Understanding How VLANs Work
The following sections describe how VLANs work:
VLAN Overview
A VLAN is a group of end stations with a common set of requirements, independent of physical location. VLANs have the same attributes as a physical LAN but allow you to group end stations even if they are not located physically on the same LAN segment.
VLANs are usually associated with IP subnetworks. For example, all the end stations in a particular IP subnet belong to the same VLAN. Traffic between VLANs must be routed. LAN port VLAN membership is assigned manually on an port-by-port basis.
VLAN Ranges
Note You must enable the extended system ID to use 4096 VLANs (see the “Understanding the Bridge ID” section).
Cisco 7600 series routers support 4096 VLANs in accordance with the IEEE 802.1Q standard. These VLANs are organized into several ranges; you use each range slightly differently. Some of these VLANs are propagated to other switches in the network when you use the VLAN Trunking Protocol (VTP). The extended-range VLANs are not propagated, so you must configure extended-range VLANs manually on each network device.
Table 14-1 describes the VLAN ranges.
Table 14-1 VLAN Ranges
|
|
|
|
0, 4095 |
Reserved |
For system use only. You cannot see or use these VLANs. |
— |
1 |
Normal |
Cisco default. You can use this VLAN but you cannot delete it. |
Yes |
2–1001 |
Normal |
For Ethernet VLANs; you can create, use, and delete these VLANs. |
Yes |
1002–1005 |
Normal |
Cisco defaults for FDDI and Token Ring. You cannot delete VLANs 1002–1005. |
Yes |
1006–4094 |
Extended |
For Ethernet VLANs only. |
No |
The following information applies to VLAN ranges:
- Layer 3 LAN ports, WAN interfaces and subinterfaces, and some software features use internal VLANs in the extended range. You cannot use an extended range VLAN that has been allocated for internal use.
- To display the VLANs used internally, enter the show vlan internal usage command.
- You can configure ascending internal VLAN allocation (from 1006 and up) or descending internal VLAN allocation (from 4094 and down).
- Switches running the Catalyst operating system do not support configuration of VLANs 1006–1024. If you configure VLANs 1006–1024, ensure that the VLANs do not extend to any switches running Catalyst software.
- You must enable the extended system ID to use extended range VLANs (see the “Understanding the Bridge ID” section).
Configurable VLAN Parameters
Note ● Ethernet VLAN 1 uses only default values.
- Except for the VLAN name, Ethernet VLANs 1006 through 4094 use only default values.
- You can configure the VLAN name for Ethernet VLANs 1006 through 4094.
You can configure the following parameters for VLANs 2 through 1001:
- VLAN name
- VLAN type (Ethernet, FDDI, FDDI network entity title [NET], TrBRF, or TrCRF)
- VLAN state (active or suspended)
- Security Association Identifier (SAID)
- Bridge identification number for TrBRF VLANs
- Ring number for FDDI and TrCRF VLANs
- Parent VLAN number for TrCRF VLANs
- Spanning Tree Protocol (STP) type for TrCRF VLANs
Understanding Token Ring VLANs
The following section describes the two Token Ring VLAN types supported on network devices running VTP version 2:
Note Cisco 7600 series routers do not support Inter-Switch Link (ISL)-encapsulated Token Ring frames. When a Cisco 7600 series router is configured as a VTP server, you can configure Token Ring VLANs from the router.
Token Ring TrBRF VLANs
Token Ring Bridge Relay Function (TrBRF) VLANs interconnect multiple Token Ring Concentrator Relay Function (TrCRF) VLANs in a switched Token Ring network (see Figure 14-1). The TrBRF can be extended across a network devices interconnected via trunk links. The connection between the TrCRF and the TrBRF is referred to as a logical port.
Figure 14-1 Interconnected Token Ring TrBRF and TrCRF VLANs
For source routing, the Cisco 7600 series router appears as a single bridge between the logical rings. The TrBRF can function as a source-route bridge (SRB) or a source-route transparent (SRT) bridge running either the IBM or IEEE STP. If an SRB is used, you can define duplicate MAC addresses on different logical rings.
The Token Ring software runs an instance of STP for each TrBRF VLAN and each TrCRF VLAN. For TrCRF VLANs, STP removes loops in the logical ring. For TrBRF VLANs, STP interacts with external bridges to remove loops from the bridge topology, similar to STP operation on Ethernet VLANs.
