The documentation set for this product strives to use bias-free language. For the purposes of this documentation set, bias-free is defined as language that does not imply discrimination based on age, disability, gender, racial identity, ethnic identity, sexual orientation, socioeconomic status, and intersectionality. Exceptions may be present in the documentation due to language that is hardcoded in the user interfaces of the product software, language used based on RFP documentation, or language that is used by a referenced third-party product. Learn more about how Cisco is using Inclusive Language.
The cables used to interconnect the CRS Back-to-Back System chassis are optical array cables called fabric cables. This chapter describes how to physically cable the fabric planes between line card chassis (LCCs) in a CRS Back-to-Back System. This chapter is organized into the following sections:
Each CRS Back-to-Back System requires 24 fabric cables. This cabling enables interchassis data communication, which is accomplished using fiber-optic bundles.
The CRS Back-to-Back System uses a customized cable/connector that visually looks the same as the multichassis cable/connector with a different PIN layout. The way to distinguish the fabric cables for the CRS Back-to-Back System is a label that says Back-to-Back.
This section describes the following topics:
The CRS Back-to-Back System has eight fabric planes that support data traffic between the lines connected to the LCCs. The below figure shows a simplified view of the relationship between the line cards and the fabric.
In general, CRS fabric planes are divided into three components or stages, which are numbered S1, S2, and S3. Data arrives at the S1 stage then goes through the S2 stage and exits at the S3 stage to the destination line card. This figure shows a simplified view of the relationship between the line cards and the fabric planes in a general CRS system.
However, in a CRS Back-to-Back System, fabric planes are divided into two stages: S1 and S3. The S2 stage is no longer needed. The purpose of the S2 stage is to direct traffic to the correct egress LCC when there are multiple egress LCCs. In the CRS Back-to-Back System, there is only one egress LCC.
Data arrives at the S1 stage in the ingress LCC and then passes over the fabric cables to the S3 stage in the egress LCC. This figure shows a simplified view of the relationship between the line cards and the fabric planes in a CRS Back-to-Back System.
Note | Refer to Figure 1 for physical cabling examples. |
In each LCC, eight S13 fabric cards provide stages S1 and S3 for each of the eight fabric planes. All ingress traffic enters through the S1 stage of the ingress S13 card, travels over the fabric cables and exits through the S3 stage on an S13 fabric card. Data traffic can enter through the S1 stage on one card and then exit the S3 stage on the same card.
This figure shows the location of the S13 fabric cards in each LCC and how the connectors are labeled on those cards.
Note the following:
Table 1 lists the product ID numbers for Cisco CRS fabric cables. The cables listed in Table 1 can be ordered. The interconnection cables listed are shipped as a set of 24 in the meter length specified. Evaluate your installation for the appropriate length of fabric cable needed before ordering. You should try to avoid long runs of coiled cables.
In Table 1, the cable name CRS-B2B-CAB-XX means the following:
Note | The = symbol at the end of a product ID number indicates that the part is a spare , which means that the cable can be ordered as a spare.The R symbol at the end of a product ID number indicates that the part is a Riser cable. |
