Virtual Local Area Networks

Suba Varadarajan, varadarajan.5@osu.edu
This paper describes virtual local area networks (VLAN's) , their uses and how they work in accordance with the 802.1Q standard.
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Table of Contents


1.0 Introduction

A Local Area Network (LAN) was originally defined as a network of computers located within the same area. Today, Local Area Networks are defined as a single broadcast domain. This means that if a user broadcasts information on his/her LAN, the broadcast will be received by every other user on the LAN. Broadcasts are prevented from leaving a LAN by using a router. The disadvantage of this method is routers usually take more time to process incoming data compared to a bridge or a switch. More importantly, the formation of broadcast domains depends on the physical connection of the devices in the network. Virtual Local Area Networks (VLAN's) were developed as an alternative solution to using routers to contain broadcast traffic.

In Section 2, we define VLAN's and examine the difference between a LAN and a VLAN. This is followed by a discussion on the advantages VLAN's introduce to a network in Section 3. Finally, we explain how VLAN's work based on the current draft standards in Section 4.

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2.0 What are VLAN's?

In a traditional LAN, workstations are connected to each other by means of a hub or a repeater. These devices propagate any incoming data throughout the network. However, if two people attempt to send information at the same time, a collision will occur and all the transmitted data will be lost. Once the collision has occurred, it will continue to be propagated throughout the network by hubs and repeaters. The original information will therefore need to be resent after waiting for the collision to be resolved, thereby incurring a significant wastage of time and resources. To prevent collisions from traveling through all the workstations in the network, a bridge or a switch can be used. These devices will not forward collisions, but will allow broadcasts (to every user in the network) and multicasts (to a pre-specified group of users) to pass through. A router may be used to prevent broadcasts and multicasts from traveling through the network.

The workstations, hubs, and repeaters together form a LAN segment. A LAN segment is also known as a collision domain since collisions remain within the segment. The area within which broadcasts and multicasts are confined is called a broadcast domain or LAN. Thus a LAN can consist of one or more LAN segments. Defining broadcast and collision domains in a LAN depends on how the workstations, hubs, switches, and routers are physically connected together. This means that everyone on a LAN must be located in the same area (see Figure1).

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Figure 1: Physical view of a LAN.

VLAN's allow a network manager to logically segment a LAN into different broadcast domains (see Figure2). Since this is a logical segmentation and not a physical one, workstations do not have to be physically located together. Users on different floors of the same building, or even in different buildings can now belong to the same LAN.

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Physical View

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Logical View

Figure 2: Physical and logical view of a VLAN.

VLAN's also allow broadcast domains to be defined without using routers. Bridging software is used instead to define which workstations are to be included in the broadcast domain. Routers would only have to be used to communicate between two VLAN's [ Hein et al].

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3.0 Why use VLAN's?

VLAN's offer a number of advantages over traditional LAN's. They are:

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4.0 How VLAN's work

When a LAN bridge receives data from a workstation, it tags the data with a VLAN identifier indicating the VLAN from which the data came. This is called explicit tagging. It is also possible to determine to which VLAN the data received belongs using implicit tagging. In implicit tagging the data is not tagged, but the VLAN from which the data came is determined based on other information like the port on which the data arrived. Tagging can be based on the port from which it came, the source Media Access Control (MAC) field, the source network address, or some other field or combination of fields. VLAN's are classified based on the method used. To be able to do the tagging of data using any of the methods, the bridge would have to keep an updated database containing a mapping between VLAN's and whichever field is used for tagging. For example, if tagging is by port, the database should indicate which ports belong to which VLAN. This database is called a filtering database. Bridges would have to be able to maintain this database and also to make sure that all the bridges on the LAN have the same information in each of their databases. The bridge determines where the data is to go next based on normal LAN operations. Once the bridge determines where the data is to go, it now needs to determine whether the VLAN identifier should be added to the data and sent. If the data is to go to a device that knows about VLAN implementation (VLAN-aware), the VLAN identifier is added to the data. If it is to go to a device that has no knowledge of VLAN implementation (VLAN-unaware), the bridge sends the data without the VLAN identifier.

In order to understand how VLAN's work, we need to look at the types of VLAN's, the types of connections between devices on VLAN's, the filtering database which is used to send traffic to the correct VLAN, and tagging, a process used to identify the VLAN originating the data.

