- About This Guide
- Chapter 1, System Overview
- Chapter 2, SONET Transport
- Chapter 3, SDH Transport Over SONET
- Chapter 4, DWDM
- Chapter 5, Ethernet Features and Functions
- Chapter 6, Technical Specifications
- Chapter 7, System Planning and Engineering
- Chapter 8, IP Networking
- Chapter 9, Applications and Configurations
- Appendix A, Compliance
- Appendix B, SONET Primer
- Appendix C, DWDM Primer
- Appendix D, Ordering
- Appendix E, Acronyms
- Glossary
Technical Specifications
Note 
The terms "Unidirectional Path Switched Ring" and "UPSR" may appear in Cisco literature. These terms do not refer to using Cisco ONS 15xxx products in a unidirectional path switched ring configuration. Rather, these terms, as well as "Path Protected Mesh Network" and "PPMN," refer generally to Cisco's path protection feature, which may be used in any topological network configuration. Cisco does not recommend using its path protection feature in any particular topological network configuration.
This chapter describes technical specifications of the ONS 15454 equipment. For additional information, refer to the Cisco ONS 15454 Reference Manual.
The following topics are covered in this chapter:
•Electrical Interface Assemblies
•Network Element Defaults and Performance Monitoring Thresholds
•Remote Monitoring Specification Alarm Thresholds
Note In this chapter, the terms ONS 15454, shelf, and node are used interchangeably.
ONS 15454 Specifications
The Cisco ONS provides flexible SONET add/drop multiplexer features and offers service aggregation and high-bandwidth transport for voice and data traffic on a single platform. It is Network Equipment Building System (NEBS) Level 3 compliant for Type 2, Type 4, and Class A devices and meets the applicable criteria set forth in the following requirements documents:
•GR-63-CORE, Issue 1, October, 1995
•GR-1089-CORE, Issue 2, with Revision 1, February, 1999
•UL Standard 60950 Ed3, December 1, 2000
•UL Standard 94, October 29, 1996
•Requirement 1.1.4-20 of AT&T NEDS MLID #9069, December 30, 1999
•SBC TP76200MP, May, 2001
ONS 15454 Configurations
Table 6-1 lists how the ONS 15454 can be configured.
Physical Specifications
The ONS 15454 shelf assemblies with a fan tray and reversible mounting ears has the following dimensions:
|
|
|
|
|---|---|---|
Height |
18.5 inches (40.7 cm) |
18.5 inches (40.7 cm) |
Width: • • |
19 inches (41.8 cm) 23 inches (50.6 cm) |
19 inches (41.8 cm) 23 inches (50.6 cm) |
Depth1 BNC and SMB EIAs: • • |
12 inches (26.4 cm) 14 inches (35.6 cm) |
12 inches (26.4 cm) 14 inches (35.6 cm) |
Depth1 UBIC-H EIAs: • • |
NA NA |
12 inches (26.4 cm) 15.0 inches (33 cm) |
Depth1 UBIC-V EIAs: • • |
NA NA |
12 inches (26.4 cm) 16.75 inches (36.85 cm) |
Weight: • • |
55 lb (24.947 kg) 98 lb (44.451 kg) |
55 lb (24.947 kg) 98 lb (44.451 kg) |
Footprint |
13 ft2 |
13 ft2 |
Minimum Aisle Clearance Requirement |
24-inches |
24-inches |
1 The optional deep door adds approximately 2 inches (4.4 cm) to depth dimensions. |
Environmental Specifications
Note The Cisco ONS 15454 is intended for use with telecommunications equipment only.
Warning Only trained and qualified personnel should be allowed to install, replace, or service this equipment.
Warning This equipment must be installed and maintained by service personnel as defined by AS/NZS 3260. Incorrectly connecting this equipment to a general purpose outlet could be hazardous. The telecommunications lines must be disconnected 1) before unplugging the main power connector and/or 2) while the front door is open.
Warning The ONS 15454 is intended for installation in restricted access areas. A restricted access area is where access can only be gained by service personnel through the use of a special tool, lock, key, or other means of security. A restricted access area is controlled by the authority responsible for the location.
Warning The ONS 15454 is suitable for mounting on concrete or other non-combustible surfaces only.
Unused card slots should be filled with a blank faceplate (Cisco P/N 15454-BLANK). The blank faceplate ensures proper airflow when operating the ONS 15454 without the front door attached, although Cisco recommends that the front door remain attached.
Note The ONS 15454 is designed to comply with Telcordia GR-1089-CORE Type 2 and Type 4. Install and operate the ONS 15454 only in environments that do not expose wiring or cabling to the outside plant. Acceptable applications include Central Office Environments (COEs), Electronic Equipment Enclosures (EEEs), Controlled Environment Vaults (CEVs), huts, and Customer Premises Environments (CPEs).
Note The ONS 15454 is not designed as a Type 3 EU and has not undergone NEBS tests and evaluation for equipment directly connected to outside plant (OSP) facilities.
Note The fan tray assembly is required for all ONS 15454 installations.
Warning To prevent the equipment from overheating, do not operate it in an area that exceeds the maximum recommended ambient temperature of 131°F (55°C) unless configured for industrial temperature (I-temp). All I-temp rated components are -40°F to +149°F (-40°C to +65°C). To prevent airflow restriction, allow at least 1 inch (25.4 mm) of clearance around the ventilation openings.
The ONS 15454 is environmentally hardened and will function at operating temperatures of -40°F to +149°F (-40°C to +65°C) and humidity of 5 to 95 percent (non-condensing) when configured with the following components:
•15454-SA-HD Shelf
•15454-SA-ANSI Shelf
•15454-FTA2 Fan Tray
•15454-FTA3-T Fan Tray
•15454-TCC2
•15454-TCC2P
•15454-XC-T
•15454-AIC-T
•15454-AIC-I
•15454-AEP
•15454-DS3_EC1-481
•15454-DSXM-12
For all other configurations, the ONS 15454 functions at operating temperatures of 32 to 131 degrees Fahrenheit (0 to +55 degrees Celsius).
Note The I-Temp symbol is displayed on the faceplate of an I-Temp compliant card. A card without this symbol is C-Temp compliant.
When installed in an ONS 15454, all plug-in cards meet the following safety requirements:
•UL 1950
•CSA C22.2 No. 950
•EN 60950
•IEC 60950
Power Specifications
•Recommended Input Voltage: -48VDC
–Two -48VDC power feeds (Breaker A and Breaker B)
•Acceptable Input Voltage Range: -40 to -56.7VDC
•Maximum Power Consumption: 1060W (System Release 3.1 or higher); 952W (System Release prior to 3.1)
•Recommended Amperage: 35A with SA-HD; 30A (System Release 3.1 or higher); 20A (System Release prior to 3.1)
•Power Terminals: #6 Lug
Bandwidth Capacity
•Total Capacity: 240 Gb/s
•Data Plane Bandwidth: 160 Gb/s
•SONET plane bandwidth: 80 Gb/s
Database Storage
•Nonvolatile Memory (Flash): 256 MB (with TCC2/TCC2P)
•Volatile memory (synchronous dynamic RAM): 256 MB (with TCC2/TCC2P)
•When dual TCC2/TCC2P cards are installed in the ONS 15454, each TCC2/TCC2P card hosts a separate database; therefore, the protect card database is available if the database on the working TCC2/TCC2P fails. You can also store a backup version of the database on the workstation running CTC. This operation should be part of a regular ONS 15454 maintenance program at approximately weekly intervals, and should also be completed when preparing an ONS 15454 for a pending natural disaster, such as a flood or fire.
Note The following parameters are not backed up and restored: node name, IP address, mask and gateway, and Internet Inter-ORB Protocol (IIOP) port. If you change the node name and then restore a backed up database with a different node name, the circuits map to the new node name. Cisco recommends keeping a record of the old and new node names.
Synchronization
•Stratum 3, per Telcordia GR-253-CORE
•Free-running Access: Accuracy +/- 4.6 ppm
•Holdover Stability: 3.7 * 10-7 per day including temperature (< 255 slips in first 24 hours)
•Modes: External, Line, Mixed
•References: BITS 1, BITS 2, Line, Internal
•SSM Message Set: Generation 1 or Generation 2
BITS Interface
•Two DS-1 or 64KHz+8KHz (TCC2P with R5.0 and higher only) BITS inputs
•Two derived DS-1 or 6MHz (TCC2P with R5.0 and higher only) outputs
•BITS 1 and BITS 2 pins provided on backplane
•BITS Coding: AMI or B8ZS
•BITS Framing: SF (D4) or ESF
Operations Interface
•Local Craft Access: An EIA/TIA-232 ASCII interface (9600 baud) or 10BaseT LAN interface on the TCC2/TCC2P faceplate.
•External Network/LAN Access: A 10BaseT LAN interface via the backplane. Set the LAN 10/100 Ethernet port for half-duplex.
•Modem Access: An EIA/TIA-232 DB-9 type connector on the TCC2/TCC2P faceplate. See Table 6-3, Computer Requirements, for modem settings.
•TL1 Access: An EIA/TIA-232 ASCII interface (9600 baud) on the TCC2/TCC2P faceplate or 10BaseT LAN interface on both the TCC2/TCC2P faceplate and backplane.
•Cisco Transport Controller (CTC) Access: A 10BaseT LAN interface on the TCC2/TCC2P faceplate and backplane.
Computer Requirements
Table 6-3 lists the requirements for PCs and UNIX workstations. In addition to the Java Runtime Environment (JRE), the Java plug-in and modified java.policy file are also included on the ONS 15454 software CD and the ONS 15454 documentation CD.
|
|
|
|
|---|---|---|
Processor |
Pentium III (or higher) 700 MHz, UltraSPARC, or equivalent |
700 MHz is the recommended processor speed. You can use computers with a lower processor speed; however, you may experience longer response times and slower performance. |
RAM |
384 MB RAM recommended, |
Cisco recommends using 512 MB RAM for networks with 25 nodes or more to avoid longer response times and slower performance. |
Hard Drive |
20 GB recommended with 50 MB vacant space available |
— |
Operating System |
• • |
— |
JRE |
JRE 1.4.2 or 1.3.1_02 |
JRE 1.4.2 is installed by the CTC Installation Wizard included on the Cisco ONS 15454 software and documentation CDs. JRE 1.4.2 provides enhancements to CTC performance, especially for large networks with numerous circuits. Cisco recommends that you use JRE 1.4.2 for networks with Software R4.6 nodes. If CTC must be launched directly from nodes running software earlier than R4.6, Cisco recommends JRE 1.3.1_02. |
Web Browser |
• • |
For the PC, use JRE 1.4.2 or 1.3.1_02 with any supported web browser. For UNIX, use JRE 1.4.2 with Netscape 7.x or JRE 1.3.1_02 with Netscape 4.76. Netscape 4.76 or 7.x is available at the following site: Internet Explorer 6.x is available at the following site: http://www.microsoft.com |
java.policy File |
A java.policy file modified for CTC |
The java.policy file is modified by the CTC Installation Wizard included on the Cisco ONS 15454 software and documentation CDs. |
Cable |
User-supplied CAT-5 straight-through cable with RJ-45 connectors on each end to connect the computer to the ONS 15454 directly or through a LAN port on the TCC2/TCC2P faceplate |
— |
Modem |
A compatible modem must meet the following minimum requirements: • • • • • • • |
— |
Shelf Assemblies
The ONS 15454 shelf assembly is the physical steel enclosure that holds plug-in cards, EIAs, and connectors for power, grounding, and alarm contacts. Table 6-4 lists the shelf assemblies deployed to date, with the newest assembly available listed at the top of the table.
Shelf Assembly Overview
When installed in an equipment rack, the ONS 15454 assembly is typically connected to a fuse and alarm panel to provide centralized alarm connection points and distributed power for the ONS 15454. Fuse and alarm panels are third-party equipment and are not described in this documentation. The front door of the ONS 15454 allows access to the shelf assembly, fan-tray assembly, and cable-management area. The backplane provide access to alarm contacts, external interface contacts, power terminals, and BNC, SMB, and UBIC connectors.