Fabric Cable Product ID |
Description and Length |
---|---|
CRS-B2B-CAB-10 |
Cisco CRS Back-to-Back Optical Cable 10 meters (32.8 feet) |
CRS-B2B-CAB-10= |
|
CRS-B2B-CAB-10R |
Cisco CRS Back-to-Back Optical Cable Riser 10 meters (32.8 feet) |
CRS-B2B-CAB-10R= |
|
CRS-B2B-CAB-15 |
Cisco CRS Back-to-Back Optical Cable 15 meters (49.2 feet) |
CRS-B2B-CAB-15= |
|
CRS-B2B-CAB-15R |
Cisco CRS Back-to-Back Optical Cable Riser 15 meters (49.2 feet) |
CRS-B2B-CAB-15R= |
|
CRS-B2B-CAB-20 |
Cisco CRS Back-to-Back Optical Cable 20 meters (65.6 feet) |
CRS-B2B-CAB-20= |
|
CRS-B2B-CAB-20R |
Cisco CRS Back-to-Back Optical Cable Riser 20 meters (65.6) |
CRS-B2B-CAB-20R= |
|
CRS-B2B-CAB-25 |
Cisco CRS Back-to-Back Optical Cable 25 meters (82 feet) |
CRS-B2B-CAB-25= |
|
CRS-B2B-CAB-25R |
Cisco CRS Line Card Chassis-Fabric Chassis Riser 25 meters (82 feet) |
CRS-B2B-CAB-25R= |
|
CRS-B2B-CAB-30 |
Cisco CRS Back-to-Back Optical Cable 30 meters (98.43) |
CRS-B2B-CAB-30= |
|
CRS-B2B-CAB-30R |
Cisco CRS Back-to-Back Optical Cable Riser 30 meters (98.43 feet) |
CRS-B2B-CAB-30R= |
|
CRS-B2B-CAB-40 |
Cisco CRS Back-to-Back Optical Cable 40 meters (131.2 feet) |
CRS-B2B-CAB-40= |
|
CRS-B2B-CAB-40R |
Cisco CRS Back-to-Back Optical Cable Riser 40 meters (131.2 feet) |
CRS-B2B-CAB-40R= |
|
CRS-B2B-CAB-50 |
Cisco CRS Back-to-Back Optical Cable 50 meters (164 feet) |
CRS-B2B-CAB-50= |
|
CRS-B2B-CAB-50R |
Cisco CRS Back-to-Back Optical Cable Riser 50 meters (164 feet) |
CRS-B2B-CAB-50R= |
|
CRS-B2B-CAB-60 |
Cisco CRS Back-to-Back Optical Cable 60 meters (197 feet) |
CRS-B2B-CAB-60= |
|
CRS-B2B-CAB-60R |
Cisco CRS Back-to-Back Optical Cable Riser 60 meters (197 feet) |
CRS-B2B-CAB-60R= |
|
CRS-B2B-CAB-70 |
Cisco CRS Back-to-Back Optical Cable 70 meters (229.7) |
CRS-B2B-CAB-70= |
|
CRS-B2B-CAB-70R |
Cisco CRS Back-to-Back Optical Cable Riser 70 meters (229.7) |
CRS-B2B-CAB-70R= |
|
CRS-B2B-CAB-80 |
Cisco CRS Back-to-Back Optical Cable 80 meters (262.5 feet) |
CRS-B2B-CAB-80= |
|
CRS-B2B-CAB-80R |
Cisco CRS Back-to-Back Optical Cable Riser 80 meters (262.5 feet) |
CRS-B2B-CAB-80R= |
|
CRS-B2B-CAB-90 |
Cisco CRS Back-to-Back Optical Cable 90 meters (295.3feet) |
CRS-B2B-CAB-90= |
|
CRS-B2B-CAB-90R |
Cisco CRS Back-to-Back Optical Cable Riser 90 meters (295.3 feet) |
CRS-B2B-CAB-90R= |
|
CRS-B2B-CAB-100 |
Cisco CRS Back-to-Back Optical Cable 100 meters (328 feet) |
CRS-B2B-CAB-100= |
|
CRS-B2B-CAB-100R |
Cisco CRS Back-to-Back Optical Cable Riser 100 meters (328 feet) |
CRS-B2B-CAB-100R= |
Planning the fabric cabling involves the following components:
When planning your cable runs, it is convenient when cables are planned, labeled, and hung from overhead cable troughs so that the end of the cable is almost touching the floor. Allow more or less slack as cables are connected.
Before you begin cabling, develop a cabling plan for your CRS Back-to-Back System. The example in the below figure routes cables upward to a monorail system and conforms to the following guidelines:
In the top shelf of the line card chassis, cables are routed downward, toward the side of the chassis, then up and out of the vertical troughs.
In the bottom shelf of the line card chassis, cables are routed upward, toward the side of the chassis, then up and out of the vertical troughs.
When preparing to cable the CRS Back-to-Back System, consider the following information:
These two figures provide a close up view of the cables attached to the fabric card.
Label cables as you unpack them. With a felt-tip pen, mark cables as 1, 2, 3 , and so on. Create a consistent labeling scheme. This section suggests a labeling scheme.
