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Improving Wireless LAN Range

  

Everyone can improve wireless range and throughput by:
•   Choosing the Best Locations
•   Tuning Your Equipment
•   Choosing the Right Equipment to Upgrade.

Better equipment — such a powerful AP — can provide a quick fix. But the best approach is to work on all three items.

Wireless and Antenna Terms

Wireless routers, access points, and adapters send and receive radio wave signals through antennas. The antenna is hidden inside adapters, but on routers and access points there's a visible antenna. Radio waves can be focussed like a lightbulb. And like a light, some materials reduce or stop radio waves. While light focused from several lights is brighter and makes it easier to see, several antennas in the same area cause interference — the radio signals will be muddy and confused.

Your goals in optimizing power are:
•   Avoid obstacles.
•   Avoid interference.
•   Increase signal strength. Power affects how far an antenna radiates.
•   Use the equipment in places it's most powerful and most sensitive.

Antennas don't radiate equally in every direction. Just as the base of a lightbulb blocks light, and just as a light can be focussed by a reflector, so an antenna signal may be blocked and focused. Since people cannot see radio waves, you'll rely on testing and trial-and-error to get an idea of where antennas "shine" most brightly. An adapter's antenna is important, but the most powerful and sensitive antennas are on routers, access points, and detachable external antennas.

The focus of an antenna is either omni-directional antenna or directional. "Omnis" are used in most home products, they radiate horizontally all around, but are weaker upward or downward. When visible, these antennas are usually a rod a few inches long. A directional antenna radiates strongly in a limited direction. It is a flat panel or a dish. These are used for point-to-point transmissions (where two antennas are focused directly at each another). These need a line of sight between them, and preferably a large open space around the main beam.

When you are near antennas you'll still get a signal, even if you are out of the direction of its strongest signals. But when further away, you have to be in the direction the beam is the most powerful and unobstructed to receive it.

One final concept before you go to the above links is interference. Interference is a signal — one you don't want — at the same frequency as the one you're using. Interference comes from devices such as microwave ovens, cell phones, 2.4 GHz cordless phones, and copy machines. Interference is also caused when your own wireless signals are bounced off reflecting objects. Objects may partly or completely absorb signals, reflect them, bend them, or let them pass right through. Metal and water (including the water in people!) absorb or reflect signals. Air, wood, and glass tend to let signals pass with weakening. And when outdoors, plants and the weather may cause interference.

 


Choosing the Best Locations

 

This describes moving equipment, positioning antennas, and avoiding obstacles. When optimizing your existing equipment, consider:
•   Placing antennas in a good location, at a good angle.
•   Avoiding physical things that block signals.
•   Reducing the interference from other things that transmit radio waves.

Before starting adjustment, make sure that antennas and cables are securely fastened!

If your network has more than a couple wireless devices, before you move things, decide which wireless devices are transmitting the heaviest load. These links are important to optimize. WiFi products have automatic data rate fallback, which allows increased distances without losing connectivity. It also means that devices that are further away are inherently slower. Therefore the most critical links in your network are those where the traffic is high, and the distances are great. Optimize those, first. The ones that are least important are links that have little, occasional traffic, and which have a strong signal strength.

Picking Good Locations for Antennas
•   Antennas should be in line-of-sight of one another, where possible. Put your face next to one antenna, to find whether the other is visible.
•   Place high, and clear of obstructions as practical.
•   Keep antennas 60 cm from metal fixtures such as sprinklers, pipes, metal ceiling, reinforced concrete, metal partitions. (However, antennas on roofs do not necessarily give the best results. )
•   Keep away from large amounts of water such as fish tanks and water coolers.
•   Antennas transmit weakly at the base, where they connect. So don't expect good reception from the bottom of a router or access point.
•   For multi-story buildings, placing antennas at 45 degrees (diagonally) or 0 degrees (straight out parallel to the floor) may be most effective.

Reducing Interference

Avoid windows unless communicating between buildings. (Windows let in interference from the outside world.)

Place antennas away from various electromagnetic noise sources, especially those in the 2400 – 2500 MHz frequency band.
Common noise-creating sources are:
•   Computers and fax machines (place wireless equipment no closer than 30 cm)
•   Copying machines, elevators and cell phones (no closer than 2 meter)
•   Microwave ovens (no closer than 3 meter)

 


Tuning Equipment

 

Using the best channels has a big effect on network performance. Your goal is to choose settings that avoid interference from other networking and radio frequency equipment.

If you have a simple home network, and aren't close to neighbors with wireless equipment, you may be lucky enough just to choose between many channels that work well.

Complications arise when:
•   You want much better coverage than you're getting.
•   You use multiple access points or wireless routers. (Then you'll probably be using more than one channel.)
•   You aren't the only person nearby running a wireless network.

Simple Spacing of Channels

As explained, improving signal strength is not like adding more lights to get a brighter livingroom. Devices that transmit powerfully — such as routers, access points, and cell phone base stations — confuse one another. It's necessary to distance them and to have them use different channels.

For 802.11b and 802.11g, there are 13 channels for wireless equipment. In the simple situation where there's little interference, you can choose any channel that works for you. When there is interference from wireless networks that overlap with one another, each network should use one of the non-overlapping channels: 1, 6, or 11 (1, 7, 13 in Europe). Then, 3 networks can use the same space with minimum interference. If you can't do that, choose channels as widely spaces as possible.

What If a Channel I Want to Use Has Too Much Noise (Interference)?

If your neighbor has a wireless network, it wouldn't be surprising that they are already using channel 1 and channel 11. Unfortunately, you can't completely avoid interference just by using other channels. Wireless protocols 802.11b and 11g only have 3 non-overlapping channels. Therefore when 4 or more channels are used in the same area, the level of interference can increase notably. If you and your close neighbor both have a router and a wireless access point, for example — which makes a total of four powerful transmitters — both of you will have a certain amount of interference.