You can mount the ONS 15454 in a 19- or 23-inch rack (482.6 or 584.2 mm). The shelf assembly ships preset for installation in a 23-inch (584.2 mm) rack, but you can reverse the mounting bracket to fit the smaller 19-inch (482.6 mm) rack. The shelf assembly weighs approximately 55 pounds (24.94 kg) with no cards installed. The shelf assembly includes a front door for added security, a fan tray module for cooling, and extensive cable-management space. An optional deep door kit (P/N 15454-SA-DRKIT) can be ordered to accommodate fiber jumpers requiring extended bending radius. The ONS 15454 must have one inch (25.4 mm) of airspace below the installed shelf assembly to allow air flow to the fan intake. If a second ONS 15454 is installed underneath the shelf assembly, the air ramp on top of the lower shelf assembly provides the air spacing needed and should not be modified in any way.
ONS 15454 optical cards have SC and LC connectors on the card faceplate. Fiber optic cables are routed into the front of the destination cards. Electrical cards (DS-1, DS-3, DS3XM, and EC-1) require electrical interface assemblies (EIAs) to provide the cable connection points for the shelf assembly. In most cases, EIAs are ordered with the ONS 15454 and come preinstalled on the backplane. See the Electrical Interface Assemblies section in this chapter for more information about the EIAs.
The ONS 15454 is powered using two -48 VDC power feeds (Breaker A and Breaker B) with a minimum of 30 Amp circuit breakers. Maximum power consumption is 1,060 Watts. Negative, return, and ground power terminals are accessible on the backplane. Figure 6-1 shows the dimensions of the ONS 15454 shelf assembly.
Figure 6-1 Shelf Assembly Dimensions
System Release 3.1 introduced the 15454-SA-ANSI shelf assembly. This shelf has enhanced fiber management capabilities and is designed to support the 10Gb/s hardware, which includes the XC-10G cross-connect, OC48 any slot, and OC192 cards.
Release 4.6 introduced the new high density 15454-SA-HD shelf assembly and updated universal backplane interface connector (UBIC) EIAs. This new high-density shelf assembly and UBICs with an increased number of connectors enables a single shelf to support up to 224 DS1s, 192 DS3/EC-1s, and 1:N protection where N is less than or equal to five, leveraging higher-density electrical cards, as well as free-up valuable shelf slots to be used for other service interfaces. Except for these changes and new symbols identifying the high density card slots, this new shelf is identical to the 15454-SA-ANSI shelf assembly. The high density shelf is software independent and backwards compatible with early releases.
Slot Assignments
As shown in Figure 6-2, the ONS 15454 shelf assembly has 17 card slots numbered sequentially from left to right. Slots 1 to 4 and 14 to 17 are multispeed slots. They can host any ONS 15454 plug-in card, except the OC48 IR 1310, OC48 LR 1550, OC48 ELR 1550, and OC192 LR 1550 cards. Slots 5, 6, 12, and 13 are high-speed slots. They can host all ONS 15454 cards, except the OC12/STM4-4 and OC3-8 cards. You can install the OC48 IR/STM16 SH AS 1310 and the OC48 LR/STM16 LH AS 1550 cards in any multispeed or high-speed card slot.
Slots 7 and 11 are dedicated to TCC2/TCC2P cards. Slots 8 and 10 are dedicated to cross-connect (XC, XCVT, XC10G) cards. Slot 9 is reserved for the optional Alarm Interface Controller (AIC or AIC-I) card. Slots 3 and 15 can also host DS1N-14 and DS3XM-12 cards that are used in 1:N protection.
Figure 6-2 ONS 15454 Shelf Assembly
Shelf assembly slots have symbols indicating the type of cards that you can install in them. Each ONS 15454 card has a corresponding symbol. The symbol on the card must match the symbol on the slot. Table 6-5 lists the slot and card symbol definitions.
Filler slot cards are available for any unpopulated card slot numbered 1 to 17, a blank filler slot card, model 15454-BLANK, must be installed to maintain proper airflow and compliance with NEBS EMI and ESD requirements.
Shelf Assembly Front Doors
The ONS 15454 shelf assembly features a standard locked door to the front compartment. A pinned hex key that unlocks the front door ships with the ONS 15454. A button on the right side of the shelf assembly releases the door. The front door shown in Figure 6-3 provides access to the shelf assembly, cable-management tray, fan-tray assembly, and LCD screen.
Figure 6-3 Shelf Assembly Front Door
The ONS 15454 ships with a standard door, but an optional deep door kit (P/N 15454-SA-DRKIT) can be ordered to accommodate fiber jumpers requiring an extended bending radius (see Figure 6-4).
Figure 6-4 Cisco ONS 15454 Deep Door
A button on the right side of the shelf assembly releases the door. You can remove the front door of the shelf assembly to provide unrestricted access to the front of the card slots. Before you remove the front door, you have to remove the ground strap of the front door as shown in Figure 6-5.
Figure 6-5 Front Door Ground Strap
An erasable label shown in Figure 6-6 is pasted on the inside of the front door. You can use the label to record slot assignments, port assignments, card types, node ID, rack ID, and serial number for the ONS 15454. The label also includes the Class I and Class 1M laser warning shown in Figure 6-7.
Figure 6-6 Erasable Label Inside Front Door
Figure 6-7 Laser Warning on the Front Door Label
Fan Tray Assembly
The fan tray assembly is located at the bottom of the ONS 15454 shelf assembly (see Figure 6-8). The fan tray is a removable drawer that holds fans and fan-control circuitry for the ONS 15454. The front door can be left in place when removing or installing the fan tray but removal is recommended. After you install the fan tray, you should only need to access it if a fan failure occurs or you need to replace or clean the fan-tray air filter.
There are presently two series of fan tray assemblies available for the ONS 15454:
1. FTA3-T high airflow assembly
2. FTA2 standard airflow assembly
Figure 6-8 Fan Tray Assembly
The fan tray slides into the ONS 15454, under the main card-cage (see Figure 6-8). Fan power, control, and status signals are provided by a rear connector that engages when the tray is inserted. The fans provide large volume airflow exceeding 100 linear feet per minute (LFM) across each of the plug-in cards. In addition to containing six variable-speed fans, the fan tray assembly provides a front-panel Liquid-Crystal Display, Status and Alarm LED's, and push-buttons, allowing for the quick monitoring of system status. A replaceable filter element slides in under the fan tray. The filter will function properly no matter which side faces up. This filter can be installed and removed by hand. Inspect the air filter every 30 days, and clean the filter every three to six months. Replace the air filter every two to three years and keep spare filters in stock. Avoid cleaning the air filter with harsh cleaning agents or solvents.
Do not operate an ONS 15454 without the mandatory fan-tray air filter.
Fan speed is controlled by TCC2/TCC2P card temperature sensors. The sensors measure the input air temperature at the fan-tray assembly. Fan speed options are low, medium, and high. If the TCC2/TCC2P card fails, the fans automatically shift to high speed. The temperature measured by the TCC2/TCC2P sensors is displayed on the LCD screen. Table 6-6 lists power requirements for the fan-tray assembly.
If one or more fans fail on the fan-tray assembly, replace the entire assembly. You cannot replace individual fans. The red Fan Fail LED on the front of the fan tray illuminates when one or more fans fail. For fan tray replacement instructions, refer to the Cisco ONS 15454 Troubleshooting Guide. The red Fan Fail LED clears after you install a working fan tray.
|
|
|
|
|
|---|---|---|---|
FTA2 |
53 |
1.21 |
198 |
FTA3 -T |
86.4 |
1.8 |
295 |
The FTA3-T shown in Figure 6-9 offers the higher airflow capabilities required to support ONS 15454 systems equipped with XC-10G cross-connect cards and is rated for industrial temperature installations (-40 to +65 Celsius). The FTA3-T employs a positive stop insertion pin (see Figure 6-9) to prevent the installation of the fan tray assembly into shelf assembly versions prior to the ANSI offering.
Figure 6-9 FTA3-T High Airflow Assembly
The FTA2 fan tray assembly is required for ONS 15454 System Release <3.1 and can be used in systems deployed for industrial temperature (I-temp) operation (-40o to +65o Celsius).
The compatibility between fan tray assemblies and shelf assemblies is outlined in Table 6-7.
Backplane
The backplane (Figure 6-10) provides access to alarm contacts, external interface contacts, power terminals, and Electrical Interface Assemblies (EIAs).
Figure 6-10 ONS 15454 Backplane
If a backplane does not have Electrical Interface Assembly (EIA) panels installed, it should have two sheet metal backplane covers (one on each side of the backplane) as illustrated in Figure 6-11. Each cover is held in place with nine 6-32 x 3/8 inch Phillips screws.
Figure 6-11 Sheet Metal Backplane Covers
Prior to System R4.0, the lower section of the backplane was covered by a clear plastic protector. With System R4.0 and higher, this section of the backplane is covered by a metal protector to reduce electro-magnetic interference. Both protectors are held in place by five 6-32 x 1/2 inch screws. Remove the lower backplane cover to access the alarm interface panel (AIP), alarm pin fields, frame ground, and power terminals (Figure 6-12).
Figure 6-12 Removable Lower Backplane Cover
The ONS 15454 has an optional plastic Rear Cover Assembly (RCA) that provides additional protection for the cables and connectors on the backplane (see Figure 6-13).
Figure 6-13 Plastic Rear Cover with Spacers
Alarm Interface Panel
The Alarm Interface Panel (AIP) is located next to the alarm contacts on the lower section of the backplane (see Figure 6-14). The AIP provides surge protection for the ONS 15454. It also provides an interface from the backplane to the fan tray assembly and LCD. The AIP plugs into the backplane using a 96-pin DIN connector and is held in place with two retaining screws. The panel has a non-volatile memory chip that stores the unique node address (MAC address).
Figure 6-14 Alarm Interface Panel
Alarm Interface Panel Replacement
Note Ensure that all nodes in the affected network are running the same software version before replacing the AIP and repairing circuits. If you need to upgrade nodes to the same software version, no hardware should be changed or circuit repair performed until after the software upgrade is complete.
If the AIP fails, a MAC Fail alarm displays on the CTC Alarms menu and/or the LCD display on the fan-tray assembly will go blank. To perform an in-service replacement of the AIP, you must contact Cisco Technical Assistance Center (TAC) at 877-323-7368.
You can replace the AIP on an in-service system without affecting traffic (except Ethernet traffic on nodes running a software release earlier than Release 4.0). The circuit repair feature allows you to repair circuits affected by MAC address changes on one node at a time. Circuit repair will work when all nodes are running the same software version. Each individual AIP upgrade requires an individual circuit repair; if AIPs are replaced on two nodes, the circuit repair must be performed twice.
Do not use a 2-A AIP with a 5-A fan-tray assembly; doing so will cause a blown fuse on the AIP.
Note The 5-A AIP (73-7665-XX) is required when installing the new fan-tray assembly (15454-FTA3), which comes preinstalled on the shelf assembly (15454-SA-ANSI).
Note The MAC address identifies the nodes that support circuits. It allows CTC to determine circuit sources, destinations, and spans. The TCC2 or TCC2P cards in the ONS 15454 also use the MAC address to store the node's database.
Note A blown fuse on the AIP board can cause the LCD display to go blank.
Alarm Contacts
The ONS 15454 has a backplane pin field located at the bottom of the backplane (see Figure 6-15). The backplane pin field provides 0.045 square inch wire-wrap pins for enabling external alarms, timing input and output, and craft interface terminals.
Figure 6-15 ONS 15454 Backplane Pinouts (System Release 3.4 or Later)
Visual and audible alarms are typically wired to trigger an alarm light or bell at a central alarm collection point when the corresponding contacts are closed. You can use the Alarm Cutoff pins to activate a remote ACO (Alarm Cut Off) for audible alarms. You can also activate the ACO function by pressing the ACO button on the TCC2/TCC2P card faceplate. The ACO function clears all audible alarm indications. After clearing the audible alarm indication, the alarm is still present and viewable in the Alarms tab in CTC.