Use a label size that works best at your installation. Each label should contain the from and to port location at which either end of the cable is attached. For example, a label could contain the following information:
From:
LCC #
Slot #/Port #
To:
LCC #
Slot #/Port #
where:
We suggest that you use a labeling schema, for example, with an Excel spreadsheet. The sample label schema shown in the below table uses the following convention: LCC_number /slot_number /port_number . Note the following:
Plane |
LCC0 Label |
LCC1 Label |
---|---|---|
0 |
0/SM0/A0 |
1/SM0/A0 |
0/SM0/A1 |
1/SM0/A1 |
|
0/SM0/A2 |
1/SM0/A2 |
|
1 |
0/SM1/A0 |
1/SM1/A0 |
0/SM1/A1 |
1/SM1/A1 |
|
0/SM1/A2 |
1/SM1/A2 |
|
2 |
0/SM2/A0 |
1/SM2/A0 |
0/SM2/A1 |
1/SM2/A1 |
|
0/SM2/A2 |
1/SM2/A2 |
|
3 |
0/SM3/A0 |
1/SM3/A0 |
0/SM3/A1 |
1/SM3/A1 |
|
0/SM3/A2 |
1/SM3/A2 |
|
4 |
0/SM4/A0 |
1/SM4/A0 |
0/SM4/A1 |
1/SM4/A1 |
|
0/SM4/A2 |
1/SM4/A2 |
|
5 |
0/SM5/A0 |
1/SM5/A0 |
0/SM5/A1 |
1/SM5/A1 |
|
0/SM5/A2 |
1/SM5/A2 |
|
6 |
0/SM6/A0 |
1/SM6/A0 |
0/SM6/A1 |
1/SM6/A1 |
|
0/SM6/A2 |
1/SM6/A2 |
|
7 |
0/SM7/A0 |
1/SM7/A0 |
0/SM7/A1 |
1/SM7/A1 |
|
0/SM7/A2 |
1/SM7/A2 |
Please observe all precautions listed in the General Safety Guidelines when you perform any procedure in this chapter. The following precautions are additional reminders before you begin cabling the CRS Back-to-Back System.
Warning | Because invisible radiation may be emitted from the aperture of the port when no fiber cable is connected, avoid exposure to radiation and do not stare into open apertures. Statement 125 |
Warning | During this procedure, wear grounding wrist straps to avoid ESD damage to the card. Do not directly touch the backplane with your hand or any metal tool, or you could shock yourself. Statement 94 |
Warning | Before working on equipment that is connected to power lines, remove jewelry (including rings, necklaces, and watches). Metal objects will heat up when connected to power and ground and can cause serious burns or weld the metal object to the terminals. Statement 43 |
If a chassis power is on, assume lasers are turned on.
Never look at the ends of the fiber cables unless you are certain the laser is powered off.
The S13 card is Class 1M. Other optical cards are Class 1.
Warning | For diverging beams, viewing the laser output with certain optical instruments within a distance of 100 MM. may pose an eye hazard. For collimated beams, viewing the laser output with certain optical instruments designed for use at a distance may pose an eye hazard. Statement 282 |
Warning | Laser radiation. Do not view directly with optical instruments. Class 1M laser product. Statement 283 |
Caution | Handle cables carefully, as described in Introduction to the CRS Back-to-Back System |
Caution | Cleanliness is critical to proper switch operation. To keep connections clean, do not remove the yellow dust cover from a port until you are ready to attach a cable. Do not remove the silver dust cover from a fabric cable until you are ready to attach the cable to the fabric card connector. Silver dust covers should be screwed on for security. Loosen the screws to remove the dust cover (see the figure below). Store dust covers in a dust-free location. |
Cable connection procedures assume that all LCCs and their cards are installed in accordance with site planning guidelines and that appropriate interconnection cable lengths are ordered and ready to be connected.
Caution | All ports should have yellow dust covers on them as you begin this procedure, as shown in Figure 4. |
The fabric cables are shipped separately from the fabric card chassis. These cables are shipped on a reel, similar to as shown in the below figure. This procedure begins with the assumption that the fabric cables have been unpacked and positioned or hung near the chassis to which they will be connected. Packaging for Riser cables may differ from the below figure.
