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Reality Check – Wireless Lessons from the Real-World

In the process of distributing wireless to a geographic area it is often necessary to place transceivers out of doors. In doing so a prudent designer understands that one cannot afford to overlook the effects of the environment on the life of the equipment and the performance of the wireless system.

The major environmental effects include;

• Weather related precipitation in the form of rain, snow, ice and fog
• The seasonal effects on propagation of signal and equipment reliability
• Electromagnetic interference caused by machinery, power distribution or other nearby transponders
• Local topography and site structures

Weather related precipitation in the form of rain, snow, ice and fog is often overlooked due to the common belief and correct understanding that precipitation has little effect at the most used frequencies. In fact, falling rain and snow does not become a real problem until around 10 GHz and above. Fog starts to be an issue at around 20 GHz. The more common 2.4 GHz signals may be attenuated only up to 0.05 dB/km (0.08 dB/mile) by torrential rain (4 inches/hr). Thick fog produces up to 0.02 dB/km (0.03 dB/mile) attenuation. At 5.8 GHz, torrential rain may produce up to 0.5 dB/km (0.8 dB/mile) attenuation, and thick fog up to 0.07 dB/km (0.11 dB/mile).

As you can see these rain attenuation numbers are very small for the commonly available frequencies. I am as willing as anyone else to call these low numbers unimportant but falling rain is not the whole story.

Standing liquid / condensation is the collection of rain, snow or dew. Even though rain itself may not cause major propagation problems, rain, dew, or snow will collect on the leaves of trees and other surfaces and will produce noticeable attenuation, up to 3dB at 2.4 GHz or half power, until it evaporates.

Sheeting liquid describes rain falling off of eaves, roofs, gutters or other structures. Sheeting is of particular concern if it is near the transponder - for even a light rain or snow melt off a medium sized roof can cause a major amount of attenuation of the signal, in excess of 20 dB at 2.4 GHz is not uncommon. Sheeting is best avoided by careful antenna positioning with regards to structure.

Even in small amounts, ice or snow buildup on antenna can be a major problem for both attenuating signal and changing the characteristics of the antenna. Careful selection of equipment is very important because some surfaces and materials are better at shedding liquids than others. An antenna that performs well in Arizona may have disappointing results in Michigan.

Often overlooked are the effects of rain snow and ice on the life and severability of equipment. Water may find a way into connectors and equipment. If allowed to do so, water may short out or cause corrosive damage to connectors and equipment. Once it freezes, water will cause ice expansion which can crack housings, allowing for more water to enter. In many cases, standard “weather proofing” or equipment which is “weather proofed” may not be enough. Equipment can be selected which is rated against a standard other than “weather hardened” or “ruggedized“. Selection against a recognized standard along with other environmental specific techniques gives the network designer a proofed solution to the problem of moisture.

Be aware in both radio and network equipment - degradation usually precedes break down. Network monitoring and scheduled maintenance are the best protections against the effects of the environment in any given location.

Conclusion:

At most commonly used frequencies the effects of precipitation are more damaging than the precipitation itself. A prudent designer will identify these and other like issues in his plan and employ a regiment of technologies and methods to overcome problems associated with the environmental conditions of a specific geographical area.

Equipment selection against a recognized standard, equipment placement with regard to structure and various weatherproofing techniques are necessary. Vigilance to the network condition, if possible in real-time, as well as an effective maintenance schedule are invaluable.

John Welch is a Senior Wireless Systems Engineer at Apprion. John has over thirty years experience in technology and engineering with RF, digital and analog devices and various wireless communication and video systems. He brings over 12 years of specialized wireless implementation and design experience with industrial, metropolitan and military wireless infrastructures and systems. Implementations to date include a last mile point to point wireless system under the 802.11 and 802.16 standards, a metropolitan wireless 802.11 deployment in the Auckland, New Zealand central business district and numerous industrial wireless network implementations at oil/gas, chemical and power facilities. In addition, John has developed patents and new inventions for wireless networking systems, antenna design and deployment methodologies.

 
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Apprion delivers wireless application networks and services for the process manufacturing industry. These wireless application networks are based on Apprion's ION System. Integrated into the ION System are five applications that are core to industrial wireless application networks: Asset Tracking, Communications, Condition Monitoring, Workforce Mobility, and Video.

Whether it is the need to address safety or security concerns, reduce maintenance or material costs, or improve productivity or asset utilization, a wireless application network from Apprion will assure that any wireless application is easier to deploy and manage while delivering value faster, more efficiently. For more information, visit www.apprion.com.

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