Distance measuring equipment

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D-VOR/DME ground station
D-VOR/DME ground station
DME by itself
DME by itself

Distance Measuring Equipment (DME) is a transponder-based radio navigation technology that measures distance by timing the propagation delay of VHF or UHF radio signals.

It was invented by Edward George "Taffy" Bowen whilst employed as Chief of the Division of Radiophysics of the Commonwealth Scientific and Industrial Research Organisation (CSIRO) in Australia. Another Australian world-first, engineered version of the system was deployed by Amalgamated Wireless Australasia Limited in the early 1950s operating in the 200 MHz VHF band. This Australian domestic version was referred by the Federal Department of Civil Aviation as DME(D) (or DME Domestic), and the later international version adopted by ICAO as DME(I).

DME is similar to Secondary Radar, except in reverse. The system was a post-war development of the IFF (Identification Friend or Foe) systems of World War II. To maintain compatibility, DME is functionally identical to the distance measuring component of TACAN.

Contents

[edit] Operation

Aircraft use DME to determine their distance from a land-based transponder by sending and receiving pulse pairs - two pulses of fixed duration and separation. The ground stations are typically colocated with VORs. A typical DME ground transponder system for enroute or terminal navigation will have a 1 kW peak pulse output on the assigned UHF channel.

A low power DME can also be colocated with an ILS localizer where it provides an accurate distance function, similar to that otherwise provided by ILS Marker Beacons.

[edit] Hardware

The DME system is composed of a UHF transmitter/receiver (interrogator) in the aircraft and a UHF receiver/transmitter (transponder) on the ground.

[edit] Timing

The aircraft interrogates the ground transponder with a series of pulse-pairs (interrogations), The ground station replies with an identical sequence of reply pulse-pairs with a precise time delay (typically 50 microseconds). The DME receiver in the aircraft searches for pulse-pairs (X-mode= 12 microsecond spacing) with the correct time interval between them. The correct time between pulse pairs is determined by each individual aircraft's particular interrogation pattern. The aircraft interrogator locks on to the DME ground station once it understands that the particular pulse sequence is the interrogation sequence it sent out originally. Once the receiver is locked on, it has a narrower window in which to look for the echoes and can retain lock.

[edit] Distance calculation

A radio pulse takes around 12.36 microseconds to travel one nautical mile to and from, this is also referred to as a radar-mile. The time difference between interrogation and reply minus the 50 microsecond ground transponder delay is measured by the interrogator's timing circuitry and translated into a distance measurement in nautical miles which is then displayed in the cockpit.

[edit] Specification

A typical DME transponder can provide concurrent distance information to about 100 aircraft.[1] Above this limit the transponder avoids overload by limiting the gain of the receiver. Replies to weaker more distant interrogations are ignored to lower the transponder load.

[edit] Radio frequency and modulation data

DME frequencies are paired to VHF omnidirectional range (VOR) frequencies. A DME interrogator is designed to automatically tune to the corresponding frequency when the associated VOR is selected. An airplane’s DME interrogator uses frequencies from 1025 to 1150 MHz. DME transponders transmit on a channel in the 962 to 1150 MHz range and receive on a corresponding channel between 962 to 1213 MHz. The band is divided into 126 channels for interrogation and 126 channels for transponder replies. The interrogation and reply frequencies always differ by 63 MHz. The spacing of all channels is 1 MHz with a signal spectrum width of 100 kHz.

Technical references to X and Y channels relate only to the spacing of the individual pulses in the DME pulse pair, 12 microsecond spacing for X channels and 36 microsecond spacing for Y channels.

DME facilities identify themselves with a 1350 Hz morse code three letter identity. If collocated with a VOR or ILS it will have the same identity code as the parent facility. Additionally, the DME will identify itself between those of the parent facility. DME identity is 1350 Hz to differentiate itself from the 1020 Hz tone of the VOR or the ILS localizer.

[edit] Accuracy

Accuracy of DME is 185 m (±0.1 nm).[1] One important thing to understand is that DME provides the physical distance from the aircraft to the DME transponder. This distance is often referred to as 'slant range' and depends trigonometrically upon both the altitude above the transponder and the ground distance from it.

For example, an aircraft directly above the DME station at 6000 feet altitude would still show one mile on the DME readout. The aircraft technically is a mile away, just a mile straight up. Slant range error is most pronounced at high altitudes when close to the DME station.

[edit] Future

It is likely that DME installations will be phased out when space-based navigational systems such as GPS and Galileo become widely used for aviation.[2] However, the system is still widely used and new beacons are being built and installed still today (June 2007).

[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