You will be attaching 24 fabric cables for each LCC. Ensure that each cable is labeled at both ends and then run each cable between the two LCCs.
The steps to take while attaching each cable to the LCC follow:
Step 1 | Slide the turn collar support on in the direction shown below:Upper shelf - all turn collars go down. Lower shelf - all turn collars go up. |
Step 2 | Gently position the connector in the correct orientation (fabric card connectors and fabric cable connectors are keyed). |
Step 3 | Hand-tighten the thumbscrews on the connector. |
Step 4 | Repeat Steps 1 through 3 to each cable. |
Step 5 | Fully tighten every connection. |
Step 6 | Gently drape and group cables behind the fabric card. Use Velcro straps to tie the growing bundles together. |
Step 7 | Bundle the cables together and velcro them to the horizontal cable manager and the vertical trough. |
The following are general fabric cabling procedures you might want to use when installing or maintaining the fabric cabling:
The turn collar protects the fabric cable bend radius and functions as a strain-relief support. It also has a Velcro strap attached to it to bundle the cables as the cables are installed.
Here are notes to help you install a turn collar:
To install a turn collar:
1
Turn collar
2
Velcro strap (to keep the fabric cable inside the turn collar and bundle fabric cables)
For information about cleaning fiber-optic cables, see Cisco CRS-1 Optical Cleaning Guide.
This section describes, in table form, the processes for executing the commands required to verify the fabric. All commands in this mode will be run from admin mode.
Step 1 |
Execute the command: show platform. The command will have output similar to below. Note that there are 24 fabric cables (SM0-23) and all are in IOS XR RUN state. Also note the 8 LCC fabric cards. Example: RP/0/RP0/CPU0:b2b(admin)#show platform | i SM 0/SM0/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 0/SM1/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 0/SM2/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 0/SM3/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 0/SM4/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 0/SM5/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 0/SM7/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 1/SM0/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 1/SM1/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 1/SM2/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 1/SM3/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 1/SM4/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 1/SM5/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON 1/SM7/SP CRS-16-FC-140/M(SP) N/A IOS XR RUN PWR,NSHUT,MON RP/0/RP0/CPU0:b2b(admin)# |
Step 2 |
Execute the command: show controllers fabric plane all detail. All planes should be UP/UP and the amount of downed bundles should be 21 on each plane. If there are more than 21 downed bundles, it means that at least one of the array cables is loose or not connected properly. Example: Flags: P - plane admin down, p - plane oper down C - card admin down, c - card oper down L - link port admin down, l - linkport oper down A - asic admin down, a - asic oper down B - bundle port admin Down, b - bundle port oper down I - bundle admin down, i - bundle oper down N - node admin down, n - node down o - other end of link down d - data down f - failed component downstream m - plane multicast down Plane Admin Oper Down Total Down Id State State Flags Bundles Bundles ------------------------------------------------------ 0 UP UP 27 21 1 UP UP 27 21 2 UP UP 27 21 3 UP UP 27 21 4 UP UP 27 21 5 UP UP 27 21 6 UP UP 27 21 7 UP UP 27 21 |
Step 3 |
Execute the command: show controllers fabric connectivity all detail. Each one of your line cards will be represented in the output. Verify that there is connectivity to all 8 planes. This will be represented by 8 1’s, like below.