VLAN Standard: IEEE 802.1Q Draft Standard

There has been a recent move towards building a set of standards for VLAN products. The Institute of Electrical and Electronic Engineers (IEEE) is currently working on a draft standard 802.1Q for VLAN's. Up to this point, products have been proprietary, implying that anyone wanting to install VLAN's would have to purchase all products from the same vendor. Once the standards have been written and vendors create products based on these standards, users will no longer be confined to purchasing products from a single vendor. The major vendors have supported these standards and are planning on releasing products based on them. It is anticipated that these standards will be ratified later this year.

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4.1 Types of VLAN's

VLAN membership can be classified by port, MAC address, and protocol type.

Port VLAN
1 1
2 1
3 2
4 1

Figure3: Assignment of ports to different VLAN's.

MAC Address VLAN
1212354145121 1
2389234873743 2
3045834758445 2
5483573475843 1

Figure4: Assignment of MAC addresses to different VLAN's.

Protocol VLAN
IP 1
IPX 2

Figure5: Assignment of protocols to different VLAN's.

IP Subnet VLAN
23.2.24 1
26.21.35 2

Figure6: Assignment of IP subnet addresses to different VLAN's.

The 802.1Q draft standard defines Layer 1 and Layer 2 VLAN's only. Protocol type based VLAN's and higher layer VLAN's have been allowed for, but are not defined in this standard. As a result, these VLAN's will remain proprietary.

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4.2 Types of Connections

Devices on a VLAN can be connected in three ways based on whether the connected devices are VLAN-aware or VLAN-unaware. Recall that a VLAN-aware device is one which understands VLAN memberships (i.e. which users belong to a VLAN) and VLAN formats.

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Figure7: Trunk link between two VLAN-aware bridges.

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Figure 8: Access link between a VLAN-aware bridge and a VLAN-unaware device.

pic5.gif

Figure9: Hybrid link containing both VLAN-aware and VLAN-unaware devices.

It must also be noted that the network can have a combination of all three types of links.

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4.3 Frame Processing

A bridge on receiving data determines to which VLAN the data belongs either by implicit or explicit tagging. In explicit tagging a tag header is added to the data. The bridge also keeps track of VLAN members in a filtering database which it uses to determine where the data is to be sent. Following is an explanation of the contents of the filtering database and the format and purpose of the tag header [802.1Q].

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Figure10: Active topology of network and VLAN A using spanning tree algorithm.

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Figure11: Ethernet frame tag header.

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Figure12: Token ring and FDDI tag header.

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Figure13: Tag control information (TCI).

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5.0 Summary

As we have seen there are significant advances in the field of networks in the form of VLAN's which allow the formation of virtual workgroups, better security, improved performance, simplified administration, and reduced costs. VLAN's are formed by the logical segmentation of a network and can be classified into Layer1, 2, 3 and higher layers. Only Layer 1 and 2 are specified in the draft standard 802.1Q. Tagging and the filtering database allow a bridge to determine the source and destination VLAN for received data. VLAN's if implemented effectively, show considerable promise in future networking solutions.

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6.0 References

1) David Passmore, John Freeman, ``The Virtual LAN Technology Report,'' March 7, 1997, http://www.3com.com/nsc/200374.html
A very good overview of VLAN's, their strengths, weaknesses, and implementation problems.

2) IEEE, ``Draft Standard for Virtual Bridge Local Area Networks,'' P802.1Q/D1, May 16, 1997,
This is the draft standard for VLAN's which covers implementation issues of Layer 1 and 2 VLAN's.

3) Mathias Hein, David Griffiths, Orna Berry, ``Switching Technology in the Local Network: From LAN to Switched LAN to Virtual LAN,'' February 1997,
Textbook explanation of what VLAN's are and their types.

7) Susan Biagi, "Virtual LANs," Network VAR v4 n1 p. 10-12, January 1996,
An Overview of VLAN's, advantages, and disadvantages.

8) David J. Buerger, ``Virtual LAN cost savings will stay virtual until networking's next era,'' Network World, March 1995,
A short summary on VLAN's.

9) IEEE, ``Traffic Class Expediting and Dynamic Multicast Filtering,'' 802.1p/D6, April 1997,
This is the standard for implementing priority and dynamic multicasts. Implementation of priority in VLAN's is based on this standard.

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7.0 Abbreviations

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Last Modified: August 14, 1997