Radar.
Publié le 11/05/2013
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gathers the weak returning radar signals and converts them into an electric current.
Because a radar antenna may both transmit and receive signals, the duplexerdetermines whether the antenna is connected to the receiver or the transmitter.
The receiver determines whether the signal should be reported and often does furtheranalysis before sending the results to the display.
The display conveys the results to the human operator through a visual display or an audible signal.
B1 The Antenna
The receiver uses an antenna to gather the reflected radar signal.
Often the receiver uses the same antenna as the transmitter.
This is possible even in somecontinuous-wave radar because the modulator in the transmitter system formats the outgoing signals in such a way that the receiver (described in followingparagraphs) can recognize the difference between outgoing and incoming signals.
B2 The Duplexer
The duplexer enables a radar system to transmit powerful signals and still receive very weak radar echoes.
The duplexer acts as a gate between the antenna and thereceiver and transmitter.
It keeps the intense signals from the transmitter from passing to the receiver and overloading it, and also ensures that weak signals coming infrom the antenna go to the receiver.
A pulse radar duplexer connects the transmitter to the antenna only when a pulse is being emitted.
Between pulses, the duplexerdisconnects the transmitter and connects the receiver to the antenna.
If the receiver were connected to the antenna while the pulse was being transmitted, the highpower level of the pulse would damage the receiver’s sensitive circuits.
In continuous-wave radar the receivers and transmitters operate at the same time.
Thesesystems have no duplexer.
In this case, the receiver separates the signals by frequency alone.
Because the receiver must listen for weak signals at the same time thatthe transmitter is operating, high power continuous-wave radar systems use separate transmitting and receiving antennas.
B3 The Receiver
Most modern radar systems use digital equipment because this equipment can perform many complicated functions.
In order to use digital equipment, radar systemsneed analog-to-digital converters to change the received signal from an analog form to a digital form.
The incoming analog signal can have any value, from 0 to tens of millions, including fractional values such as .
Digital information must have discrete values, in certain regular steps, such as 0, 1, or 2, but nothing in between.
A digital system might require the fraction to be rounded off to the decimal number 0.6666667, or 0.667, or 0.7, or even 1.
After the analog information has been translated into discrete intervals, digital numbers are usually expressed in binary form, or as series of 1s and0s that represent numbers.
The analog-to-digital converter measures the incoming analog signal many times each second and expresses each signal as a binarynumber.
Once the signal is in digital form, the receiver can perform many complex functions on it.
One of the most important functions for the receiver is Doppler filtering.Signals that bounce off of moving objects come back with a slightly different wavelength because of an effect called the Doppler effect.
The wavelength changes aswaves leave a moving object because the movement of the object causes each wave to leave from a slightly different position than the waves before it.
If an object ismoving away from the observer, each successive wave will leave from slightly farther away, so the waves will be farther apart and the signal will have a longerwavelength.
If an object is moving toward the observer, each successive wave will leave from a position slightly closer than the one before it, so the waves will be closerto each other and the signal will have a shorter wavelength.
Doppler shifts occur in all kinds of waves, including radar waves, sound waves, and light waves.
Dopplerfiltering is the receiver’s way of differentiating between multiple targets.
Usually, targets move at different speeds, so each target will have a different Doppler shift.Following Doppler filtering, the receiver performs other functions to maximize the strength of the return signal and to eliminate noise and other interfering signals.
B4 The Display
Displaying the results is the final step in converting the received radar signals into useful information.
Early radar systems used a simple amplitude scope—a display of received signal amplitude, or strength, as a function of distance from the antenna.
In such a system, a spike in the signal strength appears at the place on the screenthat corresponds to the target’s distance.
A more useful and more modern display is the plan position indicator (PPI).
The PPI displays the direction of the target inrelation to the radar system (relative to north)as an angle measured from the top of the display, while the distance to the target is represented as a distance from thecenter of the display.
Some radar systems that use PPI display the actual amplitude of the signal, while others process the signal before displaying it and displaypossible targets as symbols.
Some simple radar systems designed to look for the presence of an object and not the object’s speed or distance notify the user with anaudible signal, such as a beep.
C Radar Frequencies
Early radar systems were capable only of detecting targets and making a crude measurement of the distance to the target.
As radar technology evolved, radar systemscould measure more and more properties.
Modern technology allows radar systems to use higher frequencies, permitting better measurement of the target’s directionand location.
Advanced radar can detect individual features of the target and show a detailed picture of the target instead of a single blurred object.
Most radar systems operate in frequencies ranging from the Very High Frequency (VHF) band, at about 150 MHz (150 million Hz), to the Extra High Frequency band,which may go as high as 95 GHz (95 billion Hz).
Specific ranges of frequencies work well for certain applications and not as well for others, so most radar systems arespecialized to do one type of tracking or detection.
The frequency of the radar system is related to the resolution of the system.
Resolution determines how close twoobjects may be and still be distinguished by the radar, and how accurately the system can determine the target’s position.
Higher frequencies provide better resolutionthan lower frequencies because the beam formed by the antenna is sharper.
Tracking radar, which precisely locates objects and tracks their movement, needs higherresolution and so uses higher frequencies.
On the other hand, if a radar system is used to search large areas for targets, a narrow beam of high-frequency radar will beless efficient.
Because the high-power transmitters and large antennas that radar systems require are easier to build for lower frequencies, lower frequency radarsystems are more popular for radar that does not need particularly good resolution.
D Clutter
Clutter is what radar users call radar signals that do not come from actual targets.
Rain, snow, and the surface of the earth reflect energy, including radar waves.
Suchechoes can produce signals that the radar system may mistake for actual targets.
Clutter makes it difficult to locate targets, especially when the system is searching forobjects that are small and distant.
Fortunately, most sources of clutter move slowly if at all, so their radar echoes produce little or no Doppler shift.
Radar engineershave developed several systems to take advantage of the difference in Doppler shifts between clutter and moving targets.
Some radar systems use a moving targetindicator (MTI), which subtracts out every other radar return from the total signal.
Because the signals from stationary objects will remain the same over time, the MTIsubtracts them from the total signal, and only signals from moving targets get past the receiver.
Other radar systems actually measure the frequencies of all returningsignals.
Frequencies with very low Doppler shifts are assumed to come from clutter.
Those with substantial shifts are assumed to come from moving targets..
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