To accommodate IBM System Network Architecture (SNA) traffic, you can use a combination of SRT and SRB modes. In a mixed mode, the TrBRF determines that some ports (logical ports connected to TrCRFs) operate in SRB mode while other ports operate in SRT mode
Token Ring TrCRF VLANs
Token Ring Concentrator Relay Function (TrCRF) VLANs define port groups with the same logical ring number. You can configure two types of TrCRFs in your network: undistributed and backup.
TrCRFs typically are undistributed, which means each TrCRF is limited to the ports on a single network device. Multiple undistributed TrCRFs on the same or separate network devices can be associated with a single parent TrBRF (see Figure 14-2). The parent TrBRF acts as a multiport bridge, forwarding traffic between the undistributed TrCRFs.
Note To pass data between rings located on separate network devices, you can associate the rings to the same TrBRF and configure the TrBRF for an SRB.
Figure 14-2 Undistributed TrCRFs
By default, Token Ring ports are associated with the default TrCRF (VLAN 1003, trcrf-default), which has the default TrBRF (VLAN 1005, trbrf-default) as its parent. In this configuration, a distributed TrCRF is possible (see Figure 14-3), and traffic is passed between the default TrCRFs located on separate network devices if the network devices are connected through an ISL trunk.
Figure 14-3 Distributed TrCRF
Within a TrCRF, source-route switching forwards frames based on either MAC addresses or route descriptors. The entire VLAN can operate as a single ring, with frames switched between ports within a single TrCRF.
You can specify the maximum hop count for All-Routes and Spanning Tree Explorer frames for each TrCRF. When you specify the maximum hop count, you limit the maximum number of hops an explorer is allowed to traverse. If a port determines that the explorer frame it is receiving has traversed more than the number of hops specified, it does not forward the frame. The TrCRF determines the number of hops an explorer has traversed by the number of bridge hops in the route information field.
If the ISL connection between network devices fails, you can use a backup TrCRF to configure an alternate route for traffic between undistributed TrCRFs. Only one backup TrCRF for a TrBRF is allowed, and only one port per network device can belong to a backup TrCRF.
If the ISL connection between the network devices fails, the port in the backup TrCRF on each affected network device automatically becomes active, rerouting traffic between the undistributed TrCRFs through the backup TrCRF. When the ISL connection is reestablished, all but one port in the backup TrCRF is disabled. Figure 14-4 illustrates the backup TrCRF.
Figure 14-4 Backup TrCRF
VLAN Default Configuration
Tables 14-2 through 14-6 show the default configurations for the different VLAN media types.
Table 14-2 Ethernet VLAN Defaults and Ranges
|
|
|
VLAN ID |
1 |
1–4094 |
VLAN name |
“default” for VLAN 1 “VLAN vlan_ID ” for other Ethernet VLANs |
— |
802.10 SAID |
10 vlan_ID |
100001–104094 |
MTU size |
1500 |
1500–18190 |
Translational bridge 1 |
0 |
0–1005 |
Translational bridge 2 |
0 |
0–1005 |
VLAN state |
active |
active, suspend |
Pruning eligibility |
VLANs 2–1001 are pruning eligible; VLANs 1006–4094 are not pruning eligible. |
— |
Table 14-3 FDDI VLAN Defaults and Ranges
|
|
|
VLAN ID |
1002 |
1–1005 |
VLAN name |
“fddi-default” |
— |
802.10 SAID |
101002 |
1–4294967294 |
MTU size |
1500 |
1500–18190 |
Ring number |
0 |
1–4095 |
Parent VLAN |
0 |
0–1005 |
Translational bridge 1 |
0 |
0–1005 |
Translational bridge 2 |
0 |
0–1005 |
VLAN state |
active |
active, suspend |
Table 14-4 Token Ring (TrCRF) VLAN Defaults and Ranges
|
|
|
VLAN ID |
1003 |
1–1005 |
VLAN name |
“token-ring-default” |
— |
802.10 SAID |
101003 |
1–4294967294 |
Ring Number |
0 |
1–4095 |
MTU size |
VTPv1 default 1500 VTPv2 default 4472 |
1500–18190 |
Translational bridge 1 |
0 |
0–1005 |
Translational bridge 2 |
0 |
0–1005 |
VLAN state |
active |
active, suspend |
Bridge mode |
srb |
srb, srt |
ARE max hops |
7 |
0–13 |
STE max hops |
7 |
0–13 |
Backup CRF |
disabled |
disable; enable |
Table 14-5 FDDI-Net VLAN Defaults and Ranges
|
|
|
VLAN ID |
1004 |
1–1005 |
