Manual:Interface/VLAN: Difference between revisions

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===Trunk===
===Create ''trunks'' and implement routing between VLANs===
<p>
 
Let us assume that we have two or more MikroTik RouterOS routers connected with a hub. Interfaces to the physical network, where VLAN is to be created is ether1 for all of them (it is needed only for example simplification, it is NOT a must).
If separate VLANs are implemented on a switch, then router is required to provide communication between VLANs.
</p>
Switch works at OSI layer 2 so it uses only Ethernet header to forward and does not check IP header.
<p>
For this reason we must use the router that is working as a gateway for each VLAN. Without a router host is unable to communicate outside its own VLAN.
To connect computers through VLAN they must be connected physically and unique IP addresses should be assigned them so that they could ping each other. Then on each of them the VLAN interface should be created:
Routing process between VLANs described above is called inter-VLAN communication.
 
To illustrate inter-VLAN communication, we will create a trunk that will carry traffic from three VLANs (VLAN2 and VLAN3, VLAN4) across a single link between Mikrotik router and a manageable switch that supports VLAN trunking.
[[Image:image12005.gif]]
 
Each VLAN has its own separate subnet (broadcast domain) as we see in figure above:
* VLAN 2 – 10.10.20.0/24;
* VLAN 3 – 10.10.30.0/24;
* VLAN 4 – 10.10.40.0./24.
 
VLAN configuration on most of switches is straightforward, basically we need to define which ports are members of VLAN and define "trunk" port that can carry tagged frames between switch and router.  
 
'''Configuration example on MikroTik router:'''
 
''Create VALN interfaces:''
 
<pre>
<pre>
[admin@MikroTik] interface vlan> add name=test vlan-id=32 interface=ether1
[admin@MikroTik] /interface vlan> add name=VLAN2 vlan-id=2 interface=ether1 disabled=no
[admin@MikroTik] interface vlan> print
 
Flags: X - disabled, R - running
[admin@MikroTik] /interface vlan> add name=VLAN3 vlan-id=3 interface=ether1 disabled=no
  #    NAME                MTU  ARP      VLAN-ID INTERFACE
 
  0  R test                1500 enabled  32      ether1
[admin@MikroTik] /interface vlan> add name=VLAN4 vlan-id=4 interface=ether1 disabled=no
[admin@MikroTik] interface vlan>
</pre>
</pre>
If the interfaces were successfully created, both of them will be running. If computers are connected incorrectly (through network device that does not retransmit or forward VLAN packets), either both or one of the interfaces will not be running.
 
</p>
 
<p>
''Add ip addresses to VLANs:''
When the interface is running, IP addresses can be assigned to the VLAN interfaces.
 
</p>
<p>
On the Router 1:
<pre>
<pre>
[admin@MikroTik] ip address> add address=10.10.10.1/24 interface=test
[admin@MikroTik] ip address> add address=10.10.20.1/24 interface=VLAN2
[admin@MikroTik] ip address> print
[admin@MikroTik] ip address> add address=10.10.30.1/24 interface=VLAN3
Flags: X - disabled, I - invalid, D - dynamic
[admin@MikroTik] ip address> add address=10.10.40.1/24 interface=VLAN4
  #  ADDRESS            NETWORK        BROADCAST      INTERFACE
  0  10.0.0.204/24      10.0.0.0        10.0.0.255      ether1
  1  10.20.0.1/24       10.20.0.0      10.20.0.255    pc1
  2  10.10.10.1/24     10.10.10.0      10.10.10.255    test
[admin@MikroTik] ip address>
</pre>
</pre>
</p>
 
<p>
 
On the Router 2:
<pre>
[admin@MikroTik] ip address> add address=10.10.10.2/24 interface=test
[admin@MikroTik] ip address> print
Flags: X - disabled, I - invalid, D - dynamic
  #  ADDRESS            NETWORK        BROADCAST      INTERFACE
  0  10.0.0.201/24      10.0.0.0        10.0.0.255      ether1
  1  10.10.10.2/24      10.10.10.0      10.10.10.255    test
[admin@MikroTik] ip address>
</pre>
If it set up correctly, then it is possible to ping Router 2 from Router 1 and vice versa:
<pre>
[admin@MikroTik] ip address> /ping 10.10.10.1
10.10.10.1 64 byte pong: ttl=255 time=3 ms
10.10.10.1 64 byte pong: ttl=255 time=4 ms
10.10.10.1 64 byte pong: ttl=255 time=10 ms
10.10.10.1 64 byte pong: ttl=255 time=5 ms
4 packets transmitted, 4 packets received, 0% packet loss
round-trip min/avg/max = 3/10.5/10 ms
[admin@MikroTik] ip address> /ping 10.10.10.2
10.10.10.2 64 byte pong: ttl=255 time=10 ms
10.10.10.2 64 byte pong: ttl=255 time=11 ms
10.10.10.2 64 byte pong: ttl=255 time=10 ms
10.10.10.2 64 byte pong: ttl=255 time=13 ms
4 packets transmitted, 4 packets received, 0% packet loss
round-trip min/avg/max = 10/11/13 ms
[admin@MikroTik] ip address>
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</p>
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Revision as of 10:38, 30 August 2010