Alarm Expansion Panel
The optional alarm expansion panel (AEP) can be used with the enhanced Alarm Interface Controller card (AIC-I) card to provide an additional 48 dry alarm contacts, 32 of which are inputs and 16 are outputs. The AEP shown in Figure 6-16 is a printed circuit board assembly that is installed on the backplane. Here, the left connector is the input connector and the right connector is the output connector.
Figure 6-16 AEP Printed Circuit Board Assembly
The AIC-I without an AEP already contains direct alarm contacts. These direct AIC-I alarm contacts are routed through the backplane to wire-wrap pins accessible from the back of the shelf. If you install an AEP, you cannot use the alarm contacts on the wire-wrap pins.
See the Cisco ONS 15454 Reference Manual for AEP Specifications.
Electrical Interface Assemblies
Electrical Interface Assemblies (EIAs) are typically pre-installed when ordered with the ONS 15454. EIAs must be ordered when using DS-1, DS-3, DS3XM-6, DS3XM-12, EC-1, or DS3/EC1-48 cards.
Seven different EIA backplane covers are available for the ONS 15454:
1. BNC
2. High-Density BNC
3. Mini BNC
4. SMB
5. AMP Champ
6. UBIC-V
7. UBIC-H
EIAs are attached to the shelf assembly backplane to provide electrical interface cable connections. EIAs are available with SMB, BNC, and SCSI connectors for DS-3 or STS-1 electrical circuits. EIAs are available with AMP Champ and SCSI connectors for DS-1 circuits. You must use SMB or UBIC EIAs for DS-1 twisted-pair cable installations. UBIC-V, UBIC-H or Mini-BNC (DS3/EC-1) EIAs are required when using the high-density (48-port DS-3/EC-1 and 56-port DS-1) electrical cards. UBIC-V and UBIC-H EIAs use 50-pin SCSI connectors for DS3, EC-1 and DS-1 circuits.
You can install EIAs on one or both sides of the ONS 15454 backplane in any combination (in other words, AMP Champ on Side A and BNC on Side B or High-Density BNC on side A and SMB on side B, and so forth including the UBIC).
As you face the rear of the ONS 15454 shelf assembly, the right-hand side is the A side and the left-hand side is the B side. The top of the EIA connector columns are labeled with the corresponding slot number, and EIA connector pairs are marked transmit (Tx) and receive (Rx) to correspond to transmit and receive cables.
EIA Configurations
The matrix provided in Table 6-8 describes the EIA configurations available for the ONS 15454.
1 High-density card slots. |
Low-Density BNC EIA
You can use BNC EIAs for DS-3 and STS-1 electrical circuits. The Low-Density BNC EIA supports 24 DS-3 or 24 STS-1 electrical circuits on each side of the ONS 15454 (24 transmit and 24 receive connectors). If you install Low-Density BNC EIAs on both sides of the shelf assembly, the ONS 15454 hosts up to 48 circuits. The BNC connectors on the EIA supports Trompeter UCBJ224 (75-ohm) 4-leg connectors (King or ITT are also compatible). Right-angle mating connectors for the connecting cable are AMP 413588-2 (75-ohm) connectors. If preferred, you can also use a straight connector of the same type. Use RG-59/U cable to connect to the ONS 15454 BNC EIA. These cables are recommended to connect to a patch panel and are designed for long runs. You can use Low-Density BNC EIAs with the DS3-12, DS3-12E, DS3XM-6, DS3XM-12, or EC1-12 cards. Figure 6-17 shows the ONS 15454 with pre-installed Low-Density BNC EIAs.
Figure 6-17 Low-Density BNC EIA for use in 1:1 Protection Schemes
The EIA side marked "A" has 24 pairs of BNC connectors. The first 12 pairs of BNC connectors correspond to Ports 1 to 12 for a 12-port card and map to Slot 2 on the shelf assembly. The BNC connector pairs are marked "Tx" and "Rx" to indicate transmit and receive cables for each port. You can install an additional card in Slot 1 as a protect card for the card in Slot 2. The second 12 BNC connector pairs correspond to Ports 1 to 12 for a 12-port card and map to Slot 4 on the shelf assembly. You can install an additional card in Slot 3 as a protect card for the card in Slot 4. Slots 5 and 6 do not support DS-3 cards when the standard BNC EIA panel connectors are used.
The EIA side marked "B" provides an additional 24 pairs of BNC connectors. The first 12 BNC connector pairs correspond to Ports 1 to 12 for a 12-port card and map to Slot 14 on the shelf assembly. The BNC connector pairs are marked "Tx" and "Rx" to indicate transmit and receive cables for each port. You can install an additional card in Slot 15 as a protect card for the card in Slot 14. The second 12 BNC connector pairs correspond to Ports 1 to 12 for a 12-port card and map to Slot 16 on the shelf assembly. You can install an additional card in Slot 17 as a protect card for the card in Slot 16. Slots 12 and 13 do not support DS-3 cards when the standard BNC EIA panel connectors are used.
When BNC connectors are used with a DS3N-12 card in Slot 3 or 15, the 1:N card protection extends only to the two slots adjacent to the 1:N card due to BNC wiring constraints.
High-Density BNC EIA
The ONS 15454 high-density BNC EIA supports 48 DS-3 or STS-1 circuits on each side of the ONS 15454 (48 transmit and 48 receive connectors). If you install BNC EIAs on both sides of the unit, the ONS 15454 hosts up to 96 circuits. The high-density BNC EIA supports Trompeter UCBJ224 (75 ohm) 4 leg connectors (King or ITT are also compatible). Use straight connectors on RG-59/U cable to connect to the high-density BNC EIA. Cisco recommends these cables for connection to a patch panel; they are designed for long runs. You can use high-density BNC EIAs with DS3-12, DS3-12E, DS3XM-6, DS3XM-12, or EC1-12 cards. Figure 6-18 shows the ONS 15454 with pre-installed high-density BNC EIAs.
Figure 6-18 High-Density BNC Backplane for use in 1:N Protection Schemes
The EIA side marked "A" hosts 48 pairs of BNC connectors. Each column of connector pairs is numbered and corresponds to the slot of the same number. The first column (12 pairs) of BNC connectors corresponds to Slot 1 on the shelf assembly, the second column to Slot 2, the third column to Slot 4, and the fourth column to Slot 5. The rows of connectors correspond to Ports 1 to 12 of a 12-port card.
The EIA side marked "B" provides an additional 48 pairs of BNC connectors. The first column (12 pairs) of BNC connectors corresponds to Slot 13 on the shelf assembly, the second column to Slot 14, the third column to Slot 16, and the fourth column to Slot 17. The rows of connectors correspond to Ports 1 to 12 of a 12-port card. The BNC connector pairs are marked "Tx" and "Rx" to indicate transmit and receive cables for each port. The High-Density BNC EIA supports both 1:1 and 1:N protection across all slots except Slots 6 and 12.
BNC Insertion and Removal Tool
Due to the large number of BNC connectors on the High-Density BNC EIA, you might require a special tool for inserting and removing BNC EIAs (see Figure 6-19). This tool also helps with ONS 15454 patch panel connections.
Figure 6-19 BNC Insertion and Removal Tool
The BNC insertion and removal tool can be obtained from the following vendors:
•Trompeter Electronics Inc. (www.trompeter.com)
31186 La Baya Drive
Westlake Village, CA 91362-4047
Phone: (800) 982-2629 Fax: (818) 706-1040
Part Number: RT-1L
MiniBNC EIA
The ONS 15454 MiniBNC EIA supports a maximum of 192 transmit and receive DS-3 or STS-1 electrical connections, 96 per side (A and B) through 192 miniBNC connectors on each side. If you install BNC EIAs on both sides of the unit, the ONS 15454 hosts up to 192 circuits. The MiniBNC EIAs are designed to support DS-3 and EC-1 signals. The MiniBNC EIA supports the following cards:
•DS3-12
•DS3-12E
•EC1-12
•DS3XM-6
•DS3XM-12
•DS3/EC1-48
Note EC-1 functionality will be available on the 48-port DS-3/EC-1 card in a future software release.
Mini BNC Insertion and Removal Tool
Due to the large number of BNC connectors on the High-Density BNC EIA, you might require a special tool for inserting and removing BNC EIAs (see Figure 6-19). This tool also helps with ONS 15454 patch panel connections.
Figure 6-20 Mini BNC Insertion and Removal Tool
The Mini BNC insertion and removal tool can be obtained from the following vendors:
•Trompeter Electronics Inc. (www.trompeter.com)
31186 La Baya Drive
Westlake Village, CA 91362-4047
Phone: (800) 982-2629 Fax: (818) 706-1040
Part Number: RT-4L
SMB EIA
The ONS 15454 SMB EIA supports AMP 415484-1 75 ohm 4 leg connectors. Right-angle mating connectors for the connecting cable are AMP 415484-2 (75 ohm) connectors. Use RG-179/U cable to connect to the ONS 15454 EIA. Cisco recommends these cables for connection to a patch panel; they are not designed for long runs. Range does not affect loopback testing.
You can use SMB EIAs with DS1-14, DS3-12, DS3-12E, DS3XM-6, DS3XM-12, and EC1-12 cards. If you use DS1-14 cards, use the DS-1 electrical interface adapter (balun) to terminate the twisted pair DS-1 cable to the SMB EIA. SMB EIAs support 14 ports per slot when used with a DS1-14 card, 12 ports per slot when used with a DS3-12, DS3XM-12, or EC1-12 card, and 6 ports per slot when used with a DS3XM-6 card.
Figure 6-21 shows the ONS 15454 with pre-installed SMB EIAs and the sheet metal cover and screw locations for the EIA. The SMB connectors on the EIA are AMP 415504-3 (75 ohm) 4 leg connectors.
Figure 6-21 SMB EIA
The SMB EIA has 84 transmit and 84 receive connectors on each side of the ONS 15454 for a total of 168 SMB connectors (84 circuits).
The SMB EIA side marked "A" hosts 84 SMB connectors in six columns of 14 connectors. The "A" side columns are numbered 1 to 6 and correspond to Slots 1 to 6 on the shelf assembly. The SMB EIA side marked "B" hosts an additional 84 SMB connectors in six columns of 14 connectors. The "B" side columns are numbered 12 to 17 and correspond to Slots 12 to 17 on the shelf assembly. The connector rows are numbered 1 to 14 and correspond to the 14 ports on a DS-1 card.
For DS-3 or EC-1, the SMB EIA supports 72 transmit and 72 receive connectors, for a total of 144 SMB connectors (72 circuits). If you use a DS-3 or EC-1 card, only ports 1 to 12 are active. If you use a DS3XM-6 card, only ports 1 to 6 are active. The SMB connector pairs are marked "Tx" and "Rx" to identify transmit and receive cables for each port. If you use SMB connectors, you can install DS-1, DS-3, or EC-1 cards in any multispeed slot (Slots 1 to 6 or 12 to 17).
AMP Champ EIA
The ONS 15454 AMP Champ EIA supports 64-pin (32 pair) AMP Champ connectors for each slot on both sides of the shelf assembly where the EIA is installed. Cisco AMP Champ connectors are female AMP # 552246-1 with AMP # 552562-2 bail locks. Each AMP Champ connector supports 14 DS-1 ports. You can use AMP Champ EIAs with DS-1 cards only. Figure 6-22 shows the ONS 15454 with pre-installed AMP Champ EIAs and the corresponding sheet metal cover and screw locations for the EIA.
Figure 6-22 AMP EIA Champ Backplane
The EIA side marked "A" hosts six AMP Champ connectors. The connectors are numbered 1 to 6 for the corresponding slots on the shelf assembly. Each AMP Champ connector on the backplane supports 14 DS-1 ports for a DS1-14 card, and each connector features 28 live pairs (one transmit pair and one receive pair) for each DS-1 port.
The EIA side marked "B" hosts six AMP Champ connectors. The connectors are labeled 12 to 17 for the corresponding slots on the shelf assembly. Each AMP Champ connector on the backplane supports 14 DS-1 ports for a DS1-14 card, and each connector features 28 live pairs (one transmit pair and one receive pair) for each DS-1 port.