VLAN name |
“fddinet-default” |
— |
802.10 SAID |
101004 |
1–4294967294 |
MTU size |
1500 |
1500–18190 |
Bridge number |
1 |
0–15 |
STP type |
ieee |
auto, ibm, ieee |
VLAN state |
active |
active, suspend |
Table 14-6 Token Ring (TrBRF) VLAN Defaults and Ranges
|
|
|
VLAN ID |
1005 |
1–1005 |
VLAN name |
“trnet-default” |
— |
802.10 SAID |
101005 |
1–4294967294 |
MTU size |
VTPv1 1500; VTPv2 4472 |
1500–18190 |
Bridge number |
1 |
0–15 |
STP type |
ibm |
auto, ibm, ieee |
VLAN state |
active |
active, suspend |
VLAN Interaction with Bridged Routed Encapsulation within an Automatic Protection Switching Group
In a Bridged Routed Encapsulation (BRE) scenario, an IP routed AAL5SNAP packet is bridged over the Ethernet side, adding a MAC header with a fake SRC MAC and configured distributed storage (DST). The ATM PVC traffic is relayed over an IP and not Ethernet. However, you cannot configure more than one virtual connection (VC) on the same VLAN. To configure more than one VC, customers configure two different VLANS on the protect and working interface of the Automatic Protection Switching (APS) group. This workaround is not a viable long- term solution because it results in high convergence time and an inefficient use of the VLANS. To resolve these limitations, you can use the BRE+APS feature to configure two VCs for the same VLAN, provided their parent interfaces too belong to the same Automatic Protection Switching (APS) group.
For information on configuring an APS group, see Cisco 7600 Series Router SIP, SSC, and SPA Software Configuration Guide at http://www.cisco.com/en/US/docs/interfaces_modules/shared_port_adapters/configuration/7600series/76cfgatm.html
Requirements and Restrictions
Follow these requirements and restrictions when you configure the BRE+APS feature:
- You can configure BRE-Connect VLANS for two different VCs if the new VC:
– belongs to the same APS group to which the first VC belongs.
– does not belong to the same ATM interface as the first VC.
- Before you change the APS parameters of an interface (changing the APS group or removing the APS configurations), first ensure that the BRE configurations on the interface are removed.
- When you configure BRE on an ATM interface, you cannot configure a L2 IP address at the BRE end, but you can configure an IP address at the L3 non BRE end.
Table 14-7 Show command for ATM VLAN BRE
|
|
|
Step 1 |
Router(config)# show atm vlan bre |
Verifies the configuration and displays the status of the PVC. An Active VC is displayed as UP and an inactive VC as DN (down). |
This example shows how to verify the configuration of BRE ATM VLAN:
Router# show atm vlan bre
Interface Bre VCD VPI/VCI Vlan Learned MAC Virtual MAC State
ATM3/0/0.1 1 0/11 100 0000.0000.0000 0000.0300.0001 UP
ATM3/0/0.2 2 1/13 200 0000.0000.0000 0000.0300.0002 UP
ATM4/0/0.2 2 1/13 300 0000.0000.0000 0000.0400.0002 DN
Warning Messages
Consider instances where you have configured APS on the main interface, and have configured BRE within a main interface and subinterface. The warning message “%ATM2/0/0 - Remove BRE configs on this interface before changing APS configs"appears when you attempt to modify the APS configurations in the main interface, without removing the BRE configurations first.
Configuring VLANs
These sections describe how to configure VLANs:
Note VLANs support a number of parameters that are not discussed in detail in this section. For complete information, refer to the Cisco 7600 Series Router Cisco IOS Command Reference publication.
VLAN Configuration Background Information
If the router is in VTP server or transparent mode (see the “Configuring VTP” section), you can configure VLANs in global and config-vlan configuration modes. When you configure VLANs in global and config-vlan configuration modes, the VLAN configuration is saved in the vlan.dat files. To display the VLAN configuration, enter the show vlan command.
If the router is in VLAN transparent mode, use the copy running-config startup-config command to save the VLAN configuration to the startup-config file. After you save the running configuration as the startup configuration, use the show running-config and show startup-config commands to display the VLAN configuration.
