Distributed antenna system

A diagram contrasting a single antenna configuration with DAS
A typical DAS node for the Videotron 3G network in Montreal, Quebec
DAS deployed by Transit Wireless in New York City Subway to provide WiFi, cellular voice and data coverage. The RF node with three antennas at the platform and another antenna near the stairs on the far side.

A distributed antenna system, or DAS, is a network of spatially separated antenna nodes connected to a common source via a transport medium that provides wireless service within a geographic area or structure. DAS antenna elevations are generally at or below the clutter level and node installations are compact. A distributed antenna system may be deployed indoors (an iDAS) or outdoors (an oDAS).

Concept

As illustrated in the figure, the idea is to split the transmitted power among several antenna elements, separated in space so as to provide coverage over the same area as a single antenna but with reduced total power and improved reliability. A single antenna radiating at high power (a) is replaced by a group of low-power antennas to cover the same area (b). The idea was described in a paper by Saleh et al.[1] in 1987. These antennas have recently been employed by several service providers in many areas around the United States. DAS is often used in scenarios where alternate technologies are infeasible due to terrain or zoning challenges.

The idea works because less power is wasted in overcoming penetration and shadowing losses, and because a line-of-sight channel is present more frequently, leading to reduced fade depths and reduced delay spread.

A distributed antenna system can be implemented using passive splitters and feeders, or active-repeater amplifiers can be included to overcome the feeder losses. In systems where equalization is applied, it may be desirable to introduce delays between the antenna elements. This artificially increases delay spread in areas of overlapped coverage, permitting quality improvements via time diversity.

If a given area is covered by many distributed antenna elements rather than a single antenna, then the total radiated power is reduced by approximately a factor N1–n/2 and the power per antenna is reduced by a factor Nn/2 where a simple power-law path-loss model with path-loss exponent n is assumed. As an alternative, the total area covered could be extended for a given limit of effective radiated power, which may be important to ensure compliance with safety limits on radiation into the human body.

Precursors

Prior to the invention by Saleh et al., tunnel transmitters and leaky feeders had been used to provide radio reception in tunnels, mines, subway lines, and other indoor and underground spaces.

Use in WiFi networks

Using a distributed antenna system to create an area of wireless coverage, it is possible to use this technique to propagate indoor WiFi for commercial uses. It is estimated that only about 5% of commercial WiFi use a distributed antenna system.[2]

Placement of Distributed Antenna Systems

Distributed Antenna Systems may be placed inside buildings for increasing wireless signals within buildings. Often they are placed within large structures such as stadiums or corporate headquarters.

Systems are also placed in the utility right of way on top of utility poles, street light poles and traffic signal poles.

Regulations

Historical regulatory challenges arise at the federal, state and municipal levels. However, regulations have been getting promulgated at the State and Federal level, with midwest states leading the way with state level regulations. Academic works address this.[3] [4] Other industry resources like The DAS Forum also address regulatory issues in their conferences. More details can be found on their website.[5]

Federal Communications Commission Rules: The FCC has promulgated the FCC Pole Attachment Order 11-50 [6]

Michigan: The METRO Authority, which regulates access to the utility right of way determined in 2004 that Distributed Antenna Network Systems are part of the landline infrastructure, and hence are subject to state regulation via a administrative determination.[7]

Ohio: The Ohio Public Utility Commission has issued a pole attachment rulings which require utility to allow Distributed Antenna Systems in the utility right of way in August 2014.

See also

References

  1. A. A. M. Saleh, A. J. Rustako and R. S. Roman, Distributed Antennas for Indoor Radio Communications, IEEE Transactions on Commun., vol. 35, pp. 1245-1251, Dec. 1987
  2. "Estimate made by LComm Global". Lcommglobal.com. Retrieved 2012-10-24.
  3. "Establishing a Regulatory Framework for Distributed Antenna Systems". Ssrn.com. Retrieved 2012-10-24.
  4. "Distributed Antenna Systems - Establishing a Regulatory Framework Available". Amazon.com. Retrieved 2012-10-24.
  5. "The Distributed Antenna Systems Online Community". The DAS Forum. 2012-08-17. Retrieved 2012-08-22.
  6. "FCC Order 11-50". FCC. Retrieved 2014-09-25.
  7. "Metro Authority Determination Number 1". www.michigan.gov. Retrieved 2014-09-24.
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