI-2 card will switch back to the working fiber only if manually forced through a CLI command or if a failure condition occurs on the protection link. However, if a failure condition occurs on the protection link while the working link is still in a failed state, a switch back to the working link will not occur.

Note   For information on APS link redundancy switchover conditions, refer to the Upgrading DSLAMs for NI-2 Card and APS Link Redundancy document.
Redundancy in Subtended Configurations

In Cisco 6130 subtending configurations, NI-2 card redundancy is supported in a DS3 subtend tree or in an OC-3c subtend daisy-chain if both the subtending host chassis and the subtended node chassis have primary and secondary NI-2 cards installed. An NI-2 card failure on a node in a subtend tree or daisy-chain temporarily interrupts traffic to all subtended node chassis.

APS link redundancy is supported on optical interfaces in Cisco 6130 subtending configurations if the subtending host chassis has a secondary (redundant) OC-3c/OC-3c NI-2 card installed.

System I/O Card

A system I/O card

  • Provides transmit and receive Bayonet-Neill-Concelman (BNC) coaxial cable connections for interfacing with one DS3 network connection and up to two subtended node chassis that use DS3/2DS3 NI-2 cards.
  • Provides relays and contact wire-wrap pins for dedicated CO facility operating alarms (DS3 or OC-3c systems) that are operated by Cisco IOS software
  • Provides the BITS clock

The system I/O card attaches to the two 2-mm HM card connectors, P3 and P9, on the Cisco 6130 backplane.

Figure 1-13 shows the location of the system I/O card on the chassis backplane.


Figure 1-13   System I/O Card Locations


Figure 1-14 shows a close-up of the system I/O card.


Figure 1-14   System I/O Card


Table 1-11 describes the connectors and headers on the system I/O card.

Table 1-11   System I/O Card Connectors and Headers

Identifier Name Description

J4, J8

DS3 subtend (RX)

A 75-ohm BNC connector that is used to connect a subtending host chassis to a DS3-configured subtended node chassis TX connector.

J6, J10

DS3 subtend (TX)

A 75-ohm BNC connector that is used to connect a subtending host chassis to a DS3-configured subtended node chassis RX connector.

J12

DS3 trunk I/O (RX)

A 75-ohm BNC connector that is used to connect the trunk network RX coaxial cable or used to connect a subtending host chassis to a DS3-configured subtended node chassis TX connector.

J14

DS3 trunk I/O (TX)

A 75-ohm BNC connector that is used to connect the trunk network TX coaxial cable or used to connect a subtending host chassis to a DS3-configured subtended node chassis RX connector.

P1

Alarm wire-wrap header1
  • Pin 1 (left)—AUD2_CRIT3_CO4
  • Pin 2—AUD_CRIT_NO5
  • Pin 3—AUD_CRIT_NC6
  • Pin 4—AUD_MAJ7_CO
  • Pin 5—AUD_MAJ_NO
  • Pin 6 (right)—AUD_MAJ_NC

P2

Alarm wire-wrap header1
  • Pin 1 (left)—AUD_MIN8_CO
  • Pin 2—AUD_MIN_NO
  • Pin 3—AUD_MIN_NC
  • Pin 4—VIS9_CRIT_CO
  • Pin 5—VIS_CRIT_NO
  • Pin 6 (right)—VIS_CRIT_NC

P3

Alarm wire-wrap header1
  • Pin 1 (left)—VIS_MAJ_CO
  • Pin 2—VIS_MAJ_NO
  • Pin 3—VIS_MAJ_NC
  • Pin 4—VIS_MIN_CO
  • Pin 5—VIS_MIN_NO
  • Pin 6 (right)—VIS_MIN_NC

P4

Alarm wire-wrap header1
  • Pin 1 (left)—DOOR ALARM
  • Pin 2—Reserved
  • Pin 3—Reserved
  • Pin 4—Reserved
  • Pin 5—ACO10_NO
  • Pin 6 (right)—ACO GND11

P5

Alarm wire-wrap header1
  • Pin 1 (left)—RX_BITS12_TIPA
  • Pin 2—RX_BITS_RINGA
  • Pin 3—RX_BITS_GND/GND
  • Pin 4—RX_BITS_TIPB
  • Pin 5—RX_BITS_RINGB
  • Pin 6 (right)—RX_BITS_GND/GND

K1, K2, K3, K4, K5, K6

Audible and visual alarm relays

Not in use.
1Each wire-wrap header is connected to a relay contact on the active NI-2 card in the Cisco 6130 chassis through the system I/O card connectors.