Version.png

Applies to RouterOS: v3, v4+

Summary

Sub-menu: /interface vlan
Standards: IEEE 802.1Q

Virtual Local Area Network (VLAN) is layer 2 method that allows you to have multiple Virtual LANs on a single physical interface (ethernet, wireless, etc.), giving the ability to segregate LANs efficiently.

You can use MikroTik RouterOS (as well as Cisco IOS, Linux and other router systems) to mark these packets as well as to accept and route marked ones.

As VLAN works on OSI Layer 2, it can be used just as any other network interface without any restrictions. VLAN successfully passes through regular Ethernet bridges.

You can also transport VLANs over wireless links and put multiple VLAN interfaces on a single wireless interface. Note that as VLAN is not a full tunnel protocol (i.e., it does not have additional fields to transport MAC addresses of sender and recipient), the same limitation applies to bridging over VLAN as to bridging plain wireless interfaces. In other words, while wireless clients may participate in VLANs put on wireless interfaces, it is not possible to have VLAN put on a wireless interface in station mode bridged with any other interface.

802.1Q

The most commonly used protocol for Virtual LANs (VLANs) is IEEE 802.1Q. It is standardized encapsulation protocol that defines how to insert a four-byte VLAN identifier into Ethernet header. (see Figure 12.1.)

File:Image12001.gif

Each VLAN is treated as separate subnet. It means that, by default, host in specific VLAN cannot communicate with host that is member of another VLAN, although they are connected in the same switch. So if you want inter-VLAN communication you need a router. RouterOS supports up to 4095 VLAN interfaces, each with a unique VLAN ID, per interface. VLAN priorites may also be used and manipulated.

When the VLAN extends over more than one switch, the inter-switch link have to become trunk, where packets are tagged to indicate which VLAN they belong to. A trunk carries the traffic of multiple VLANs, it is like a point-to-point link that carries tagged packets between switches or between a switch and router.

File:Image12003.gif


Q-in-Q

Original 802.1Q allows only one vlan header, Q-in-Q in the other hand allows two or more vlan headers. In RouterOS Q-in-Q can be configured by adding one vlan interface over another. Example:

/interface vlan
add name=vlan1 vlan-id=11 interface=ether1
add name=vlan2 vlan-id=12 interface=vlan1

If any packet is sent over "vlan2" interface, two vlan tags will be added to ethernet header - "11" and "12".

Properties

Property Description
arp (disabled | enabled | proxy-arp | reply-only; Default: enabled) Address Resolution Protocol mode
interface (name; Default: ) Name of physical interface on top of which VLAN will work
l2mtu (integer; Default: ) Layer2 MTU. For VLANS this value is not configurable. Read more>>
mtu (integer; Default: 1500) Layer3 Maximum transmission unit
name (string; Default: ) Interface name
use-service-tag (yes | no; Default: ) 802.1ad compatible Service Tag
vlan-id (integer: 4095; Default: 1) Virtual LAN identifier or tag that is used to distinguish VLANs. Must be equal for all computers that belong to the same VLAN.


Icon-note.png

Note: MTU should be set to 1500 bytes as on Ethernet interfaces. But this may not work with some Ethernet cards that do not support receiving/transmitting of full size Ethernet packets with VLAN header added (1500 bytes data + 4 bytes VLAN header + 14 bytes Ethernet header). In this situation MTU 1496 can be used, but note that this will cause packet fragmentation if larger packets have to be sent over interface. At the same time remember that MTU 1496 may cause problems if path MTU discovery is not working properly between source and destination.


Setup examples

Simple Example

Lets assume that we have several MikroTik routers connected to a hub. Remember that hub is OSI physical layer device (if there is a hub between routers, then from L3 point of view it is the same as Ethernet cable connection between them). For simplification assume that all routers are connected to the hub using ether1 interface and has assigned IP addresses as illustrated in figure below. Then on each of them the VLAN interface should be created. File:Image12004.gif

Configuration for R2 and R4 is shown below:

R2:

[admin@MikroTik] /interface vlan> add name=VLAN2 vlan-id=2 interface=ether1 disabled=no

[admin@MikroTik] /interface vlan> print 
Flags: X - disabled, R - running, S - slave 
 #    NAME                  MTU   ARP        VLAN-ID INTERFACE                
0 R  VLAN2                 1500  enabled    2       ether1


R4:

[admin@MikroTik] /interface vlan> add name=VLAN2 vlan-id=2 interface=ether1 disabled=no

[admin@MikroTik] /interface vlan> print 
Flags: X - disabled, R - running, S - slave 
 #    NAME                  MTU   ARP        VLAN-ID INTERFACE                
0 R  VLAN2                 1500  enabled    2       ether1


The next step is to assign IP addresses to the VLAN interfaces.