You can use a combination of access points and antennas and other equipment to create local "spotlights" of strong transmission, rather than trying to cover everywhere.

If there's a severe problem, a practical and sociable thing is to talk to your neighbors using wireless networks that can be seen when you scan. Together, you can choose optimal channels for your respective networks. You'll want your own channels at least 5 apart. So, for example, you could use channels 1 and 8, and your neighbor could use 5 and 11.

You may be able to place routers and access points further away inside your homes. After all, the kinds of physical barriers that reduce your transmission range also reduce the signal that your neighbor doesn't want to see.

If you can use a directional antenna, or an antenna cable to shift an antenna, that can help you both.

Super G technology is faster, but it uses two, non-configurable channels. Therefore it may not be possible to pick other channels that avoid its interference.

Reducing Wireless Network Traffic

When there's noise, your network performance drops, so one approach is not to stop the noise, but to reduce the amount of network data being transmitted.

In a noisy environment, it may be useful to keep part of your network wired. If Ethernet cabling isn't an option, consider Powerline products — using existing home wiring instead of cables.

When SSID Broadcast is turned on, it's easiest for equipment to find the strongest signal. However this also causes network overhead. When the SSID is broadcast, your neighbor's equipment may keep a record of it, and automatically try to connect several times a second; this can cause significant performance reduction. So where there are close networks, turn off SSID Broadcast, and change the default SSID.

Turning off WEP and WPA may increase network throughput, but exposes your network to hackers. This is not recommended, except for testing purposes.

 


Choosing the Right Equipment

 

This section is useful:
•   To compare how various wireless devices should be used, or
•   If Choosing the Best Locations and Tuning Your Equipment don't get the performance you want, or
•   You want a big improvement immediately at a reasonable cost.

The cheaper solutions are first, followed by more expensive, but very powerful ones. A network with more than a few computers may benefit from a combination of approaches.

     I. A New Router 
     II. A Second Router as a Wireless Access Point 
     III. Powerline 
     IV. An Access Point 
     V. An Antenna 
     VI. Bi-directional Amplifier
     VII. A Site Survey

I. A New Router

Replace your existing router with a better one. This is recommended if your router is a couple years old. A new router will probably double your coverage in a single area.

Advantages
•   Making the change is likely to be simple.

Disadvantages
•   May require you to also buy new adapters to get all the router benefits.
•   Isn't best for difficult environments with spotty coverage, or for covering large areas such as entire buildings.

II. A Second Router to use as a Wireless Access Point

With this solution you disable features of a wireless router, leaving the wireless transmitter working. This configuration uses an existing wired or wireless router.

Advantages
•   Low cost. With an inexpensive router, this is the cheapest solution.

Disadvantages
•   Only suitable for small, moderately loaded networks. E.g., not good for running a game server or a database server.
•   Can be slightly difficult to configure.

III. Powerline

Instead of networking through the air, or through Ethernet cables, Powerline uses the existing electrical wires in your walls.

Advantages
•   Fairly low cost.
•   Excellent solution in difficult RFI environments, since Powerline signals don't go through the air.
•   Good security for casual users.
•   Powerline can easily be moved in a house. No reconfiguration is needed, units can be plugged in where and when you want.
•   Doesn't require continuous wireless coverage, just an available electrical plug.
•   Works nicely with wireless technology to cover "blind spots".

Disadvantages
•   Powerline performance is not limited by RFI, but it is limited by noisy power. As with wireless, it's difficult to know exactly how well Powerline will work until you try it.
•   Powerline is often not suitable for businesses, dorms, and hotels.

IV. An Access Point

Dedicated access points have better performance and features than routers that are used as access points.

Advantages
•   Can cover an area far distant from your wireless router, without having to cover all the area in between.
•   Potentially excellent LAN performance, especially with careful configuration and placement.
•   Advanced security features.

Disadvantages
•   Business access
•   Using access points in repeater mode does not result in the best performance.
•   Configuration is more complicated than other solutions.

V. Antennas

Antennas can provide great power.  Antennas and boosters are available that transmit for tens of kilometers. Less powerful antennas may still cover an entire building.

Advantages
•   Antennas give excellent throughput over large continuous areas.
•   Antennas are available for outdoor, as well as indoor use.
•   Antennas are often the most practical solution for networking between buildings.

Disadvantages
•   Antennas must be connected to equipment specifically designed for them. This adds to cost.
•   A site survey may be needed before installation. (See below.)
•   Antennas may require professional installation. This adds to cost.
•   In thunderstorms, connections may be slow or temporarily interrupted. Critical networking or networking in areas of frequent storms may require other network connections as a backup.
  

VI. Bi-directional Amplifiers

Amplifiers give about 10 dB to 20 dB extra transmit power for the Wireless LAN network significantly increasing the range of the network by three to fifteen times.
Bi-directional amplifiers consist:
•   Transmit path provides highly linear gain of 17 to 23 dB.
•   Low Noise Amplifier with signal gain of 12 dB to 20 dB improves the receive sensitivity of radio, while keeping noise level very low.
•   Receive Filtering. A band pass filter in receive path of the amplifier gives added protection against out of band noise. 

Advantages
 •  Increased network throughput and far reliable connection.

Disadvantages
 •   Possibility of interference with adjacent wireless LAN networks.


VII. A Site Survey

A site survey is a study of your environment, your network, and your computing needs. Self-help site survey software is available, but a complete evaluation requires a professional. For a network of more than a few computers, plan on using 1-2 hours of help in the range of €100-€150 / hour. For all but small networks using the cheaper approaches described above, the amount spent will be saved by avoiding buying wrong equipment, or equipment that isn't cost-effective in your situation.