Tactical Air Navigation

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VORTAC TGO (TANGO) Germany. The TACAN antenna is the highest antenna in the center of the image.
VORTAC TGO (TANGO) Germany. The TACAN antenna is the highest antenna in the center of the image.

TACtical Air Navigation, or TACAN, is a navigation system used by military aircraft. It provides the user with a distance and bearing from a ground station. It is a more accurate version of the VHF omnidirectional range / Distance Measuring Equipment (VOR/DME) system that provides range and bearing information for civil aviation. At VORTAC facilities, the DME portion of the TACAN system is available for civil use.

Contents

[edit] Operation

A US Air Force TACAN Antenna.
A US Air Force TACAN Antenna.

TACAN in general can be described as the military version of the VOR/DME system. It operates in the frequency band 960-1215 MHz. The bearing unit of TACAN is more accurate than a standard VOR since it makes use of a two frequency principle, with 15 Hz and 135 Hz components.

The distance measurement component of TACAN operates with the same specifications as do civil DMEs. Therefore to reduce the number of required stations, TACAN stations are frequently co-located with VOR facilities. These co-located stations are known as VORTACs. This is a station composed of a VOR for civil bearing information and a TACAN for military bearing information and military/civil distance measuring information. The TACAN transponder performs the function of a DME without the need for a separate, collocated DME. Because the rotation of the antenna creates a large portion of the azimuth signal, if the antenna fails, the azimuth component is no longer available and the TACAN downgrades to a DME only mode.

[edit] Accuracy

Theoretically a TACAN should provide a ninefold increase in accuracy compared to a VOR but operational use has shown only a 1.5 to 2 fold increase.[citation needed]

Accuracy of the 135 Hz azimuth component is ±1° or ±63 m at 3.47 km.[1] Accuracy of the DME portion is 185 m (±0.1 nautical mile).[1]

[edit] Benefits

TACAN antenna at Shemya, Alaska.
TACAN antenna at Shemya, Alaska.

Because the azimuth and range units are combined in one system it provides for simpler installation. Less space is required than a VOR because a VOR requires a large counterpoise and a fairly complex phased antenna system. A TACAN system theoretically might be placed on a building, a large truck, an airplane, or a ship, and be operational in a short period of time. TACAN, for example, are used on air refueling tankers.

[edit] Drawbacks

A shipboard TACAN antenna on USS Raleigh (LPD-1) with a lightning rod extending above it.
A shipboard TACAN antenna on USS Raleigh (LPD-1) with a lightning rod extending above it.

For military usage a primary drawback is lack of the ability to control emissions (EMCON) and stealth. Naval TACAN operations are designed so an aircraft can find the ship and land. There is no encryption involved, an enemy can simply use the range and bearing provided to attack a ship equipped with a TACAN. Some TACANs have the ability to employ a "Demand Only" mode wherein they will only transmit when interrogated by an aircraft on-channel. It is likely that TACAN will be replaced with a differential GPS system similar to the Local Area Augmentation System called JPALS. The Joint Precision Approach and Landing System has a low probability of intercept to prevent enemy detection and an aircraft carrier version can be used for autoland operations.

Some systems used in the United States modulate the transmitted signal by using a 900 RPM rotating antenna. Since this antenna is fairly large and must rotate 24 hours a day, it can cause reliability issues. Modern systems have antennas that use electronic rotation (instead of mechanical rotation) and have no moving parts.

[edit] Future

Like all other forms of aircraft radio navigation currently used, it is likely that TACAN will be replaced by some form of space based navigational system such as GPS.[2]

[edit] See also

[edit] References

  1. ^ a b Department of Transportation and Department of Defense (March 25, 2002). 2001 Federal Radionavigation Systems (PDF). Retrieved on November 27, 2005.
  2. ^ Department of Transportation and Department of Defense (March 25, 2002). 2001 Federal Radionavigation Plan (PDF). Retrieved on August 2, 2006.

[edit] External links

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