Flags: P - plane admin down, p - plane oper down C - card admin down, c - card oper down L - link port admin down, l - linkport oper down A - asic admin down, a - asic oper down B - bundle port admin Down, b - bundle port oper down Example: I - bundle admin down, i - bundle oper down N - node admin down, n - node down o - other end of link down d - data down f - failed component downstream m - plane multicast down Card In Tx Planes Rx Planes Monitored Total Percent R/S/M Use 01234567 01234567 For (s) Uptime (s) Uptime ------------------------------------------------------------------------------- 0/RP0/CPU0 1 11111111 11111111 12702 12702 100.0000 0/RP1/CPU0 1 11111111 11111111 12702 12702 100.0000 1/RP0/CPU0 1 11111111 11111111 50137 50137 100.0000 1/RP1/CPU0 1 11111111 11111111 50137 50137 100.0000 |
Step 4 |
Execute the command: show controllers fabric bundle all detail. This command will show you output like below. Verify that each line shows 72 and 0. This shows that for Line Card Chassis 0, each of the fiber bundles has 72 active links and 0 downed links. If the output does not look like below, try cleaning the cable that is showing the problem. Example: Flags: P - plane admin down, p - plane oper down C - card admin down, c - card oper down A - asic admin down, a - asic oper down L - link port admin down, l - linkport oper down B - bundle port admin Down, b - bundle port oper down I - bundle admin down, i - bundle oper down N - node admin down, n - node down X - ctrl admin down, x - ctrl down o - other end of link down d - data down f - failed component downstream m - plane multicast down, s - link port permanently shutdown t - no barrier input O - Out-Of-Service oper down T - topology mismatch down e - link port control only D - plane admin data down U - issu down u - untunable g - tuning in progress v - successfully tuned at least once w - most recent tuning attempt failed h - tuning pending z - rx-eye measurement in progress Bundle Oper Down Plane Total Down Down Bundle Bundle R/S/M/P State Flags Id Links bp1-bp2 bp2-bp1 Port1 Port2 ---------------------------------------------------------------------------------------- 1/SM0/SP/0 UP 0 72 0 0 1/SM0/SP/0 0/SM0/SP/0 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM0/SP/1 UP 0 72 0 0 1/SM0/SP/1 0/SM0/SP/1 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM0/SP/2 UP 0 72 0 0 1/SM0/SP/2 0/SM0/SP/2 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM2/SP/0 UP 2 72 0 0 1/SM2/SP/0 0/SM2/SP/0 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +----------------------------------------------------------------+ 1/SM2/SP/1 UP 2 72 0 0 1/SM2/SP/1 0/SM2/SP/1 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM2/SP/2 UP 2 72 0 0 1/SM2/SP/2 0/SM2/SP/2 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM3/SP/0 UP 3 72 0 0 1/SM3/SP/0 0/SM3/SP/0 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM3/SP/1 UP 3 72 0 0 1/SM3/SP/1 0/SM3/SP/1 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM3/SP/2 UP 3 72 0 0 1/SM3/SP/2 0/SM3/SP/2 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM4/SP/0 UP 4 72 0 0 1/SM4/SP/0 0/SM4/SP/0 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM4/SP/1 UP 4 72 0 0 1/SM4/SP/1 0/SM4/SP/1 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM4/SP/2 UP 4 72 0 0 1/SM4/SP/2 0/SM4/SP/2 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM5/SP/0 UP 5 72 0 0 1/SM5/SP/0 0/SM5/SP/0 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM5/SP/1 UP 5 72 0 0 1/SM5/SP/1 0/SM5/SP/1 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM5/SP/2 UP 5 72 0 0 1/SM5/SP/2 0/SM5/SP/2 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM7/SP/0 UP 7 72 0 0 1/SM7/SP/0 0/SM7/SP/0 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM7/SP/1 UP 7 72 0 0 1/SM7/SP/1 0/SM7/SP/1 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ 1/SM7/SP/2 UP 7 72 0 0 1/SM7/SP/2 0/SM7/SP/2 +-----------------------------------------------------------------+ | Timestamp Flags Event Direction | +-----------------------------------------------------------------+ RP/0/RP0/CPU0:b2b(admin)# |