2AUD = audible.

3CRIT = critical.

4CO = common.

5NO = normally open.

6NC = normally closed.

7MAJ = major.

8MIN = minimum.

9VIS = visual.

10The ACO button is located on the faceplate of the NI-2 card. This switch turns off the audible alarms that are generated by the system software.

11GND = ground.

12RX_BITS = receive building-integrated timing source.

An EMI shield is formed by the EMI fence, which is soldered in place on the system I/O card, and the EMI cover (see Figure 1-14). Printed circuit board fuses, relays, and surge protectors are shielded by two clear plastic covers: a safety shield and an ESD shield. The EMI cover and protective shields must be in place during Cisco 6130 with NI-2 system operation.

Front Cover

The Cisco 6130 chassis ships with a front cover that must be installed and in place while the system is in operation, as shown in Figure 1-15.


Figure 1-15   Cisco 6130 Front Cover Installation


Rear Cover

You can order and install an optional rear cover and accessory kit for the Cisco 6130 chassis. The rear cover attaches to the back of the Cisco 6130 chassis and restricts access to the backplane and cable connectors. To keep cables from interfering with the opening of the rear cover, the cables that come down from the top of the rack can be tie wrapped to the cover-mounting brackets.

The rear cover accessory kit contains

  • 1 cover-mounting bracket (detached)
  • 1 cover-mounting bracket (with the rear cover attached)
  • 10 tie wraps
  • 6 standoff screws

Fan Tray

The system requires forced air cooling when you use a Cisco 6130 chassis. Therefore, you must install a fan tray with three fan modules below the chassis and leave 1 rack unit (RU) of space below the fan tray for intake plenum. Figure 1-16 shows the front view of the fan tray.


Figure 1-16   Fan Tray


Note   The fan tray must be bolted into the rack and connected to the chassis. If you are using multiple Cisco 6130 chassis in your configuration, a fan tray must be installed under each chassis.

An LED is located on the front of each of the three fan modules. If the LED is

Figure 1-17 shows the backplane of the fan tray.


Figure 1-17   Fan Tray Backplane


Table 1-12 describes the connectors on the backplane of the fan tray.

Table 1-12   Fan Tray Backplane Connectors

Identifier Name Description

P1

Power

Terminal block connector with four dual power input connections (-48VA, -48VB, and two -48VB RTN).

P2

A two-position header providing connections for fan tray alarm contacts.

Not in use.

J1

Alarm

26-pin SCSI connector used to connect the fan tray to the Cisco 6130 chassis.

Cisco 6120 POTS Splitter Overview

The Cisco 6120 POTS splitter is a device that separates voice frequencies from DSL signals. It is used to allow POTS service to continue over communication lines accessed by DSL equipment such as the Cisco 6130 chassis. POTS frequencies are sent to the voice switch and xDSL frequencies are routed to the ATU-C line cards, depending on the configuration you install. The Cisco 6120 is electrically passive. Therefore, a complete loss of power to the Cisco 6130 with NI-2 system does not affect voice transport to the Public Switched Telephone Network (PSTN).

To colocate voice-switching equipment through the CO MDF, use separate 50-pin Champ connectors to cable to POTS signals. Special cables are required for this connection. Obtain these cables from Cisco, or build the cables according to a standard, accepted cable specification, for example, the Nortel NT-T100 series cable specification. For more information on the required cables, see "Cable and Port Mapping Specifications."

Note   Refer to the appropriate vendor documentation for information on the third-party POTS splitter.

Cisco 6120 Card Compartment

The card compartment includes 22 slots. Table 1-13 describes each card slot assignment for the Cisco 6120.

Table 1-13   Cisco 6120 Card Slot Assignments

Card Slot Card Assignment

1 to 10

DMT POTS cards only

11

Blank faceplate1

12

Screwed-down faceplate

13 to 22

DMT POTS cards only
1Blank faceplates must be installed in all open slots of each chassis.
Note   You can purchase blank faceplates for empty Cisco 6120 card slots.

