Acoustic location

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Acoustic location is the art and science of using sound to determine the distance and direction of something. Location can be done actively or passively, and can take place in gases (such as the atmosphere), liquids (such as water), and in solids (such as in the earth).

  • Active acoustic location involves the creation of sound in order to produce an echo, which is then analysed to determine the location of the object in question.
  • Passive acoustic location involves the detection of sound or vibration created by the object being detected, which is then analysed to determine the location of the object in question.

Both of these techniques, when used in water, are known as sonar; passive sonar and active sonar are both widely used.

Acoustic mirrors and dishes, when using microphones, are a means of passive acoustic localisation, but when using speakers are a means of active localisation. Typically, more than one device is used, and the location is then triangulated between the several devices.

Acoustic location in air was used from mid-WWI to the early years of WWII for the passive detection of aircraft by picking up the noise of the engines. It was rendered obsolete before and during WWII by the introduction of radar, which was far more effective but interceptable. Acoustics has the advantage that it can see round corners and over hills.


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[edit] Active / Passive locators

Active locators have some sort of signal generation device, in addition to a listening device. The two devices do not have to be located together.

[edit] Sonar

SONAR (SOund Navigation And Ranging) — or sonar — is a technique that uses sound propagation under water (or occasionally in air) to navigate, communicate or to detect other vessels. There are two kinds of sonar — active and passive - the former often being used for active localisation and the latter often for passive localisation. An single active sonar can localise in range and bearing as well as measuring radial speed. However, a single passive sonar can only localise in bearing directly, though target motion analysis can be used to localise in range, given time. Multiple passive sonars can be used for range localisation by triangularisation or correlation, directly.

For more information on this item, see the article on Sonar.

[edit] Biological echo location

Dolphins and whales are well known for their use of echolocation. Bats are also famous for their use of echolocation. For more information of this item, see the article on animal echolocation.

[edit] ToA Localization

Having speakers/ultrasonic transmitters emitting sound at known positions and time, the position of a target equipped with a microphone/ultrasonic receiver can be estimated based on the Time of Arrival (ToA) of the sound . The accuracy is usually poor under Non-line-of-sight (NLoS) conditions, where there are blockages in between the transmitters and the receivers [1].

[edit] Seismic surveys

Seismic surveys involve the generation of sound waves to measure underground structures. Source waves are generally generated by percussion mechanisms located near the ground or water surface, typically dropped weights, vibroseis trucks, or explosives. Data are collected with geophones, then stored and processed by computer. Current technology allows the generation of 3D images of underground rock structures using such equipment.

For more information, see Reflection seismology.

[edit] References

  1. ^ Lin Chi Mak and Tomonari Furukawa, "A Time-of-Arrival-Based Positioning Technique with NLOS Mitigation Using Low-frequency Sound", Advanced Robotics, Vol. 22, no. 5, pp. 507-526, 2008

[edit] See also

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