Step 5 | Execute the command: show controllers fabric plane all statistics. Verify that the output looks similar to below. The actual number of packets does not matter, as long as all fabric planes are showing some packets passed and no increasing errors. It is normal to have a few UCEs across the planes and many CEs on Plane 4. |
Step 6 |
Execute the command: show controllers fabric bundle all brief | i rack/SMslot/. This command will show you output like below. Verify that the status of all of the bundle members is UP. Example: Flags: P - plane admin down, p - plane oper down C - card admin down, c - card oper down A - asic admin down, a - asic oper down L - link port admin down, l - linkport oper down B - bundle port admin Down, b - bundle port oper down I - bundle admin down, i - bundle oper down N - node admin down, n - node down X - ctrl admin down, x - ctrl down o - other end of link down d - data down f - failed component downstream m - plane multicast down, s - link port permanently shutdown t - no barrier input O - Out-Of-Service oper down T - topology mismatch down e - link port control only D - plane admin data down U - issu down u - untunable g - tuning in progress v - successfully tuned at least once w - most recent tuning attempt failed h - tuning pending z - rx-eye measurement in progress Bundle Oper R/S/M/P State ------------------- 1/SM0/SP/0 UP 1/SM0/SP/1 UP 1/SM0/SP/2 UP 1/SM2/SP/0 UP 1/SM2/SP/1 UP 1/SM2/SP/2 UP 1/SM3/SP/0 UP 1/SM3/SP/1 UP 1/SM3/SP/2 UP 1/SM4/SP/0 UP 1/SM4/SP/1 UP 1/SM4/SP/2 UP 1/SM5/SP/0 UP 1/SM5/SP/1 UP 1/SM5/SP/2 UP 1/SM7/SP/0 UP 1/SM7/SP/1 UP 1/SM7/SP/2 UP RP/0/RP0/CPU0:b2b(admin)# # Or, you can perform a query by providing a bundle identifier for each fabric card. Execute the following command: show controllers fabric bundle 1/sm0/sp/n brief (where n varies from 0 to 2). Example: Fri Jan 13 19:06:09.248 PST Flags: P - plane admin down, p - plane oper down C - card admin down, c - card oper down A - asic admin down, a - asic oper down L - link port admin down, l - linkport oper down B - bundle port admin Down, b - bundle port oper down I - bundle admin down, i - bundle oper down N - node admin down, n - node down X - ctrl admin down, x - ctrl down o - other end of link down d - data down f - failed component downstream m - plane multicast down, s - link port permanently shutdown t - no barrier input O - Out-Of-Service oper down T - topology mismatch down e - link port control only D - plane admin data down U - issu down u - untunable g - tuning in progress v - successfully tuned at least once w - most recent tuning attempt failed h - tuning pending z - rx-eye measurement in progress Bundle Oper R/S/M/P State ------------------- 1/SM0/SP/1 UP |
Step 7 |
If any of the bundles are down, verify whether any of the links are down between two bundle ports (bp1, bp2) and verify the connectivity of the cables to ensure that the bundles are properly connected. Execute the following command: show controllers fabric bundle 1/sm0/sp/0 connection. Example: Fri Jan 13 19:05:00.529 PST Flags: P - plane admin down, p - plane oper down C - card admin down, c - card oper down A - asic admin down, a - asic oper down L - link port admin down, l - linkport oper down B - bundle port admin Down, b - bundle port oper down I - bundle