Figure 1-18 identifies the Cisco 6120 card slots. Each slot on a chassis is numbered along the top of the chassis. In this guide, the slot numbers are shown on the cards for easy reference and readability. These slots are referred to in subsequent sections of this chapter and elsewhere in this guide.


Figure 1-18   Cisco 6120 Card Slots


Cisco 6120 Backplane

Figure 1-19 shows the backplane of the Cisco 6120.


Figure 1-19   Cisco 6120 Backplane


Table 1-14 describes the connectors on the backplane of the Cisco 6120.

Table 1-14   Cisco 6120 Backplane Connectors

Identifier Connector Description

J1 through J6

Six 50-position Champ connectors for connection to the Cisco 6130 chassis.

J7 through J10

Voice

Four 50-position Champ connectors for connection to external voice terminating equipment.

J11 through J14

Line

Four 50-position Champ connectors for incoming xDSL voice/data connections.

J36

One 9-pin D-sub connector reserved for future use.

Figure 1-20 shows the location of the Cisco 6120 data, voice, and line connections.


Figure 1-20   Cisco 6120 Connections


Cisco 6120 Cards

The DMT POTS card separates ADSL data from the POTS signals.

Note   The Cisco 6130 with a POTS splitter configuration will support the 8 kHz DMT POTS card.

Figure 1-21 shows the DMT POTS card faceplate.


Figure 1-21   DMT POTS Card Faceplate


Management Software

You can provision and manage the Cisco 6130 with NI-2 system through the following management software:

  • Cisco IOS—A CLI that is available for network element provisioning.
  • CDM—A GUI designed to configure and manage the 6xxx series of Cisco IOS software-based DSLAMs. CDM provides the following areas of network management—fault, configuration, performance, and security. CDM runs with the Cisco EMF; both are installed on Sun workstations.

Cisco EMF is based on an object model in which network elements or modules represent the managed entity. Each object is defined by a class and specific attributes. An object can represent a network element or a more abstract entity such as a link relationship, a network, or a container such as a site, shelf, or region.

Note    If your network contains multiple Sun workstations, you must dedicate one workstation as the server and all additional workstations as clients. The server should be the repository and distributor of database information from which the clients request information. The client workstations allow multiple users to monitor the managed network.
Note   See the "Hardware Specifications" section on page A-1 for minimum software and network management release requirements per Cisco 6130 chassis component.

The supported alarms that are generated by the management software are

  • CRITICAL—A critical visual alarm condition is indicated when the CRITICAL LED in the NI-2 card faceplate lights.
    • When a critical alarm occurs, the critical visual and audible alarm relays are activated.
    • A critical alarm affects many or all subscribers that are connected to the node (for example, failure of the NI-2 card or the trunk can cause a critical alarm).
    • Critical alarms clear after you fix the condition that triggered the alarm.
    • Audible alarms are turned off when you press the ACO button on the NI-2 card faceplate.
  • MAJOR—A major visual alarm condition is indicated when the MAJOR LED in the NI-2 card faceplate lights.
    • When a major alarm occurs, the major visual and audible alarm relays are also activated.
    • Several subscribers that are connected to the node are affected.
    • Major alarms clear after you fix the condition that triggered the alarm.
    • Audible alarms are turned off when you press the ACO button on the NI-2 card faceplate.
  • MINOR—A minor visual alarm condition is indicated when the MINOR LED in the NI-2 card faceplate lights.
    • When a minor alarm occurs, the minor visual and audible alarm relays are also activated.
    • A small number of subscribers that are connected to the node are affected.
    • Minor alarms clear after you fix the condition that triggered the alarm.
    • Audible alarms are turned off when you press the ACO button on the NI-2 card faceplate.

Visual and audible alarm relay contacts can be wired from the Cisco 6130 chassis to CO alarm devices (remote lights or bells) located anywhere within the facility.

The visual and audible alarm relays are located on the system I/O card, but the NI-2 card hardware operates them. The visual alarms clear after you fix the problem that triggered the alarm. The audible alarms can be disabled by pressing the ACO button on the NI-2 card or clearing the alarm in the Cisco IOS software.

For more information on alarms that are generated in the management software, see "Troubleshooting."