Cisco Systems IGX 8400 Series Manual De Usuario
Card Installation and Node Startup 3-11
Setting Up a UXM-E
The following is the command sequence for bringing up the trunk. You must bring up the trunk
before you add connections. For detailed command descriptions, see the command references.
before you add connections. For detailed command descriptions, see the command references.
Step 1
To verify the correct card locations in both the local and remote nodes, enter:
dspcds
Step 2
Configure the cellbus bandwidth allocation for the card if you do not plan to rely on
automatic increases from switch software. Use the superuser command cnfbusbw on the
CLI to see the current allocation and increase the allocation.
automatic increases from switch software. Use the superuser command cnfbusbw on the
CLI to see the current allocation and increase the allocation.
Note
Cisco recommends that you not allow oversubscription. Refer to the Cisco IGX 8400 Series
Reference for the description of cellbus bandwidth allocation and the Cisco WAN Switching
SuperUser Command Reference for a description of cnfbusbw. Any user can view the current
cellbus bandwidth allocation by using the dspbusbw command.
SuperUser Command Reference for a description of cnfbusbw. Any user can view the current
cellbus bandwidth allocation by using the dspbusbw command.
Step 3
Activate the trunk by using uptrk. Execute this command on the nodes at both ends of
the trunk. On the CLI, use the vt command to reach the far-end node to execute
commands. The only trunk cards you can connect to a UXM-E trunk are another UXM-E
trunk card or a BXM in trunk mode. The syntax of the single-port trunk specification is
slot.port.
the trunk. On the CLI, use the vt command to reach the far-end node to execute
commands. The only trunk cards you can connect to a UXM-E trunk are another UXM-E
trunk card or a BXM in trunk mode. The syntax of the single-port trunk specification is
slot.port.
To specify an IMA trunk through the CLI, enter uptrk slot.first_line–last_line. The line
numbers must be contiguous.
numbers must be contiguous.
Step 4
At each end, configure trunk parameters as required by using cnftrk. Each type of trunk
comes up with a default configuration, but you can alter the configuration with cnftrk.
Refer to the cnftrk description in the Cisco WAN Switching Command Reference for the
parameters that apply to each interface.
comes up with a default configuration, but you can alter the configuration with cnftrk.
Refer to the cnftrk description in the Cisco WAN Switching Command Reference for the
parameters that apply to each interface.
Step 5
Use addtrk to add the trunk. Adding the trunk makes it a usable resource, so you can
subsequently add connections through Cisco WAN Manager or the CLI (addcon). Add
the trunk at only one node. If, after you add the trunk, you later determine that changes to
the trunk parameters are necessary, you can change certain parameters with cnftrk
without taking the trunk out of service.
subsequently add connections through Cisco WAN Manager or the CLI (addcon). Add
the trunk at only one node. If, after you add the trunk, you later determine that changes to
the trunk parameters are necessary, you can change certain parameters with cnftrk
without taking the trunk out of service.
Step 6
Optionally, you can configure a UXM-E trunk as a clock source. Enter:
cnfclksrc
Step 7
Configure the cellbus bandwidth allocation with cnfbusbw if you plan to activate many
ports or carry a large number of connections on the UXM-E trunk. Use dspbusbw or
cnfbusbw to check cellbus usage and changes in bandwidth requirements for the
UXM-E. For information on cellbus bandwidth needs, see the Cisco IGX 8400 Series
Reference.
ports or carry a large number of connections on the UXM-E trunk. Use dspbusbw or
cnfbusbw to check cellbus usage and changes in bandwidth requirements for the
UXM-E. For information on cellbus bandwidth needs, see the Cisco IGX 8400 Series
Reference.
Step 8
To configure physical and logical trunk statistics, use cnfphyslnstats and cnftrkstats,
respectively. See the Cisco IGX 8400 Series Reference regarding UXM-E trunk statistics.
respectively. See the Cisco IGX 8400 Series Reference regarding UXM-E trunk statistics.
Inverse Multiplexing over ATM on Trunks
An IMA lets you group physical T1 or E1 lines to form a logical trunk. A logical trunk consisting of
more than one T1 or E1 line supports connections with data rates that are much higher than the T1
or E1 rate. System software lets you specify IMA so that one or more physical lines within the
logical trunk can serve as backup if a line fails. IMA characteristics are as follows:
more than one T1 or E1 line supports connections with data rates that are much higher than the T1
or E1 rate. System software lets you specify IMA so that one or more physical lines within the
logical trunk can serve as backup if a line fails. IMA characteristics are as follows:
•
All physical ports of an IMA trunk use the same line configuration.