admin down, i - bundle oper down N - node admin down, n - node down X - ctrl admin down, x - ctrl down o - other end of link down d - data down f - failed component downstream m - plane multicast down, s - link port permanently shutdown t - no barrier input O - Out-Of-Service oper down T - topology mismatch down e - link port control only D - plane admin data down U - issu down u - untunable g - tuning in progress v - successfully tuned at least once w - most recent tuning attempt failed h - tuning pending z - rx-eye measurement in progress Bundle Oper Down Plane Total Down Down Bundle Bundle R/S/M/P State Flags Id Links bp1-bp2 bp2-bp1 Port1 Port2 ---------------------------------------------------------------------------------------- 1/SM0/SP/0 UP 0 72 0 0 1/SM0/SP/0 0/SM0/SP/0 Actual connection data: Link Port Expected Actual State s3rx/1/SM0/SP/0/88 s1tx/0/SM0/SP/0/51 s1tx/0/SM0/SP/0/51 UP s3rx/1/SM0/SP/1/88 s1tx/0/SM0/SP/1/51 s1tx/0/SM0/SP/1/51 UP s3rx/1/SM0/SP/0/95 s1tx/0/SM0/SP/0/70 s1tx/0/SM0/SP/0/70 UP s3rx/1/SM0/SP/1/95 s1tx/0/SM0/SP/1/70 s1tx/0/SM0/SP/1/70 UP s3rx/1/SM0/SP/0/77 s1tx/0/SM0/SP/0/64 s1tx/0/SM0/SP/0/64 UP s3rx/1/SM0/SP/1/77 s1tx/0/SM0/SP/1/64 s1tx/0/SM0/SP/1/64 UP s3rx/1/SM0/SP/0/81 s1tx/0/SM0/SP/0/71 s1tx/0/SM0/SP/0/71 UP s3rx/1/SM0/SP/1/81 s1tx/0/SM0/SP/1/71 s1tx/0/SM0/SP/1/71 UP s3rx/1/SM0/SP/0/79 s1tx/0/SM0/SP/0/87 s1tx/0/SM0/SP/0/87 UP s3rx/1/SM0/SP/1/79 s1tx/0/SM0/SP/1/87 s1tx/0/SM0/SP/1/87 UP s3rx/1/SM0/SP/0/78 s1tx/0/SM0/SP/0/94 s1tx/0/SM0/SP/0/94 UP s3rx/1/SM0/SP/1/78 s1tx/0/SM0/SP/1/94 s1tx/0/SM0/SP/1/94 UP s3rx/0/SM0/SP/0/88 s1tx/1/SM0/SP/0/51 s1tx/1/SM0/SP/0/51 UP s3rx/0/SM0/SP/1/88 s1tx/1/SM0/SP/1/51 s1tx/1/SM0/SP/1/51 UP s3rx/0/SM0/SP/0/95 s1tx/1/SM0/SP/0/70 s1tx/1/SM0/SP/0/70 UP s3rx/0/SM0/SP/1/95 s1tx/1/SM0/SP/1/70 s1tx/1/SM0/SP/1/70 UP s3rx/0/SM0/SP/0/77 s1tx/1/SM0/SP/0/64 s1tx/1/SM0/SP/0/64 UP s3rx/0/SM0/SP/1/77 s1tx/1/SM0/SP/1/64 s1tx/1/SM0/SP/1/64 UP s3rx/0/SM0/SP/0/81 s1tx/1/SM0/SP/0/71 s1tx/1/SM0/SP/0/71 UP s3rx/0/SM0/SP/1/81 s1tx/1/SM0/SP/1/71 s1tx/1/SM0/SP/1/71 UP For example, if the cabling is incorrect and needs swapping, the output of the command appears as follows: Example: Wed Jul 27 21:34:24.859 UTC Flags: P - plane admin down, p - plane oper down C - card admin down, c - card oper down A - asic admin down, a - asic oper down L - link port admin down, l - linkport oper down B - bundle port admin Down, b - bundle port oper down I - bundle admin down, i - bundle oper down N - node admin down, n - node down X - ctrl admin down, x - ctrl down o - other end of link down d - data down f - failed component downstream m - plane multicast down, s - link port permanently shutdown t - no barrier input O - Out-Of-Service oper down T - topology mismatch down e - link port control only D - plane admin data down U - issu down Bundle Oper Down Plane Total Down Down Bundle Bundle R/S/M/P State Flags Id Links bp1-bp2 bp2-bp1 Port1 Port2 ---------------------------------------------------------------------------------------- 1/SM4/SP/0 DOWN b 4 72 24 24 1/SM4/SP/0 0/SM4/SP/0 Actual connection data: Please check bundle connection, they appear to be swapped with another bundle. Link Port Expected Actual State s3rx/1/SM4/SP/0/88 s1tx/0/SM4/SP/0/51 s1tx/0/SM4/SP/0/114 DOWN s3rx/1/SM4/SP/1/88 s1tx/0/SM4/SP/1/51 s1tx/0/SM4/SP/1/114 DOWN s3rx/1/SM4/SP/0/95 s1tx/0/SM4/SP/0/70 s1tx/0/SM4/SP/0/78 DOWN s3rx/1/SM4/SP/1/95 s1tx/0/SM4/SP/1/70 s1tx/0/SM4/SP/1/78 DOWN s3rx/1/SM4/SP/0/77 s1tx/0/SM4/SP/0/64 s1tx/0/SM4/SP/0/24 DOWN s3rx/1/SM4/SP/1/77 s1tx/0/SM4/SP/1/64 s1tx/0/SM4/SP/1/24 DOWN |
When the CRS Back-to-Back System cabling is complete, see Cisco IOS XR Getting Started Guide for directions on bringing up the system.