Note ● When the router boots, if the VTP domain name and VTP mode in the startup-config and vlan.dat files do not match, the router uses the configuration in the vlan.dat file.
- VLAN database mode, which was available in Release 12.2(18)SXD and earlier releases, is no longer supported.
- RPR+ redundancy does not support configurations entered in VLAN database mode. Use global configuration mode with RPR+ redundancy.
Creating or Modifying an Ethernet VLAN
User-configured VLANs have unique IDs from 1 to 4094, except for reserved VLANs (see Table 14-1). Enter the vlan command with an unused ID to create a VLAN. Enter the vlan command for an existing VLAN to modify the VLAN (you cannot modify an existing VLAN that is being used by a Layer 3 port or a software feature).
See the “VLAN Default Configuration” section for the list of default parameters that are assigned when you create a VLAN. If you do not specify the VLAN type with the media keyword, the VLAN is an Ethernet VLAN.
To create or modify a VLAN, perform this task:
|
|
|
Step 1 |
Router# configure terminal or Router# vlan database |
Enters VLAN configuration mode. |
Step 2 |
Router(config)# vlan vlan_ID {[- vlan_ID ]|[, vlan_ID ]) Router(config-vlan)# or Router(vlan)# vlan vlan_ID |
Creates or modifies an Ethernet VLAN, a range of Ethernet VLANs, or several Ethernet VLANs specified in a comma-separated list (do not enter space characters). |
Router(config)# no vlan vlan_ID Router(config-vlan)# or Router(vlan)# no vlan vlan_ID |
Deletes a VLAN. |
Step 3 |
Router(config-vlan)# end or Router(vlan)# exit |
Updates the VLAN database and returns to privileged EXEC mode. |
Step 4 |
Router# show vlan [ id | name ] vlan |
Verifies the VLAN configuration. |
When you create or modify an Ethernet VLAN, note the following information:
- RPR+ redundancy does not support a configuration entered in VLAN database mode. Use global configuration mode with RPR+ redundancy.
- Because Layer 3 ports and some software features require internal VLANs allocated from 1006 and up, configure extended-range VLANs starting with 4094.
- Layer 3 ports and some software features use extended-range VLANs. If the VLAN you are trying to create or modify is being used by a Layer 3 port or a software feature, the router displays a message and does not modify the VLAN configuration.
When deleting VLANs, note the following information:
- You cannot delete the default VLANs for the different media types: Ethernet VLAN 1 and FDDI or Token Ring VLANs 1002 to 1005.
- When you delete a VLAN, any LAN ports configured as access ports assigned to that VLAN become inactive. The ports remain associated with the VLAN (and inactive) until you assign them to a new VLAN.
This example shows how to create an Ethernet VLAN and verify the configuration:
Router# configure terminal
---- -------------------------------- --------- -------------------------------
VLAN Type SAID MTU Parent RingNo BridgeNo Stp BrdgMode Trans1 Trans2
---- ----- ---------- ----- ------ ------ -------- ---- -------- ------ ------
3 enet 100003 1500 - - - - - 0 0
Primary Secondary Type Interfaces
------- --------- ----------------- ------------------------------------------
This example shows how to verify the configuration:
Router# show vlan name VLAN0003
---- -------------------------------- --------- ---------------------
VLAN Type SAID MTU Parent RingNo BridgeNo Stp Trans1 Trans2
---- ----- ---------- ----- ------ ------ -------- ---- ------ ------
3 enet 100003 1500 - - - - 0 0
You can also use the sh vlan free and sh vlan free summary command to To list and view the total number of free vlans and display the vlan usage summary information in the system.
Summary Total number of free vlans in the system
Summary Total number of free vlans in the system
Router#show vlan free summ
Router#show vlan free summary ?
Router#show vlan free summary
======= VLAN free/usage Summary =======
Total number of available vlans = 4094
Total number of free vlans = 4074
Total number of used vlans = 20
Assigning a Layer 2 LAN Interface to a VLAN
A VLAN created in a management domain remains unused until you assign one or more LAN ports to the VLAN.
Note Make sure you assign LAN ports to a VLAN of the appropriate type. Assign Ethernet ports to Ethernet-type VLANs.
To assign one or more LAN ports to a VLAN, complete the procedures in the “Configuring LAN Interfaces for Layer 2 Switching” section.
Configuring the Internal VLAN Allocation Policy
For more information about VLAN allocation, see the “VLAN Ranges” section.
