2 wireless lan layout considerations, 1 coverage, 1 overlapping coverage – Polycom H340 User Manual

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Deploying SpectraLink e340, h340 and i640 Wireless Telephones

BEST PRACTICES GUIDE

October 2010

2 Wireless LAN Layout Considerations

SpectraLink handsets utilize a Wi-Fi network consisting of WLAN access points (APs) distributed throughout a

building or campus. The required number and placement of APs in a given environment is driven by multiple factors,

including intended coverage area, system capacity, access point type, power output, physical environment, and radio

types.

2.1 Coverage

One of the most critical considerations in deployment of SpectraLink handsets is to ensure sufficient wireless

signaling coverage. Enterprise Wi-Fi networks are often initially laid out for data applications and may not provide

adequate coverage for voice users. Such networks may be designed to only cover areas where data devices are

commonly used, and may not include coverage in other areas such as stairwells, break rooms or building entrances

– all places where telephone conversations are likely to occur.

The overall quality of coverage is more important for telephony applications. Coverage that may be suitable for data

applications may not be seamless enough to support the requirements of VoWLAN. Most data communication

protocols provide a mechanism for retransmission of lost or corrupted packets. Delays caused by retransmissions

are not harmful, or even discernable, for most data applications. Likewise, data applications will typically tolerate

more retries than voice applications, as the useful life of a voice packet is short. However, the real-time nature of a

full-duplex telephone conversation requires that voice packets be received correctly within tens of milliseconds of

their transmission. There is little time for retransmission, and lost or corrupted packets must be discarded after

limited retries. In areas of poor wireless coverage, the performance of data applications may be acceptable due to

retransmission of data packets, but for real-time voice, audio quality will likely suffer.

Another factor to consider when determining the coverage area is the device usage. Wireless telephones are used

differently than wireless data devices. Handset users tend to walk as they talk, while data users are usually

stationary or periodically nomadic. Wireless voice requires full mobility while data generally requires simple

portability. Wireless handsets are typically held close to the user’s body, introducing additional radio signal

attenuation. Data devices are usually set on a surface or held away from the body. The usage factor may result in

reduced range for a wireless telephone as compared with a data device. Therefore, the WLAN layout should account

for some reduction of radio signal propagation.

2.1.1 Overlapping Coverage

Wi-Fi cell overlap must be considered when planning your VoWLAN deployment. Handsets make a determination to

roam in less than half the overlapping coverage area. Therefore, the coverage area must be adequate enough so

that when a voice user is moving, the handset has time to discover the next AP before signal on the existing AP

becomes too weak.

A properly designed Wi-Fi network will position APs with sufficient overlapping coverage to ensure there are no

coverage gaps, or “dead spots”, between them. The result is seamless handoff between APs and excellent voice

quality throughout the facility. Sufficient overlapping coverage is usually considered 15% to 20% signal overlap

between AP cells in a deployment utilizing maximum transmit power for both handsets and APs. Smaller cells will

need larger overlaps due to the potential for much smaller cell size which causes a decrease in overall overlap from

a maximum transmit power deployment. The 15% to 20% of signal overlap between AP cells generally works well

with a typical walking speed of the user (the average walking speed of an individual is 3 mph). If the speed of the

moving user is greater (such as a golf cart, fork lift or running/jogging) then a different overlap strategy may be

necessary for successful handoff between APs.

The WLAN layout must factor in the transmission settings that are configured within the APs. The transmission of

voice requires relatively low data rates and a small amount of bandwidth compared to other applications. The 802.11

standard includes automatic rate switching capabilities so that as a user moves away from the AP, the radio adapts

and uses a less complex and slower transmission scheme to send the data. The result is increased range when

operating at reduced transmission data rates. When voice is an application on the WLAN, APs should be configured