UBIC-V EIA
The universal backplane interface connector (UBIC-V) backplane covers are typically preinstalled when ordered with the ONS 15454 high density shelf (15454-SA-HD). UBIC-Vs are required when using the high-density (48-port DS-3/EC-1 and 56-port DS-1) electrical cards.
UBIC-V EIAs are attached to the shelf assembly backplane to provide up to 112 transmit and receive connections through 16 SCSI connectors per side (A and B). The UBIC-V EIAs are designed to support DS-1, DS-3, and EC-1 signals. The appropriate cable assembly is required depending on the type of signal.
You can install UBIC-Vs on one or both sides of the ONS 15454. As you face the rear of the ONS 15454 shelf assembly, the right side is the A side (15454-EIA-UBIC-V-A) and the left side is the B side (15454-EIA-UBIC-V-B). The diagrams adjacent to each row of SCSI connectors indicate the slots and ports that correspond with each SCSI connector in that row, depending on whether you are using a high-density (HD) or low-density (LD) configuration. UBIC-V EIAs will support the high-density DS3/EC1-48 and DS3XM-12 cards, as well as low-density electrical cards. Figure 6-23 shows the slot assignments for sides A and B.
Note The high-density DS1-56 electrical card will be available in a future release.
Figure 6-23 UBIC-V Slot Designations
The UBIC-V sheet metal covers use the same screw holes as the standard sheet metal covers, but they have 12 additional holes for pan-head screws and three holes for jack screws, so you can screw down the cover and the board using standoffs on the UBIC-V board.
When installed with the standard door and cabling on the backplane, the ONS 15454 shelf measures approximately 15.7 inches deep when partially populated with backplane cables, 16.1 inches deep when fully populated, and 16.75 inches deep with the rear cover installed.
When installed with the deep door and cabling on the backplane, the ONS 15454 shelf measures approximately 17.5 inches deep when partially populated with backplane cables, 17.9 inches deep when fully populated, and 18.55 inches deep with the rear cover installed.
The A and B sides each host 16 high-density, 50-pin SCSI connectors. The A-side maps to Slots 1 through 6 and the B-side maps to Slots 12 through 17.
In Software Releases 4.1.x and 4.6.x, UBIC-V EIAs support unprotected, 1:1, and 1:N (N < 5) protection groups. In Software R5.0 and higher, UBIC-V EIAs also support available high-density cards in unprotected and 1:N (N < 2) protection groups.
UBIC-H EIA
UBIC-H EIAs are attached to the shelf assembly backplane to provide up to 112 transmit and receive DS-1 connections through 16 SCSI connectors per side (A and B) or 96 transmit and receive DS-3 connections. The UBIC-H EIAs are designed to support DS-1, DS-3, and EC-1 signals. The appropriate cable assembly is required depending on the type of signal.
You can install UBIC-H EIAs on one or both sides of the ONS 15454. As you face the rear of the ONS 15454 shelf assembly, the right side is the A side (15454-EIA-UBICH-A) and the left side is the B side (15454-EIA-UBICH-B). The J-labels adjacent to each row of SCSI connectors indicate the slots and ports that correspond with each SCSI connector in that row, depending on whether you are using a high density (HD) or low density (LD) configuration. UBIC-H EIAs will support the high-density DS3/EC1-48 and DS3XM-12 cards, as well as low-density electrical cards. Figure 6-24 shows the A and B side connector labeling.
Note The high-density DS1-56 electrical card will be available in a future release.
Figure 6-24 UBIC-H EIA Connector Labeling
When installed with the standard door and cabling on the backplane, the ONS 15454 shelf measures approximately 14.5 inches deep when fully populated with backplane cables, and 15.0 inches deep with the rear cover installed.
When installed with the deep door and cabling on the backplane, the ONS 15454 shelf measures approximately 16.5 inches deep when fully populated with backplane cables, and 17.0 inches deep with the rear cover installed.
The A and B sides each host 16 high-density, 50-pin SCSI connectors. The A-side maps to Slots 1 through 6 and the B-side maps to Slots 12 through 17.
In Software Releases prior to Release 5.0, UBIC-H EIAs support unprotected, 1:1, and 1:N (where N < 5) protection groups. In Software R5.0 and greater, UBIC-Hs additionally support available high-density cards in unprotected and 1:N protection (where N < 2) protection groups.
Plug-in Cards
ONS 15454 plug-in cards have electrical plugs at the back that plug into electrical connectors on the shelf assembly backplane. When the ejectors are fully closed, the card plugs into the assembly backplane. Figure 6-25 shows card installation.
Figure 6-25 Installation of Plug-in Cards
Release 5.0 features background ASIC monitoring for all line cards and cross connect cards, standby assurance for DS-3 cards, and BLSR PCA Pseudo Random Bit Signal (PRBS) generation and detection. This inhibits switching to a failed line card, if such a card exists, by generating a diagnostic failure alarm. The feature also causes a switch-away on the cross connect cards via an equipment failure alarm. All diagnostic failures are logged in the alarm history. The feature accomplishes these goals by adding three new timers that ensure the correct state of the cards at key points in card communication. A verification guard timer is used when a Force is issued, to ensure that the far end has a chance to respond. A detection guard timer is used to ensure the presence of an SF/SD condition before switching away from a card. A recover guard timer ensures the absence of SF/SD prior to switching to a card.
Card Replacement
To replace an ONS 15454 card with another card of the same type, you do not need to make any changes to the database; remove the old card and replace it with a new card. To replace a card with a card of a different type, physically remove the card and replace it with the new card, then delete the original card from CTC. For specifics, refer to the Cisco ONS 15454 Procedure Guide.
Card Descriptions
The tables in this section describe the function and slot assignment for each ONS 15454 plug-in card. Each card is marked with a symbol that corresponds to a slot (or slots) on the ONS 15454 shelf assembly. The cards can only be installed into slots displaying the same symbols.
•Refer to Table 6-9 for Common Card Functions and Slot Assignment
•Refer to Table 6-10 for Electrical Card Functions and Slot Assignment
•Refer to Table 6-11 for Optical Card Functions and Slot Assignment
•Refer to Table 6-12 for Transponder and Muxponder Card Functions and Slot Assignments
•Refer to Table 6-15 for Ethernet Card Functions and Slot Assignment
•Refer to Table 6-17 for DWDM Card Functions and Slot Assignment
•Refer to Table 6-16 for Storage Area Network (SAN) Transport Card Function and Slot Assignment
See http://cisco.com/en/US/products/hw/optical/ps2006/prod_eol_notices_list.html for the latest list of End-Of-Life and End-Of-Sale notices.
Note Do not operate the ONS 15454 with only one TCC card and one XC/XCVT/XC10G card. Two TCC and cross-connect cards must always be installed for redundant operation.
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OC3-IR-4/STM1-SH-1310 nm |
The OC3 IR 4/STM1 SH 1310 card provides four intermediate- or short-range SONET/SDH OC-3 ports compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. Each port operates at 155.52 Mb/s over a single-mode fiber span. The card supports VT and non-concatenated or concatenated payloads at the STS-1 or STS-3c signal levels. The OC3 IR 4/STM1 SH 1310 card supports 1+1 unidirectional or bidirectional protection switching. You can provision protection on a per port basis. The card uses SC connectors. |
1-6 and 12-17 |
OC3-IR-8/STM1-SH-1310 nm |
The OC3IR/STM1SH 1310-8 card provides eight intermediate- or short-range SONET/SDH OC-3 ports compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. Each port operates at 155.52 Mb/s over a single-mode fiber span. The card supports the same payloads and protection schemes as the four port OC3 card. (labeled) on the card faceplate. The card uses LC connectors on the faceplate, angled downward 12.5 degrees. |
1-4 and 14-17 |
OC12-IR/STM4-SH-1310 nm |
The OC12 IR/STM4 SH 1310 card provides one intermediate- or short-range SONET/SDH OC-12 port compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. The port operates at 622.08 Mb/s over a single-mode fiber span. The card supports VT and non-concatenated or concatenated payloads at STS-1, STS-3c, STS-6c or STS-12c signal levels. The OC12 IR/STM4 SH 1310 card supports 1+1 unidirectional or bidirectional protection switching. You can provision protection on a per port basis. The card uses SC connectors. |
1-6 and 12-17 |
OC12-LR/STM4-LH-1310 nm |
The OC12 LR/STM4 LH 1310 card provides one long-range SONET OC-12 port per card compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. The port operates at 622.08 Mb/s over a single-mode fiber span. The card supports the same payloads and protection schemes as the OC12 IR/STM4 SH 1310 card. The OC12 LR/STM4 LH 1310 uses SC connectors. |
1-6 and 12-17 |
OC12-LR/STM4-LH-1550 nm |
The OC12 LR/STM4 LH 1550 card provides one long-range SONET/SDH OC-12 port compliant with the ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. The port operates at 622.08 Mb/s over a single-mode fiber span. The card supports the same payloads and protection schemes as the OC12 IR/STM4 SH 1310 card. The OC12 LR/STM4 LH 1550 card uses SC connectors. |
1-6 and 12-17 |
OC12-IR-4/STM4-SH-1310 nm |
The OC12 IR/STM4 SH 1310-4 card provides four intermediate- or short-range SONET/SDH OC-12/STM-4 ports compliant with the ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. Each port operates at 622.08 Mb/s over a single-mode fiber span. The card supports VT and non-concatenated or concatenated payloads at the STS-1, STS-3c, STS-6c, or STS-12c signal levels. The OC12 IR/STM4 SH 1310-4 card supports 1+1 unidirectional or bidirectional protection switching. You can provision protection on a per port basis. The OC12 IR/STM4 SH 1310-4 card uses SC connectors. |
1-4 and 14-171 |
OC48-IR-1310 nm |
The OC48 IR 1310 card provides one intermediate-range, SONET OC-48 port per card, compliant with Telcordia GR-253-CORE. Each port operates at 2.49 Gb/s over a single-mode fiber span. The card supports VT and non-concatenated, or concatenated payloads at STS-1, STS-3c, STS-6c, STS-12c, or STS-48c signal levels. The OC48 IR 1310 card supports 1+1 unidirectional or bidirectional protection switching. The OC48 IR 1310 card uses SC connectors. |
5, 6, 12, and 13 |
OC48-LR-1550 nm |
The OC48 LR 1550 card provides one long-range, SONET OC-48 port per card, compliant with Telcordia GR-253-CORE. Each port operates at 2.49 Gb/s over a single-mode fiber span. The card supports VT, non-concatenated or concatenated payloads at STS-1, STS-3c, STS-6c STS-12c or STS-48c signal levels. The OC48 LR 1550 card supports 1+1 unidirectional or bidirectional protection switching. The OC48 LR 1550 card uses SC connectors. |
5, 6, 12, and 13 |
OC48-IR/STM16-SH-AS-1310 nm |
The OC48 IR/STM16 SH AS 1310 card provides one intermediate-range SONET/SDH OC-48 port compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. The port operates at 2.49 Gb/s over a single-mode fiber span. The card supports VT and non-concatenated or concatenated payloads at STS-1, STS-3c, STS-6c, STS-12c, or STS-48c signal levels. The card supports 1+1 unidirectional or bidirectional protection switching and uses SC connectors. |
1-6 and 12-17 |
OC48-LR/STM16-LH-AS-1550 nm |
The OC48 LR/STM16 LH AS 1550 card provides one long-range SONET/SDH OC-48 port compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. The OC48 LR/STM16 LH AS 1550 and OC48 IR/STM16 SH AS 1310 cards are functionally the same. |
1-6 and 12-17 |