Note The internal VLAN allocation policy is applied only following a reload.
To configure the internal VLAN allocation policy, perform this task:
|
|
|
Step 1 |
Router(config)# vlan internal allocation policy { ascending | descending } |
Configures the internal VLAN allocation policy. |
Router(config)# no vlan internal allocation policy |
Returns to the default (ascending). |
Step 2 |
Router(config)# end |
Exits configuration mode. |
Step 3 |
Router# reload |
Applies the new internal VLAN allocation policy.
Caution You need not enter the
reload command immediately. Enter the
reload command during a planned maintenance window.
|
When you configure the internal VLAN allocation policy, note the following information:
- Enter the ascending keyword to allocate internal VLANs from 1006 and up.
- Enter the descending keyword to allocate internal VLAN from 4094 and down.
This example shows how to configure descending as the internal VLAN allocation policy:
Router# configure terminal
Router(config)# vlan internal allocation policy descending
Configuring VLAN Translation
On trunk ports, you can translate one VLAN number to another VLAN number, which transfers all traffic received in one VLAN to the other VLAN.
These sections describe VLAN translation:
Note To avoid spanning tree loops, be careful not to misconfigure the VLAN translation feature.
VLAN Translation Guidelines and Restrictions
When translating VLANs, follow these guidelines and restrictions:
- A VLAN translation configuration is inactive if it is applied to ports that are not Layer 2 trunks.
- Do not configure translation of ingress native VLAN traffic on an 802.1Q trunk. Because 802.1Q native VLAN traffic is untagged, it cannot be recognized for translation. You can translate traffic from other VLANs to the native VLAN of an 802.1Q trunk.
- If you enable a vlan translation within an interface, the inteface is reset.
- Do not remove the VLAN to which you are translating from the trunk.
- The VLAN translation configuration applies to all ports in a port group. VLAN translation is disabled by default on all ports in a port group. Enable VLAN translation on ports as needed.
- The following table lists:
– The modules that support VLAN translation
– The port groups to which VLAN translation configuration applies
– The number of VLAN translations supported by the port groups
– The trunk types supported by the modules
Note LAN ports on OSMs support VLAN translation. LAN ports on OSMs are in a single port group.
|
|
|
Port Ranges
per
Port Group
|
Translations
per
Port Group
|
VLAN Translation
Trunk-Type Support
|
WS-SUP720-3BXL WS-SUP720-3B WS-SUP720 |
2 |
1 |
1–2 |
32 |
802.1Q |
WS-SUP32-10GE |
3 |
2 |
1, 2–3 |
16 |
ISL 802.1Q |
WS-SUP32-GE |
9 |
1 |
1–9 |
16 |
ISL 802.1Q |
WS-X6704-10GE |
4 |
4 |
1 port in each group |
128 |
ISL 802.1Q |
WS-X6708-10GE |
8 |
8 |
1 port in each group |
16 |
ISL 802.1Q |
WS-X6502-10GE |
1 |
1 |
1 port in 1 group |
32 |
802.1Q |
WS-X6724-SFP |
24 |
2 |
1–12 13–24 |
128 |
ISL 802.1Q |
WS-X6816-GBIC |
16 |
2 |
1–8 9–16 |
32 |
802.1Q |
WS-X6516A-GBIC |
16 |
2 |
1–8 9–16 |
32 |
802.1Q |
WS-X6516-GBIC |
16 |
2 |
1–8 9–16 |
32 |
802.1Q |
WS-X6748-GE-TX |
48 |
4 |
1-23 odd 25-47 odd 2-24 even 26-48 even |
128 |
ISL 802.1Q |
WS-X6516-GE-TX |
16 |
2 |
1–8 9–16 |
32 |
802.1Q |
WS-X6524-100FX-MM |
24 |
1 |
1–24 |
32 |
ISL 802.1Q |
WS-X6548-RJ-45 |
48 |
1 |
1–48 |
32 |
ISL 802.1Q |
WS-X6548-RJ-21 |
48 |
1 |
1–48 |
32 |
ISL 802.1Q |
Note For a WS-X6748-GE-TX card, the ports are grouped in an odd and even fashion per ASIC and number of VLAN mappings per port group is 128. Since the VLAN mapping configuration is applicable to all ports in a port group, the total number of VLAN mappings done are 22.