R2:

 [admin@MikroTik] ip address> add address=10.10.10.3/24 interface=VLAN2
 [admin@MikroTik] ip address> print
 Flags: X - disabled, I - invalid, D - dynamic
   #   ADDRESS            NETWORK         BROADCAST       INTERFACE
   0   10.0.1.4/24        10.0.1.0        10.0.1.255      ether1
   1   10.20.0.1/24       10.20.0.0       10.20.0.255     pc1
   2   10.10.10.3/24      10.10.10.0      10.10.10.255    vlan2

 [admin@MikroTik] ip address>

R4:

 [admin@MikroTik] ip address> add address=10.10.10.5/24 interface=VLAN2
 [admin@MikroTik] ip address> print
 Flags: X - disabled, I - invalid, D - dynamic
   #   ADDRESS            NETWORK         BROADCAST       INTERFACE
   0   10.0.1.5/24        10.0.1.0        10.0.1.255      ether1
   1   10.30.0.1/24       10.30.0.0       10.30.0.255     pc2
   2   10.10.10.5/24      10.10.10.0      10.10.10.255    vlan2

[admin@MikroTik] ip address>


At this point it should be possible to ping router R4 from router R2 and vice versa:

 '''Ping from R2 to R4:'''

 [admin@MikroTik] ip address> /ping 10.10.10.5

 10.10.10.5 64 byte ping: ttl=255 time=4 ms

 10.10.10.5 64 byte ping: ttl=255 time=1 ms

 2 packets transmitted, 2 packets received, 0% packet loss

 round-trip min/avg/max = 1/2.5/4 ms


 '''From R4 to R2:'''
 
 [admin@MikroTik] ip address> /ping 10.10.10.3
 10.10.10.3 64 byte ping: ttl=255 time=6 ms
 10.10.10.3 64 byte ping: ttl=255 time=1 ms
 2 packets transmitted, 2 packets received, 0% packet loss
 round-trip min/avg/max = 1/3.5/6 ms

To make sure if VLAN setup is working properly, try to ping R1 from R2. If pings are timing out then VLANs are successfully isolated.

 
 '''From R2 to R1:'''

 [admin@MikroTik] ip address> /ping 10.10.10.2
 10.10.10.2 ping timeout
 10.10.10.2 ping timeout
 3 packets transmitted, 0 packets received, 100% packet loss

Create trunks and implement routing between VLANs

If separate VLANs are implemented on a switch, then router is required to provide communication between VLANs. Switch works at OSI layer 2 so it uses only Ethernet header to forward and does not check IP header. For this reason we must use the router that is working as a gateway for each VLAN. Without a router host is unable to communicate outside its own VLAN. Routing process between VLANs described above is called inter-VLAN communication.

To illustrate inter-VLAN communication, we will create a trunk that will carry traffic from three VLANs (VLAN2 and VLAN3, VLAN4) across a single link between Mikrotik router and a manageable switch that supports VLAN trunking. File:Image12005.gif

Each VLAN has its own separate subnet (broadcast domain) as we see in figure above:

  • VLAN 2 – 10.10.20.0/24;
  • VLAN 3 – 10.10.30.0/24;
  • VLAN 4 – 10.10.40.0./24.

VLAN configuration on most of switches is straightforward, basically we need to define which ports are members of VLAN and define "trunk" port that can carry tagged frames between switch and router.

Configuration example on MikroTik router:

Create VALN interfaces:

[admin@MikroTik] /interface vlan> add name=VLAN2 vlan-id=2 interface=ether1 disabled=no

[admin@MikroTik] /interface vlan> add name=VLAN3 vlan-id=3 interface=ether1 disabled=no

[admin@MikroTik] /interface vlan> add name=VLAN4 vlan-id=4 interface=ether1 disabled=no


Add ip addresses to VLANs:

[admin@MikroTik] ip address> add address=10.10.20.1/24 interface=VLAN2
[admin@MikroTik] ip address> add address=10.10.30.1/24 interface=VLAN3
[admin@MikroTik] ip address> add address=10.10.40.1/24 interface=VLAN4


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