OC48-ELR/STM16-EH-ITU-100GHz |
Thirty-seven distinct OC48 ELR/STM16 EH 100 GHz cards provide the ONS 15454 DWDM channel plan. Nineteen of the cards operate in the blue band with spacing of 100 GHz on the ITU grid (1528.77 nm, 1530.33 nm, 1531.12 nm, 1531.90 nm, 1532.68 nm, 1533.47 nm, 1534.25 nm, 1535.04 nm, 1535.82 nm, 1536.61 nm, 1538.19 nm, 1538.98 nm, 1539.77 nm, 1540.56 nm, 1541.35 nm, 1542.14 nm, 1542.94 nm, 1543.73 nm, 1544.53 nm). ITU spacing conforms to ITU-T G.692 and Telcordia GR-2918-CORE, issue 2. The other eighteen cards operate in the red band with spacing of 100 GHz on the ITU grid (1546.12 nm, 1546.92 nm, 1547.72 nm, 1548.51 nm,1549.32 nm, 1550.12 nm, 1550.92 nm, 1551.72 nm, 1552.52 nm, 1554.13 nm, 1554.94 nm, 1555.75 nm, 1556.55 nm, 1557.36 nm, 1558.17 nm, 1558.98 nm, 1559.79 nm, 1560.61 nm). These cards are also designed to interoperate with Cisco's ONS 15454) DWDM solution. Each OC48 ELR/STM16 EH 100 GHz card has one SONET OC-48/SDH STM-16 port that complies with Telcordia GR-253-CORE, ITU-T G.692, and ITU-T G.958. The port operates at 2.49 Gb/s over a single-mode fiber span. The card carries VT, concatenated, and non-concatenated payloads at STS-1, STS-3c, STS-6c, STS-12c, or STS-48c signal levels. Each card supports 1+1 unidirectional or bidirectional protection switching and uses SC connectors. |
5, 6, 12, and 13 |
OC192-SR/STM64-IO-1310 nm |
The OC192 SR/STM64 IO 1310 card provides one intra-office (IO) short-range SONET/SDH OC-192 port in the 1310-nm wavelength range, compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. The port operates at 9.95328 Gb/s and supports VT and non-concatenated or concatenated payloads. The OC192 SR/STM64 IO 1310 card supports 1+1 unidirectional or bidirectional protection switching and uses SC connectors. |
5, 6, 12, and 13 |
OC192-IR/STM64-SH-1550 nm |
The OC192 IR/STM64 SH 1550 card provides one intermediate-range SONET/SDH OC-192 port in the 1550-nm wavelength range, compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. The port operates at 9.95328 Gb/s and supports VT and non-concatenated or concatenated payloads. The OC192 IR/STM64 SH 1550 card supports 1+1 unidirectional or bidirectional protection switching and uses SC connectors. |
5, 6, 12, and 13 |
OC192-LR/STM64-LH-1550 nm |
The OC192 LR/STM64 LH 1550 card provides one long-range SONET/SDH OC-192 port compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE. The OC192 LR/STM64 LH 1550 and OC192 IR/STM64 SH 1550 cards are functionally the same. |
5, 6, 12, and 13 |
OC192-LR/STM64-LH-ITU-100GHz |
Sixteen distinct OC-192/STM-64 ITU 100 GHz DWDM cards comprise the ONS 15454 DWDM channel plan. 2 Eight of the cards operate in the blue band with a spacing of 100 GHz in the ITU grid (1534.25 nm, 1535.04 nm, 1535.82 nm, 1536.61 nm, 1538.19 nm, 1538.98 nm, 1539.77 nm, and 1540.56 nm). The other eight cards operate in the red band with a spacing of 100 GHz in the ITU grid (1550.12 nm, 1550.92 nm, 1551.72 nm, 1552.52 nm, 1554.13 nm, 1554.94 nm, 1555.75 nm, and 1556.55 nm). The OC192 LR/STM64 LH ITU card provides one long-reach STM-64/OC-192 port per card, compliant with ITU-T G.707, ITU-T G.957, and Telcordia GR-253-CORE . The port operates at 9.95328 Gb/s and supports VT and non-concatenated or concatenated payloads. Each card supports 1+1 unidirectional or bidirectional protection switching and uses SC connectors. |
5, 6, 12, and 13 |
1 If you ever expect to upgrade an OC-12/STM-4 ring to a higher bit rate, you should not put an OC12 IR/STM4 SH 1310-4 in that ring. The four-port card is not upgradable to a single-port card. The reason is that four different spans, possibly going to four different nodes, cannot be merged to a single span. 2 Of the sixteen OC-192/STM-64 ITU 100 GHz DWDM cards, the following eight cards are available with System Release 4.0: 1534.25 nm, 1535.04 nm, 1535.82 nm, 1536.61 nm, 1550.12 nm, 1550.92 nm, 1551.72 nm, and 1552.52 nm. |
The TXP_MR_2.5G and TXPP_MR_2.5G cards support 2R and 3R modes of operation where the client signal is mapped into a ITU-T G.709 frame. The mapping function is simply done by placing a digital wrapper around the client signal. Only OC-48/STM-16 client signals are fully ITU-T G.709 compliant and the output bit rate depends on the input client signal. Table 6-13 shows the possible combinations of client interfaces, input bit rates, 2R and 3R modes, and ITU-T G.709 monitoring.
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OC-48/STM-16 |
2.488 Gb/s |
3R |
On or Off |
DV-6000 |
2.38 Gb/s |
2R |
NA |
2 Gigabit Fiber Channel (2G-FC)/FICON |
2.125 Gb/s |
3R1 |
On or Off |
High definition television (HDTV) |
1.48 Gb/s |
2R |
NA |
Gigabit Ethernet (GE) |
1.25 Gb/s |
3R |
On or Off |
1 Gigabit Fiber Channel (1G-FC)/FICON |
1.06 Gb/s |
3R |
On or Off |
OC-12/STM-4 |
622 Mb/s |
3R |
On or Off |
OC-3/STM-1 |
155 Mb/s |
3R |
On or Off |
ESCON |
200 Mb/s |
2R |
NA |
SDI/D1 Video |
270 Mb/s |
2R |
NA |
1 No monitoring. |
The output bit rate is calculated for the trunk bit rate by using the 255/238 ratio as specified in ITU-T G.709 for OTU1. Table 6-14 lists the calculated trunk bit rates for the client interfaces with ITU-T G.709 enabled.
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CE-100T-8 |
The CE-100T-8 card provides eight RJ-45 10/100 Mb/s Ethernet ports as well as an RJ-45 console port, all of which are accessible at the faceplate. The CE-100T-8 card provides mapping of 10/100 Mb/s Ethernet traffic into SONET STS-12 payloads, making use of low order (VT1.5) virtual concatenation, high order (STS-1) virtual concatenation, and generic framing procedure (GFP), point-to-point protocol/high-level data link control (PPP/HDLC) framing protocols. It also supports the link capacity adjustment scheme (LCAS), which allows hitless dynamic adjustment of SONET link bandwidth. The circuit types supported are: • • • • Each 10/100 Ethernet port can be mapped to a SONET channel in increments of VT1.5 or STS-1 granularity, allowing an efficient transport of Ethernet and IP over the SONET infrastructure. |
1-6 and 12-17 |
E100T-121 |
Use the E100T-12 with the XC or XCVT cards. The E100T-12 card provides 12 switched, IEEE 802.3-compliant, 10/100BaseT Ethernet ports that can independently detect the speed of an attached device (autosense) and automatically connect at the appropriate speed. The ports auto configure to operate at either half or full duplex and determine whether to enable or disable flow control. You can also configure Ethernet ports manually. Each E100T-12 card supports standards-based, wire-speed, Layer 2 Ethernet switching between its Ethernet interfaces. The IEEE 802.1Q tag logically isolates traffic (typically subscribers). IEEE 802.1Q also supports multiple classes of service. The E100T-12 ports use RJ-45 interfaces. |
1-6 and 12-17 |
E1000-21 |
Use the E1000-2 with the XC or XCVT cards. Do not use the E1000-2 when the XC10G card is in use. The E1000-2 card provides two IEEE 802.3 compliant 1000 Mb/s ports for high-capacity customer LAN interconnections. Each port supports full-duplex operation. Each E1000-2 card supports standards-based, Layer 2 Ethernet switching between its Ethernet interfaces and SONET interfaces on the ONS 15454. The IEEE 802.1Q VLAN tag logically isolates traffic (typically subscribers). The E1000-2 card uses GBIC modular receptacles for the optical interfaces. |
11-6 and 12-17 |
E100T-G |
The E100T-G is the functional equivalent of the E100T-12, but will interoperate with the XC10G cross-connect. The E100T-G ports use RJ-45 interfaces. |
1-6 and 12-17 |
E1000-2-G |
The E1000-2-G is the functional equivalent of the E1000-2, but will interoperate with the XC10G cross-connect. |
1-6 and 12-17 |
G1000-41 |
Use the G1000-4 card with the XC-10G card. The G1000-4 card provides four ports of IEEE 802.3 compliant 1000-Mb/s interfaces. Each port supports full-duplex operation for a maximum bandwidth of OC-48 on each card. The circuit sizes supported are STS-1, STS-3c, STS-6c, STS-9c, STS-24c, STS-48c. The G1000-4 card uses GBIC modular receptacles for the optical interfaces. |
1-6 and 12-17 |
G1K-4 |
The G1K-4 card provides four ports of IEEE 802.3 compliant 1000-Mb/s interfaces. Each interface supports full-duplex operation for a maximum bandwidth of 1 Gb/s or 2 Gb/s bidirectional per port, and 2.5 Gb/s or 5 Gb/s bidirectional per card. Each port auto negotiates for full duplex and 802.3z flow control. The circuit sizes supported are STS-1, STS-3c, STS-6c, STS-9c, STS-24c, STS-48c. The G1K-4 card uses GBIC modular receptacles for the optical interfaces. |
1-6 and 12-17 |
ML100T-12 |
The ML100T-12 card provides 12 ports of IEEE 802.3 compliant 10/100 interfaces. Each card supports standards-based, wire-speed, Layer 2 Ethernet switching between its Ethernet ports. The IEEE 802.1Q tag and port-based VLANs logically isolate traffic (typically subscribers). Priority queuing is also supported to provide multiple classes of service. Each interface supports full-duplex operation for a maximum bandwidth of 200 Mb/s per port and 2.488 Gb/s per card. Each port independently detects the speed of an attached device (autosenses) and automatically connects at the appropriate speed. The ports auto configure to operate at either half or full duplex and can determine whether to enable or disable flow control. The card features two virtual packet over SONET (POS) ports with a maximum combined bandwidth of STS-48. The ports function in a manner similar to OC-N card ports, and each port carries an STS circuit with a size of STS-1, STS-3c, STS-6c, STS-9c, STS-12c, or STS-24c. The ML-Series POS ports supports virtual concatenation (VCAT) of SONET circuits and a software link capacity adjustment scheme (SW-LCAS). The ML-Series card supports a maximum of two VCAT groups with each group corresponding to one of the POS ports. Each VCAT group must be provisioned with two circuit members. An ML-Series card supports STS-1c-2v, STS-3c-2v and STS-12c-2v. |
1-6 and 12-17 with the XC10G or 5, 6, 12, and 13 with the XC or XCVT |
ML1000-2 |
The ML1000-2 card provides two ports of IEEE 802.3 compliant 1000-Mb/s interfaces. Each interface supports full-duplex operation for a maximum bandwidth of 2 Gbps per port and 4 Gbps per card. Each port auto configures for full duplex and IEEE 802.3z flow control. Each ML1000-2 card supports standards-based, Layer 2 Ethernet switching between its Ethernet ports and any other Ethernet or SONET trunk interfaces on the ONS 15454. The IEEE 802.1Q tag and port-based VLANS logically isolate traffic (typically subscribers). Priority queuing is also supported to provide multiple classes of service. Two queues are provided on card. Queue level is provisionable from 0 to 7. 0 to 3 map, and 4 to 7 map. The card features two virtual packet over SONET (POS) ports with a maximum combined bandwidth of STS-48. The ports function in a manner similar to OC-N card ports, and each port carries an STS circuit with a size of STS-1, STS-3c, STS-6c, STS-9c, STS-12c, or STS-24c. The ML-Series POS ports supports VCAT of SONET circuits and a software link capacity adjustment scheme (SW-LCAS). The ML-Series card supports a maximum of two VCAT groups with each group corresponding to one of the POS ports. Each VCAT group must be provisioned with two circuit members. An ML-Series card supports STS-1c-2v, STS-3c-2v and STS-12c-2v. The ML1000-2 card interfaces to Small Form Factor Pluggable (SFP) slots supporting SX and LS GBICs. |
1-6 and 12-17 with the XC10G or 5, 6, 12, and 13 with the XC or XCVT |
1 See http://cisco.com/en/US/products/hw/optical/ps2006/prod_eol_notices_list.html for the latest End-Of-Life and End-Of-Sale notices. |
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|---|---|---|
OSCM |