Note To configure a port as a trunk, see the “Configuring a Layer 2 Switching Port as a Trunk” section.
Configuring VLAN Translation on a Trunk Port
To translate VLANs on a trunk port, perform this task:
|
|
|
Step 1 |
Router(config)# interface type slot/port |
Selects the Layer 2 trunk port to configure. |
Step 2 |
Router(config-if)# switchport vlan mapping enable |
Enables VLAN translation. |
Step 3 |
Router(config-if)# switchport vlan mapping original_vlan_ID translated_vlan_ID |
Translates a VLAN to another VLAN. The valid range is 1 to 4094. |
Router(config-if)# no switchport vlan mapping { all | original_vlan_ID translated_vlan_ID } |
Deletes the mapping. |
Step 4 |
Router(config-if)# end |
Exits configuration mode. |
Step 5 |
Router# show interface type 1 slot/port vlan mapping |
Verifies the VLAN mapping. |
This example shows how to map VLAN 1649 to VLAN 755 Gigabit Ethernet port 5/2:
Router# configure terminal
Router(config)# interface gigabitethernet 5/2
Router(config-if)# switchport vlan mapping 1649 755
This example shows how to verify the configuration:
Router# show interface gigabitethernet 5/2 vlan mapping
Original VLAN Translated VLAN
------------- ---------------
Enabling VLAN Translation on Other Ports in a Port Group
To enable VLAN translation on other ports in a port group, perform this task:
|
|
|
Step 1 |
Router(config)# interface type slot/port |
Selects the LAN port to configure. |
Step 2 |
Router(config-if)# switchport vlan mapping enable |
Enables VLAN translation. |
Router(config-if)# no switchport vlan mapping enable |
Disables VLAN translation. |
Step 3 |
Router(config-if)# end |
Exits configuration mode. |
Step 4 |
Router# show interface type 1 slot/port vlan mapping |
Verifies the VLAN mapping.
Note The vlan option is available, although it may not be displayed in the listed options for the show interface command..
|
This example shows how to enable VLAN translation on a port:
Router# configure terminal
Router(config)# interface gigabitethernet 5/2
Router(config-if)# switchport vlan mapping enable
Mapping 802.1Q VLANs to ISL VLANs
The valid range of user-configurable ISL VLANs is 1 through 1001 and 1006 through 4094. The valid range of VLANs specified in the IEEE 802.1Q standard is 1 to 4094. You can map 802.1Q VLAN numbers to ISL VLAN numbers.
802.1Q VLANs in the range 1 through 1001 and 1006 through 4094 are automatically mapped to the corresponding ISL VLAN. 802.1Q VLAN numbers corresponding to reserved VLAN numbers must be mapped to an ISL VLAN in order to be recognized and forwarded by Cisco network devices.
These restrictions apply when mapping 802.1Q VLANs to ISL VLANs:
- You can configure up to eight 802.1Q-to-ISL VLAN mappings on the Cisco 7600 series router.
- You can only map 802.1Q VLANs to Ethernet-type ISL VLANs.
- Do not enter the native VLAN of any 802.1Q trunk in the mapping table.
- When you map an 802.1Q VLAN to an ISL VLAN, traffic on the 802.1Q VLAN corresponding to the mapped ISL VLAN is blocked. For example, if you map 802.1Q VLAN 1007 to ISL VLAN 200, traffic on 802.1Q VLAN 200 is blocked.
- VLAN mappings are local to each Cisco 7600 series router. Make sure you configure the same VLAN mappings on all appropriate network devices.
To map an 802.1Q VLAN to an ISL VLAN, perform this task:
|
|
|
Step 1 |
Router(config)# vlan mapping dot1q dot1q_vlan_ID isl isl_vlan_ID |
Maps an 802.1Q VLAN to an ISL Ethernet VLAN. The valid range for dot1q_vlan_ID is 1001 to 4094. The valid range for isl_vlan_ID is the same. |
Router(config)# no vlan mapping dot1q { all | dot1q_vlan_ID } |
Deletes the mapping. |
Step 2 |
Router(config)# end |
Exits configuration mode. |
Step 3 |
Router# show vlan |
Verifies the VLAN mapping. |
This example shows how to map 802.1Q VLAN 1003 to ISL VLAN 200:
Router# configure terminal
Router(config)# vlan mapping dot1q 1003 isl 200
This example shows how to verify the configuration:
802.1Q Trunk Remapped VLANs: