The last decade of the 20th century witnessed

the use of Internet.

The first decade of the 21st century has seen

the rise of wireless connectivity.

Wireless networking is now commonplace mobile

connectivity is becoming a rule, not an exception.

But getting there was not as easy as it may seem

today.

Wireless networking requires a basic understanding

of the world of Radio Frequency (RF) where

concepts like channel planning, cell sizes and

frequency reuse are the norm.

In this white paper, we have discussed the

three phases of WLAN architecture evolution i.e.

WLAN for convenience (limited adoption),

WLAN as the network of choice (instead of wires)

and WLAN for business critical applications.

We have also compared legacy microcell architectures

to Meru's Air Traffic Control architecture and

provided guidance on selection of the right

architecture.

Phase 1: Infancy "Wireless LAN Network of Convenience"

In early 2000, wireless LANs were deployed in a

limited fashion to enable convenient mobile access for

workers with laptops, without the need to plug into

the network. For many networks the primary application

was casual access to email and the Internet,

for both guests and employees.

The solution to this problem was groundbreaking:

plug in wireless access points (APs),

wherever network access was needed.

These access points were deployed in standalone mode

for providing connectivity to a few users.

Soon the demand on the network increased as more

and more users wanted to use the standalone access

point for wireless access. Adding access points

to improve the coverage area and capacity required

careful selection of non-overlapping channels to avoid

interference between access points.

IEEE 802.11 APs operate in an unlicensed RF

spectrum-specifically, the 2.4GHz and 5GHz Industrial,

Science, and Medicine (ISM) bands.

The 2.4 GHz band is also used by microwave ovens,

cordless phones and many other wireless devices.

This band is divided up into three distinct,

non-overlapping channels, known as channels 1, 6 and 11.

APs operating physically close to each other and on the

same channel interfere with one another.

Adding more APs to boost capacity causes interference

between new and old APs and actually reduces the overall

aggregate capacity of the network. One approach to

avoiding co-channel interference was to follow the

typical hexagonal cell tiling model,

borrowed from the cellular world, which allows the

three channels to be separated as far as physically

possible.

Phase 2:

Adolescence "Wireless LAN-Network of Extending Coverage"

Microcells Enable Enterprise Wireless Adolescence In 2004,

IEEE 802.11g enterprise grade WLAN access points were

introduced to the market.

OFDM-based 802.11g operates at a maximum raw data rate

of 54 Mbps but has the same number of non-overlapping

channels as 802.11b.

The 802.11g standard provided some increase in available

throughput but was not enough to meet the growing

requirements of the wireless network.

Most 802.11g access points delivered 22-27Mbps.

The hexagon tiling approach worked to a certain point.

In 2004-2005, the wireless network usage model began

to shift from one of casual access, to one in which

wireless is used for providing connectivity in areas

where it was not possible to draw wires.

This made WLAN access an integral part of the

enterprise-network, now for business critical operations.

The number of users on the network started increasing and

it was no longer possible to meet the requirement of a

growing network using the hexagonal tiling approach

alone.

Hexagonal tiling was combined with limiting the access

point power settings in the microcell approach since a

microcell is basically a smaller cell-created by turning

down the power level of the radio.

Smaller cells mean that more APs can be packed into the

building without increasing the interference since the

relative distances between the APs stay the same.

Microcells,

while solving the capacity issue to some extent,

introduce several other problems in the network such

as latency due to frequent hand-offs,

interference from non-802.11 devices,

and more coverage holes.

Most importantly, it increases the number of APs by

20 which has a direct impact on the cost of the

WLAN infrastructure.

Trade-off between coverage holes and load-balancing

To provide ubiquitous access,

coverage holes need to be filled.

One approach is to selectively increase the power levels

of the cells

wherever coverage holes are detected. This results in

irregular hexagonal tiling pattern and makes it difficult

to use dynamic RF load balancing features.

RF load balancing features were first introduced in the

products so that the RF environment could readjust itself

if interference occurred. But if the coverage of some

access points are selectively adjusted to eliminate

dead spots,

dynamic RF load balancing can not function properly.

So, either RF load balancing is disabled or coverage

holes are ignored.

Smaller cells result in more frequent handoffs between

cells.

While frequent hand-off does not affect data clients,

latency significantly disrupts for voice communication.

The more APs a client sees, the more they may choose to

hand off-especially if the loads on the APs vary.

Signal resiliency is sacrificed

Lower signal strength reduces the signal-to-noise ratio,

allowing interference from other 802.11 sources and

non-802.11 sources (such as Bluetooth and microwave ovens)

to become more disruptive to the network.

The microcell architecture results in 20-30% more APs.

While it serves the vendors selling this architecture well,

it significantly increases the cost of the equipment

(more access points as well as bigger controllers),

channel planning and design, and post deployment

RF channel management issues.

Phase 3: WLAN : Network of Choice

Air Traffic Control: The Solution for Mature Enterprise

WLANs

Air Traffic Control addresses the problems that legacy

microcell architectures are unable to solve.

Air Traffic Control has several elements, each designed

to overcome a problem introduced by the microcell

deployments.

Virtual Cells

Instead of attempting to avoid co-channel interference

between channels as in a microcell architecture,

the Air Traffic Control architecture uses the Virtual

Cell to eliminate co-channel interference by placing

all access points on one channel span and letting the

controller control a fully-coordinated,

distributed architecture.

To a client, all APs appear as one.

All APs are placed on the same channel with the

same Basic Service Set Identifier (BSSID),

as opposed to each AP having its own unique BSSID.

With the Virtual Cell,

co-channel interference elimination works to negate the

effects of the overlap by taking advantage of it instead

of avoiding it.