The OSCM has one set of optical ports and one Ethernet port located on the faceplate. An optical service channel (OSC) is a bidirectional channel connecting all the nodes in a ring. The channel transports OSC overhead that is used to manage ONS 15454 DWDM networks. The OSC uses the 1510 nm wavelength and does not affect client traffic. The primary purpose of this channel is to carry clock synchronization and orderwire channel communications for the DWDM network. It also provides transparent links between each node in the network. The OSC is an OC-3 formatted signal. The OSCM is used in amplified nodes that include the OPT-BST booster amplifier. The OPT-BST includes the required OSC wavelength combiner and separator component. The OSCM cannot be used in nodes where you use OC-N cards, electrical cards, or cross-connect cards. The OSCM supports the following features: • • • • • |
8 and 10 |
OSC-CSM |
The OSC-CSM has three sets of optical ports and one Ethernet port located on the faceplate. The OSC-CSM is identical to the OSCM, but also contains a combiner and separator module in addition to the OSC module. The OSC-CSM is used in unamplified nodes. This means that the booster amplifier with the OSC wavelength combiner and separator is not required for OSC-CSM operation. The OSC-CSM supports the following features: • • • • • • • • • |
1-6 and 12-17 |
OPT-PRE |
The OPT-PRE amplifier has five optical ports (three sets) located on the faceplate. The OPT-PRE is designed to support 64 channels at 50-GHz channel spacing, but Software R4.6 and R5.0 only supports 32 channels at 100 GHz. The OPT-PRE is a C-band DWDM, two-stage erbium-doped fiber amplifier (EDFA) with mid-amplifier loss (MAL) for allocation to a dispersion compensation unit (DCU). To control the gain tilt, the OPT-PRE is equipped with a built-in VOA. The VOA can also be used to pad the DCU to a reference value. The OPT-PRE features: • • • • • • • • • • • • |
1-6 and 12-17 |
OPT-BST |
The OPT-BST amplifier has four sets of optical ports located on the faceplate. The OPT-BST is designed to support 64 channels at 50-GHz channel spacing, but Software R4.6 supports 32 channels at 100 GHz. The OPT-BST is a C-band DWDM EDFA with OSC add-and-drop capability. When an ONS 15454 MSTP has an OPT-BST installed, it is only necessary to have the OSCM to process the OSC. To control the gain tilt, the OPT-BST is equipped with a built-in VOA. The OPT-BST features include: • • • • • • • • • • •
Note |
1-6 and 12-17 |
32MUX-O |
The 32MUX-O has five sets of ports located on the faceplate. The 32-channel multiplexer card (32 MUX-O) multiplexes 32 100 GHz-spaced channels identified in the channel plan. The 32MUX-O is typically used in hub nodes and provides the multiplexing of 32 channels, spaced at 100 GHz, into one fiber before their amplification and transmission along the line. The 32MUX-O features include: • • • • |
Two slots between Slots 1-5 and 12-16 |
32DMX-O |
The 32DMX-O has five sets of ports located on the faceplate. The 32-Channel Demultiplexer (32 DMX-O) card demultiplexes 32 100 GHz-spaced channels identified in the channel plan. The 32DMX-O features include: • • •
Note |
Two slots between Slots 1-5 and 12-16 |
32DMX |
The 32DMX has five sets of ports located on the faceplate. The 32-Channel Demultiplexer card (32DMX) is a single-slot optical demultiplexer. The card receives an aggregate optical signal on its COM RX port and demultiplexes it into to 32 100-GHz-spaced channels. The 32DMX card works in conjunction with the 32WSS card to create a software-controlled network element with ROADM functionality. ROADM functionality requires two 32DMX single-slot cards and two 32WSS double-slot cards (six slots in the ONS 15454 chassis). Equipped with ROADM functionality, ONS 15454 MSTP nodes can be configured at the optical channel level using CTC, Cisco MetroPlanner, and Cisco Transport Manager (CTM). Both the 32DMX card and 32WSS card utilize planar lightwave circuit (PLC) technology to perform wavelength-level processing. The 32DMX includes these high-level features: • • |
1-6 and 12-17 |
4MD-xx.x |
The 4MD-xx.x card has five sets of ports located on the faceplate. The 4-Channel Multiplexer/Demultiplexer (4MD-xx.x) card multiplexes and demultiplexes four 100 GHz-spaced channels identified in the channel plan. The 4MD-xx.x card is designed to be used with band OADMs (both AD-1B-xx.x and AD-4B-xx.x). There are eight versions of this card that correspond with the eight sub-bands specified in Table 4-17. The 4MD-xx.x has the following features implemented inside a plug-in optical module: • • • • |
1-6 and 12-17 |
AD-1C-xx.x |
The AD-1C-xx.x card has three sets of ports located on the faceplate. The 1-Channel OADM (AD-1C-xx.x) card passively adds or drops one of the 32 channels utilized within the 100 GHz-spacing of the DWDM card system. There are thirty-two versions of this card, each designed only for use with one wavelength. Each wavelength version of the card has a different part number. The AD-1C-xx.x has the following internal features: • • • • • |
1-6 and 12-17 |
AD-2C-xx.x |
The AD-2C-xx.x card has four sets of ports located on the faceplate. The 2-Channel OADM (AD-2C-xx.x) card passively adds or drops two adjacent 100 GHz channels within the same band. There are sixteen versions of this card, each designed for use with one pair of wavelengths. The card bidirectionally adds and drops in two different sections on the same card to manage signal flow in both directions. Each version of the card has a different part number. The AD-2C-xx.x cards are provisioned for the channel pairs in Table 4-18. In this table, channel IDs are given rather than wavelengths. The AD-2C-xx.x has the following features: • • • • • |
1-6 and 12-17 |
AD-4C-xx.x |
The AD-4C-xx.x card has six sets of ports located on the faceplate. The 4-Channel OADM (AD-4C-xx.x) card passively adds or drops all four 100 GHz-spaced channels within the same band. There are eight versions of this card, each designed for use with one band of wavelengths. The card bidirectionally adds and drops in two different sections on the same card to manage signal flow in both directions. There are eight versions of this card with eight part numbers. The AD-4C-xx.x cards are provisioned for the channel pairs in Table 4-19. The AD-4C-xx.x has the following features: • • • • • |
1-6 and 12-17 |
AD-1B-xx.x |
The AD-1B-xx.x card has three sets of ports located on the faceplate. The 1-Band OADM (AD-1B-xx.x) card passively adds or drops a single band of four adjacent 100 GHz-spaced channels. There are eight versions of this card with eight different part numbers, each version designed for use with one band of wavelengths. The card bidirectionally adds and drops in two different sections on the same card to manage signal flow in both directions. This card can be used when there is asymmetric adding and dropping on each side (east or west) of the node; a band can be added or dropped on one side but not on the other. The AD-1B-xx.x has the following features: • • • • • • |
1-6 and 12-17 |
AD-4B-xx.x |
The AD-4B-xx.x card has six sets of ports located on the faceplate. The 4-Band OADM (AD-4B-xx.x) card passively adds or drops four bands of four adjacent 100 GHz-spaced channels. There are two versions of this card with different part numbers, each version designed for use with one set of bands. The card bidirectionally adds and drops in two different sections on the same card to manage signal flow in both directions. This card can be used when there is asymmetric adding and dropping on each side (east or west) of the node; a band can be added or dropped on one side but not on the other. The AD-4B-xx.x cards are provisioned for the channel pairs in Table 4-20. The AD-4B-xx.x has the following features: • • • • • |
1-6 and 12-17 |
32WSS |
The 32WSS card has seven sets of ports located on the faceplate. The card takes up two slots and can operates in Slots 1-2, 3-4, 5-6, or in Slots 12-13, 14-15, or 16-17. The 32-Channel Wavelength Selective Switch (32WSS) card performs channel add/drop processing within the ONS 15454 DWDM node. The 32WSS works in conjunction with the 32DMX to implement ROADM functionality. Equipped with ROADM functionality, the ONS 15454 DWDM can be configured to add or drop individual optical channels using CTC, Cisco MetroPlanner, and CTM. A ROADM network element utilizes two 32WSS cards (two slots each) and two 32DMX cards (one slot each), for a total of six slots in the chassis. The 32WSS has six types of ports: • • • • • • |
1-2, 3-4, 5-6, and 12-13, 14-15, or 16-17 |
LED Indicators
TCC+, TCC2, and TCC2P Cards
The TCC+, TCC2, and TCC2P (TCC) cards have the following LED indicators on the faceplates.
Card-Level Indicators
•Red FAIL LED - This LED is lit during reset. The FAIL LED flashes during the boot and write process. Replace the card if the FAIL LED persists.
•ACT/STBY LED - The ACT/STBY (Active/Standby) LED indicates the TCC is in active mode when the LED is green, and in standby mode when it is yellow. The ACT/STBY LED also provides the timing reference and shelf control. When the active TCC is writing to its database to the standby TCC database, the card LEDs blink. To avoid memory corruption, do not remove the TCC when the active or standby LED is blinking.
Network-Level Indicators
•Red CRIT LED - Indicates critical alarms in the network at the local terminal.
•Red MAJ LED - Indicates major alarms in the network at the local terminal.
•Yellow MIN LED - Indicates a minor alarm in the network at the local terminal.
•Red REM LED - Provides first-level alarm isolation. The remote (REM) LED turns red when an alarm is present in one or several of the remote terminals.
•Green SYNC LED - Indicates that node timing is synchronized to an external reference.
•Green ACO LED - After pressing the alarm cutoff (ACO) button, the green ACO LED illuminates. The ACO button opens the audible alarm closure on the backplane. ACO state is stopped if a new alarm occurs. After the originating alarm is extinguished, the ACO LED and audible alarm control are reset.
XC, XCVT, and XC10G Cards
The XC, XCVT, and XC10G (cross-connect) cards have the following card-level LED indicators on the faceplates:
•Red FAIL LED - The red FAIL LED indicates that the card's processor is not ready. If the FAIL LED persists, replace the card.
•ACT/STBY LED - The ACT/STBY (Active/Standby) LED turns green when the XC card is active and carrying traffic and amber when it is in the standby mode as a protect card.
Electrical, Optical, and DWDM Cards
The electrical, optical, and DWDM cards have the following card-level LED indicators:
•Red FAIL LED - The red FAIL LED indicates that the card's processor is not ready. If the FAIL LED persists, replace the card.
•ACT/STBY LED - The ACT/STBY (Active/Standby) LED turns green when the card is active and carrying traffic and amber when it is in the standby mode as a protect card.
•Amber SF LED - The amber SF LED indicates a signal failure or condition such as port LOS, LOF, AIS, or high BERs. The amber SF LED also illuminates when the transmit and receive fibers are incorrectly connected. When the fibers are properly connected, the light turns off.
Port-level indicators include the following:
•Bicolor LEDs show the status per port. The LEDs shows green if the port is available to carry traffic, is provisioned as in-service, and is part of a protection group, in the active mode. You can also find the status of the ports using the LCD screen on the ONS 15454 fan-tray assembly. Use the LCD to quickly view the status of any port or card slot; the screen displays the number and severity of alarms for a given port or slot.
•The OSCM has three OC-3 optical ports located on the faceplate. One long-reach OSC transmits and receives the OSC to and from another DWDM node. Both data communications network (DCN) data and far-end (FE) payload are carried on this link. Two intermediate-reach OC-3 ports are used for DCN extension.
•The OSC-CSM has a UC port and three sets of ports located on the faceplate.
