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Radar (Radio Detection And Ranging), remote detection system used to locate and identify objects. Radar signals bounce off objects in their path, and the radar system detects the echoes of signals that return. Radar can determine a number of properties of a distant object, such as its distance, speed, direction of motion, and shape. Radar can detect objects out of the range of sight and works in all weather conditions, making it a vital and versatile tool for many industries. Radar has many uses, including aiding navigation in the sea and air, helping detect military forces, improving traffic safety, and providing scientific data. One of radar’s primary uses is air traffic control, both civilian and military. Large networks of ground-based radar systems help air traffic controllers keep track of aircraft and prevent midair collisions. Commercial and military ships also use radar as a navigation aid to prevent collisions between ships and to alert ships of obstacles, especially in bad weather conditions when visibility is poor. Military forces around the world use radar to detect aircraft and missiles, troop movement, and ships at sea, as well as to target various types of weapons. Radar is a valuable tool for the police in catching speeding motorists. In the world of science, meteorologists use radar to observe and forecast the weather (see Meteorology). Other scientists use radar for remote sensing applications, including mapping the surface of the earth from orbit, studying asteroids, and investigating the surfaces of other planets and their moons (see Radar Astronomy).
Radar relies on sending and receiving electromagnetic radiation, usually in the form of radio waves (see Radio) or microwaves. Electromagnetic radiation is energy that moves in waves at or near the speed of light. The characteristics of electromagnetic waves depend on their wavelength. Gamma rays and X rays have very short wavelengths. Visible light is a tiny slice of the electromagnetic spectrum with wavelengths longer than X rays, but shorter than microwaves. Radar systems use long-wavelength electromagnetic radiation in the microwave and radio ranges. Because of their long wavelengths, radio waves and microwaves tend to reflect better than shorter wavelength radiation, which tends to scatter or be absorbed before it gets to the target. Radio waves at the long-wavelength end of the spectrum will even reflect off of the atmosphere’s ionosphere, a layer of electrically-charged particles in the earth’s atmosphere. A radar system starts by sending out electromagnetic radiation, called the signal. The signal bounces off objects in its path. When the radiation bounces back, part of the signal returns to the radar system; this echo is called the return. The radar system detects the return and, depending on the sophistication of the system, simply reports the detection or analyzes the signal for more information. Even though radio waves and microwaves reflect better than electromagnetic waves of other lengths, only a tiny portion—about a billionth of a billionth—of the radar signal gets reflected back. Therefore, a radar system must be able to transmit high amounts of energy in the signal and to detect tiny amounts of energy in the return. A radar system is composed of four basic components: a transmitter, an antenna, a receiver, and a display. The transmitter produces the electrical signals in the correct form for the type of radar system. The antenna sends these signals out as electromagnetic radiation. The antenna also collects incoming return signals and passes them to the receiver, which analyzes the return and passes it to a display. The display enables human operators see the data. All radar systems perform the same basic tasks, but the way systems carry out their tasks has some effect on the system’s parts. A type of radar called pulse radar sends out bursts of radar at regular intervals. Pulse radar requires a method of timing the bursts from its transmitter, so this part is more complicated than the transmitter in other radar systems. Another type of radar called continuous-wave radar sends out a continuous signal. Continuous-wave radar gets much of its information about the target from subtle changes in the return, or the echo of the signal. The receiver in continuous-wave radar is therefore more complicated than in other systems.
The system surrounding the transmitter is made up of three main elements: the oscillator, the modulator, and the transmitter itself. The transmitter supplies energy to the antenna in the form of a high-energy electrical signal. The antenna then sends out electromagnetic radar waves as the signal passes through it.
The production of a radar signal begins with an oscillator, a device that produces a pure electrical signal at the desired frequency. Most radar systems use frequencies that fall in the radio range (from a few million cycles per second—or Hertz—to several hundred million Hertz) or the microwave range (from several hundred million Hertz to a several tens of billions Hertz). The oscillator must produce a precise and pure frequency to provide the radar system with an accurate reference when it calculates the Doppler shift of the signal (for further discussion of the Doppler shift, see the Receiver section of this article below).
© 1993-2008 Microsoft Corporation. All Rights Reserved.
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© 2008 Microsoft
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