•The OPT-PRE amplifier has five optical ports located on the faceplate. MON is the output monitor port. COM Rx is the input signal port. COM Tx is the output signal port. DCC Rx is the MAL input signal port. DCC Tx is the MAL output signal port.
•The OPT-BST amplifier has eight optical ports located on the faceplate. MON Rx is the output monitor port (receive section). MON Tx is the output monitor port. COM Rx is the input signal port. LINE Tx is the output signal port. LINE Rx is the input signal port (receive section). COM Tx is the output signal port (receive section). OSC Rx is the OSC add input port. OSC Tx is the OSC drop output port.
•The 32MUX-O and 32DMX-O cards have five sets of ports located on the faceplate. COM Tx is the line output. MON is the optical monitoring port. The xx.x-yy.y Rx ports represent the four groups of 8 channels ranging from xx.x wavelength to yy.y wavelength according to the channel plan.
•The 32DMX card has five ports located on the faceplate. The port labeled COM RX is the line input (it typically receives DROP TX from the 32WSS module). The TX ports are 32 drop ports. The connectors provide four groups of eight channels ranging from xx.x wavelength to yy.y wavelength according to the channel plan.
•The 4MD-xx.x card has five sets of ports located on the faceplate. COM Rx is the line input. COM Tx is the line output. The 15xx.x Tx ports represent demultiplexed channel Outputs 1 to 4. The 15xx.x Rx ports represent multiplexed channel Inputs 1 to 4.
•The AD-1C-xx.x has six LC-PC-II optical ports: two for add/drop channel client input and output, two for express channel input and output, and two for communication.
•The AD-2C-xx.x card has eight LC-PC-II optical ports: four for add/drop channel client input and output, two for express channel input and output, and two for communication.
•The AD-4C-xx.x card has 12 LC-PC-II optical ports: eight for add/drop channel client input and output, two for express channel input and output, and two for communication.
•The AD-1B-xx.x has six LC-PC-II optical ports: two for add/drop channel client input and output, two for express channel input and output, and two for communication.
•The AD-4B-xx.x has 12 LC-PC-II optical ports: eight for add/drop band client input and output, two for express channel input and output, and two for communication.
•The 32WSS card has five sets of ports located on the faceplate. COM RX is the line input, COM TX is the line output, EXP RX is the port where a channel can be added or passed through, EXP TX is the port that passes through the channels that are not dropped, and DROP TX is the port for the dropped channels. The xx.x-yy.y TX ports represent the four groups of eight channels ranging from xx.x wavelength to yy.y wavelength according to the channel plan.
•Each FC_MR-4 port has a corresponding ACT/LNK LED. The ACT/LNK LED is solid green if the port is available to carry traffic, is provisioned as in-service, and in the active mode. The ACT/LNK LED is blinking green if the port is carrying traffic.
Ethernet Cards
The Ethernet cards have the following card-level LED indicators:
•Red FAIL LED - The red FAIL LED indicates the card's processor is not ready or a catastrophic software failure occurred on the Ethernet card. As part of the boot sequence, the FAIL LED is turned on, and it turns off when the software is deemed operational.
•ACT/STBY LED - ACT/STBY LED provides the operational status of the card. When the LED is green it indicates that the Ethernet card is active and the software is operational. The LED is amber when the card is in the standby mode.
Port-level Indicators include the following:
•LED Off - No link exists to the Ethernet port.
•Steady Amber LED - A link exists to the Ethernet port, but traffic flow is inhibited. For example, an unconfigured circuit, an error on line, or a non-enabled port may inhibit traffic flow.
•Solid Green LED - A link exists to the Ethernet port, but no traffic is carried on the port.
•Flashing Green LED - A link exists to the Ethernet port and traffic is being carried on the port. The LED flash rate reflects the traffic rate for the port.
Card Port and Connector Information
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|---|---|---|---|---|---|
DS1-14 |
14 |
GR-499-CORE |
1.544 Mb/s |
SMB with Balun adapter or AMP Champ |
Backplane EIA |
DS1N-14 |
14 |
GR-499-CORE |
1.544 Mb/s |
SMB with Balun or AMP Champ1 |
NA |
DS3-12 |
12 |
GR-499-CORE |
44.736 Mb/s |
SMB or BNC1 |
Backplane EIA |
DS3N-12 |
12 |
GR-499-CORE |
44.736 Mb/s |
SMB or BNC1 |
NA |
DS3-12E |
12 |
GR-499-CORE |
44.736 Mb/s |
SMB or BNC1 |
Backplane EIA |
DS3N-12E |
12 |
GR-499-CORE |
44.736 Mb/s |
SMB or BNC1 |
Backplane EIA |
DS3/EC1-48 |
48 |
GR-499-CORE |
44.736 Mb/s |
SMB or BNC1 |
Backplane EIA |
DS3XM-6 |
6 |
GR-499-CORE M13 |
44.736 Mb/s |
SMB or BNC1 |
Backplane EIA |
DS3XM-12 |
12 |
GR-499-CORE M13 |
44.736 Mb/s |
SMB or BNC1 |
Backplane EIA |
EC1-12 |
12 |
GR-253-CORE |
51.84 Mb/s |
SMB or BNC1 |
Backplane EIA |
OC3-4/STM1 (All) |
4 |
GR-253-CORE |
155.52 Mb/s |
SC |
Faceplate |
OC3-8/STM1 |
8 |
GR-253-CORE |
155.52 Mb/s |
LC |
Faceplate |
OC12/STM4 |
1 |
GR-253-CORE |
622.08 Mb/s |
SC |
Faceplate |
OC12-4/STM4 |
4 |
GR-253-CORE |
622.08 Mb/s |
SC |
Faceplate |
OC48/STM16 (All versions) |
1 |
GR-253-CORE |
2488.32 Mb/s |
SC |
Faceplate |
OC48/STM16-AS |
1 |
GR-253-CORE |
2488.32 Mb/s |
SC |
Faceplate |
OC48/STM16-ITU (100 GHz & 200 GHz) |
1 |
GR-253-CORE ITU-T G.692 ITU-T G.958 |
2488.32 Mb/s |
SC |
Faceplate |
OC-192/STM642 (All versions) |
1 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
SC |
Faceplate |
OC-192/STM64- ITU2 (100 GHz) |
1 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
SC |
Faceplate |
MXP-2.5-10G2 |
4-Client 1-Trunk |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
Client: SFP Trunk: LC |
Faceplate |
MXP_2.5G_10E2 |
4-Client 1-Trunk |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
Client: SFP Trunk: LC |
Faceplate |
TXP-MR-10G2 |
1-Client 1-Trunk |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC |
Faceplate |
TXP-MR-10E2 |
1-Client 1-Trunk |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC |
Faceplate |
TXP_MR_2.5G |
1-Client 1-Trunk |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
2.488 Gb/s |
Client: SFP Trunk: LC |
Faceplate |
TXPP_MR_2.5G |
1-Client 2-Trunk |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
2.488 Gb/s |
Client: SFP Trunk: LC |
Faceplate |
FC_MR-4 |
4 |
GR-253-CORE ITU-T G.957 |
1.0625- or 2.125-Gb/s |
GBIC-SC |
Faceplate |
E100T-12 |
12 |
IEEE 802.3 |
100 Mb/s |
RJ-45 |
Faceplate |
E1000-2 |
2 |
IEEE 802.3 |
1000 Mb/s |
GBIC-SC |
Faceplate |
E100T-G |
12 |
IEEE 802.3 |
100 Mb/s |
RJ-45 |
Faceplate |
E1000-2-G |
2 |
IEEE 802.3 |
1000 Mb/s |
GBIC-SC |
Faceplate |
G1000-4 |
4 |
IEEE 802.3 |
1000 Mb/s |
GBIC-SC |
Faceplate |
G1K-4 |
4 |
IEEE 802.3 |
1000 Mb/s |
GBIC-SC |
Faceplate |
ML100T-12 |
12 |
IEEE 802.3 |
100 Mb/s |
RJ-45 |
Faceplate |
ML1000-2 |
2 |
IEEE 802.3 |
1000 Mb/s |
LC-SFP |
Faceplate |
OSCM |
2 |
GR-253-CORE ITU-T G.957 |
155.52 Mb/s |
LC |
Faceplate |
OSC-CSM |
4 |
GR-253-CORE ITU-T G.957 |
UDC: FE Optical: 155.52 Mb/s |
UDC: RJ45 Optical: LC |
Faceplate |
OPT-PRE |
5 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
OPT-BST |
4 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
32MUX-O |
5 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
32DMX-O |
5 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
32DMX |
5 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
4MD-xx.x |
5 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
AD-1C-xx.x |
3 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
AD-2C-xx.x |
4 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
AD-4C-xx.x |
6 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
AD-1B-xx.x |
3 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
AD-4B-xx.x |
6 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
32WSS |
7 |
GR-253-CORE ITU-T G.707 ITU-T G.957 |
9.95328 Gb/s |
LC-UPC/2 |
Faceplate |
1 When used as a protect card, the card does not have a physical external connection. The protect card connects to the working card(s) through the backplane and becomes active when the working card fails. The protect card then uses the physical connection of the failed card. 2 Warning: Class 1 (21 CFR 1040.10 and 1040.11) and Class 1M (IEC 60825-1 2001-01) laser products. Invisible laser radiation may be emitted from the end of the unterminated fiber cable or connector. Do not stare into the beam or view directly with optical instruments. Viewing the laser output with certain optical instruments (for example, eye loupes, magnifiers, and microscopes) within a distance of 100 mm may pose an eye hazard. Use of controls or adjustments, or performance of procedures other than those specified may result in hazardous radiation exposure. |
Card Compatibility
The following tables list the software release and common card compatibility for each plug-in card. Table cells with dashes (—) mean cards are not compatible with the listed software release or cross-connect card.
See http://cisco.com/en/US/products/hw/optical/ps2006/prod_eol_notices_list.html for the latest list of End-Of-Life and End-Of-Sale notices.
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|---|---|---|---|---|---|---|---|---|---|---|---|---|
TCC+ |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes |
Yes |
Yes |
TCC2 |
— |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
TCC2P |
— |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
XC |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes |
Yes |
— |
XCVT |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes |
Yes |
— |
XC10G1 |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes |
AIC |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
AIC-I |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
AEP |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
1 The XC10G card requires a TCC+/TCC2/TCC2P card, Software R3.1 or later, and the 15454-SA-ANSI or 15454-SA-HD shelf assemblies to operate. |
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OC3-IR-4/STM1-SH-1310 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OC-3-IR-8/STM1-SH-1310 |
- |
- |
- |
- |
- |
Yes |
Yes |
Yes |
Yes |
- |
- |
Yes in slots 1-4 and 14-17 |
OC12-IR/STM4-SH-1310 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OC12-LR/STM4-LH-1310 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OC12-LR/STM4-LH-1550 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OC12-IR-4/STM4-SH-1310 |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes in slots 1-4 and 14-17 |
OC48-IR-1310 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OC48-LR-1550 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OC48-IR/STM16-SH-AS-1310 |
— |
Yes1 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes, in slots 5, 6, 12, and 13 |
Yes, in slots 5, 6, 12, and 13 |
Yes1 |
OC48-LR/STM16-LH-AS-1550 |
— |
Yes1 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes, in slots 5, 6, 12, and 13 |
Yes, in slots 5, 6, 12, and 13 |
Yes1 |
OC48-ELR/STM16-EH-100GHz |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OC48-ELR-200GHz |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OC192-SR/STM64-IO-1310 |
— |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes1 |
OC192-IR/STM64-SH-1550 |
— |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes1 |
OC192-LR/STM64-LH-1550 |
— |
Yes1 |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes1 |
OC192-LR/STM64-LH-ITU |
— |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
— |
— |
Yes1 |
1 The XC10G card requires a TCC+/TCC2/TCC2P card, Software R3.1 or later, and the 15454-SA-ANSI or 15454-SA-HD shelf assemblies to operate. |
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|---|---|---|---|---|---|---|---|---|---|---|---|---|
CE-100T-8 |
— |
— |
— |
— |
— |
— |
— |
— |
Yes |
— |
— |
Yes |
E100T-12 |
Yes |
Yes |
Yes |
yes |
Yes |
Yes |
Yes |
Yes |
Yes |
— |
Yes |
— |
E1000-2 |
Yes |
Yes |
Yes |
yes |
Yes |
Yes |
Yes |
Yes |
Yes |
— |
Yes |
— |
E100T-G |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes1 |
E1000-2-G |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes1 |
G1000-4 |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes1 |
G1K-4 |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
ML100T-12 |
— |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes, in slots 5, 6, 12, and 13 |
Yes, in slots 5, 6, 12, and 13 |
Yes |
ML1000-2 |
— |
— |
— |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes, in slots 5, 6, 12, and 13 |
Yes, in slots 5, 6, 12, and 13 |
Yes |
1 To use Ethernet cards with the XC10G card, select either the E100T-G, E1000-2-G, G1000-4, or G1K4 card. Do not use the E100T-12 card or E1000-2 card with the XC10G. |
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|---|---|---|---|---|---|
FC_MR-4 |
Yes |
Yes |
Yes, in slots 5, 6, 12, and 13 |
Yes, in slots 5, 6, 12, and 13 |
Yes |
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|---|---|---|---|---|---|---|---|---|
TXP_MR-10G |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
TXP_MR_10E |
- |
- |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
TXP_MR_2.5G |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
TXPP_MR_2.5G |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
MXP_2.5_10G |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
MXP_2.5_10E |
- |
- |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
MXP_MR_2.5G |
- |
- |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
MXPP_MR_2.5G |
- |
- |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
1 XC10G cannot be used with Release 4.5, but is supported in Release 4.6 and higher for hybrid MSTP/MSPP configurations. |
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|---|---|---|---|---|---|---|---|---|
OSCM |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OSC-CSM |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OPT-PRE |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
OPT-BST |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
32MUX-O |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
32DMX-O |
Yes |
Yes |
Yes |
yes |
Yes |
Yes |
Yes |
Yes |
32DMX |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
4MD-xx.x |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
AD-1C-xx.x |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
AD-2C-xx.x |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
AD-4C-xx.x |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
AD-1B-xx.x |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
AD-4B-xx.x |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
32WSS |
— |
— |
Yes |
Yes |
Yes |
Yes |
Yes |
Yes |
1 XC10G cannot be used with Release 4.5, but is supported in Release 4.6 and higher for hybrid MSTP/MSPP configurations. |
GBIC and SFP Connectors
The ONS 15454 Ethernet cards use industry standard small form-factor pluggable connectors (SFPs) and Gigabit Interface Converter (GBIC) modular receptacles. The ML-Series Gigabit Ethernet cards use standard Cisco SFPs. The Gigabit E-Series card and the G-Series card use standard Cisco GBICs. With Software Release 4.1 and higher, G-Series cards can also be equipped with dense wavelength division multiplexing (DWDM) and coarse wavelength division multiplexing (CWDM) GBICs to function as Gigabit Ethernet transponders.
For all Ethernet cards, the type of GBIC or SFP plugged into the card is displayed in CTC and TL1. Cisco offers SFPs and GBICs as separate orderable products.
GBIC and SFP Card Compatibility
Only use GBICs and SFPs certified for use in Cisco Optical Networking Systems. The qualified Cisco GBIC and SFP pluggable module's top assembly numbers (TANs) are provided in Table 6-50.
The technical specifications for Cisco's GBICs and SFPs are listed in Table 6-26.
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General: |
|||||
Connector |
SC |
SC |
SC |
SFP |
SFP |
Wavelength |
850 nm |
1300 nm |
1550 nm |
850 nm |
1300 nm |
Minimum Cable Distance1 |
2 m |
2 m |
2 m |
2 m |
2 m |
Maximum Cable Distance |
1,804 ft (550 m) |
32,810 ft. (10 km) |
262,480 ft. (80 km) |
1,804 ft (550 m) |
32,810 ft. (10 km) |
Port Cabling |
|||||
Wavelength |
850 nm |
1300 nm |
1550 nm |
850 nm |
1300 nm |
Fiber Type |
MMF |
SMF |
SMF |
MMF |
SMF |
Core Size (microns) |
62.5 |
62.5 |
Not Conditional |
62.5 |
62.5 |
Modal Bandwidth |
160 MHz/km |
500 MHz/km |
NA |
160 MHz/km |
500 MHz/km |
Maximum Distance |
220 m |
550 m |
80 km |
220 m |
550 m |
Fiber Loss Budgets: |
|||||
Transmit Minimum |
-9.5 dBm |
-11 dBm |
0 dBm |
-9.5 dBm |
-11 dBm |
Transmit Maximum |
-4 dBm |
-3 dBm |
4.77 dBm |
-4 dBm |
-3 dBm |
Receive Minimum |
-17 dBm |
-19 dBm |
-24 dBm |
-17 dBm |
-19 dBm |
Receive Maximum |
0 dBm |
-3 dBm |
-1 dBm |
0 dBm |
-3 dBm |
Operating Temperature |
-5 to +55 degrees Celsius (+23 to +131 degrees Fahrenheit) |
-5 to +55 degrees Celsius (+23 to +131 degrees Fahrenheit) |
-5 to +55 degrees Celsius (+23 to +131 degrees Fahrenheit) |
• • • |
• • • |
Dimensions: |
|||||
Height |
0.39 in. |
0.39 in. |
0.39 in. |
0.03 in. |
0.03 in. |
Width |
1.18 in. |
1.18 in. |
1.18 in. |
0.53 in. |
0.53 in. |
Depth |
2.56 in. |
2.56 in. |
2.56 in. |
2.22 in. |
2.22 in. |
IEEE Compliant |
Yes |
Yes |
Yes |
Yes |
Yes |
1 When using an LX SFP or LX GBIC with multimode fiber, you must install a mode-conditioning patch cord between the SFP/GBIC and the multimode fiber cable on both the transmit and receive ends of the link. The mode-conditioning patch cord is required for link distances less than 100 m (328 feet) or greater than 300 m (984 feet). The mode-conditioning patch cord prevents overdriving the receiver for short lengths of multimode fiber and reduces differential mode delay for long lengths of multimode fiber. |
DWDM and CWDM GBICs
DWDM (15454-GBIC-xx.x, 15454E-GBIC-xx.x) and CWDM (15454-GBIC-xxxx, 15454E-GBIC-xxxx) GBICs operate in the ONS 15454 G-Series card when the card is configured in Gigabit Ethernet Transponding mode or in Ethernet over SONET mode. DWDM and CWDM GBICs are both wavelength division multiplexing (WDM) technologies and operate over single-mode fibers with SC connectors. Cisco CWDM GBIC technology uses a 20 nm wavelength grid and Cisco ONS 15454 DWDM GBIC technology uses a 1 nm wavelength grid. CTC displays the specific wavelengths of the installed CWDM or DWDM GBICs. DWDM wavelengths are spaced closer together and require more precise lasers than CWDM. The DWDM spectrum allows for optical signal amplification.
The DWDM and CWDM GBICs receive across the full 1300 nm and 1500 nm bands, which includes all CWDM, DWDM, LX/LH, ZX wavelengths, but transmit on one specified wavelength. This capability can be exploited in some of the G-Series transponding modes by receiving wavelengths that do not match the specific transmission wavelength.
G1000-4 cards support CWDM and DWDM GBICs. G1K-4 cards with the Common Language Equipment Identification (CLEI) code of WM5IRWPCAA (manufactured after August 2003) support CWDM and DWDM GBICs. G1K-4 cards manufactured prior to August 2003 do not support CWDM or DWDM GBICs.
The ONS 15454-supported CWDM GBICs reach support eight wavelengths as shown in Table 6-27.
The ONS 15454 supports 32 different DWDM GBICs in the red and blue bands and can be paired with optical amplifiers, such as the Erbium-Doped Fiber Amplifier (EDFA). Operating temperature range for DWDM GBICs is from -5 to +40 degrees Celsius.
Network Element Defaults and Performance Monitoring Thresholds
The following tables lists the network element (NE) default settings for the ONS 15454 and threshold ranges for monitored parameters. These tables include card and node default settings from the factory. Cards not listed in these tables are not supported by NE defaults. The factory [default] settings are in brackets. For a description of defaults and performance monitoring (PM) parameters, see the Cisco ONS 15454 Reference Manual.
You can disable any monitored threshold by setting its value to zero. To change card settings individually (that is, without changing the NE defaults), refer to the Change Card Settings chapter of the Cisco ONS 15454 Procedure Guide. To change node settings, refer to the Change Node Settings chapter of the Cisco ONS 15454 Procedure Guide.
•Refer Table 6-29 for CTC defaults
•Refer Table 6-30 for Node defaults
•Refer Table 6-31 for DS1-14 defaults
•Refer Table 6-32 for DS3-12/DS3-12E defaults
•Refer Table 6-33 for DS3/EC1-48 defaults
•Refer Table 6-34 for DS3XM-6 defaults
•Refer Table 6-35 for DS3XM-12 defaults
•Refer Table 6-36 for EC1-12 defaults
•Refer Table 6-37 for OC3-4/OC3-8 defaults
•Refer Table 6-38 for OC12/OC12-4 defaults
•Refer Table 6-39 for OC48 defaults
•Refer Table 6-40 for OC-192 defaults
•Refer Table 6-41 for OSC-CSM defaults
•Refer Table 6-42 for OSCM defaults
•Refer Table 6-43 for MXP_2.5G_10G defaults
•Refer Table 6-44 for MXP_2.5G_10E defaults
•Refer Table 6-45 for MXP_MR_2.5G/MXPP_MR_2.5G defaults
•Refer Table 6-46 for TXP_MR_10G defaults
•Refer Table 6-47 for TXP_MR_10E defaults
•Refer Table 6-48 for TXP_MR_2.5G/TXPP_MR_2.5G defaults
•Refer Table 6-49 for FC_MR-4 defaults
•Refer Table 6-50 for CE-100T-8 defaults
•Refer Table 6-51 for G1000-4/G1K4 defaults
•Refer Table 6-52 for ML100T-12 defaults
•Refer Table 6-53 for ML1000-2 defaults
See http://cisco.com/en/US/products/hw/optical/ps2006/prod_eol_notices_list.html for the latest list of End-Of-Life and End-Of-Sale notices.
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Configuration |
AINS Soak Time (hrs:min) |
00:00 - 48:00 [08:00] |
State |
IS; OOS,DSLBD; OOS,MT [OOS,DSLBD] |
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|---|---|---|
Configuration |
Card Mode |
HDLC, GFP-F [HDLC] |
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|---|---|---|
Configuration |
Card Mode |
HDLC, GFP-F [HDLC] |
Remote Monitoring Specification Alarm Thresholds
The ONS 15454 supports remote monitoring (RMON) Management Information Base (MIB) objects specified in RFC 2819 [1], RFC 2358, and RFC 2233. RMON MIBs are intended to interface with a network management system (NMS) to monitor the health of the ONS 15454 network.
One of the ONS 15454 RMON MIBs is the Alarm group, which consists of the alarmTable. An NMS uses the alarmTable to find the alarm-causing thresholds for network performance. The thresholds apply to the current 15-minute interval and the current 24-hour interval. RMON monitors several variables, such as Ethernet collisions, and triggers an event when the variable crosses a threshold during that time interval. For example, if a threshold is set at 1000 collisions and 1001 collisions occur during the 15-minute interval, an event triggers. CTC allows you to provision these thresholds for Ethernet statistics.
Release 5.0 adds enhancements to the SNMP agent on the ONS 15454 MSPP to supplement existing RMON support. This enhancement includes support for the High Capacity RMON (HC-RMON) MIB. HC-RMON-MIB is an extension of RMON. RMON counters are 32-bit while HC-RMON counters are 32-bit and 64-bit as defined in the MIB. Release 5.0 supports the following HC-RMON tables:
•mediaIndependentTable
•etherStatsHighCapacityTable
•etherHistoryHighCapacityTable
Table 6-54 defines the RMON MIB variables you can provision in CTC. For example, to set the collision threshold, choose etherStatsCollisions from the Variable menu.
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