RU2558676C1 - Compensation channel-switched active jamming compensation device - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: existing interference compensation device further includes series-connected second envelope detector, second adder, as well as a third envelope detector, the input of which is connected to the output of a compensation antenna and the output is connected to the second input of the second adder, the output of which is connected to the second input of a threshold device, and the input of the second envelope detector is connected to the output of the main antenna.

EFFECT: lower probability of false alarm owing to elimination of interference edges.

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Description

The invention relates to radar, can be used in equipment for detecting targets against the background of active interference.

Known heterodyne auto-compensator [Adaptive interference compensation in communication channels. Yu.I. Losev, A.G. Berdnikov, E.Sh. Goikhman, B.D. Sizov; Under. Ed. Yu.I. Loseva. - M.: Radio and Communications, 1988, p. 43], comprising a main channel with a converter and an adder, as well as a compensation channel with correlation feedback implemented using a correlator including a multiplier and a narrow-band integrating filter. In the adder, the addition of voltages is carried out in the main and compensation channels, which leads to suppression of noise and at the same time to an increase in internal noise. The disadvantage of this device is the decrease in the sensitivity of the receiving path due to the internal noise of the compensation channel.

A device for compensating active interference is also known [Bakulev P.A., Sosnovsky A.A. Radar Systems: Laboratory Workshop. Textbook Allowance for students special. "Radio electronic systems." M .: Radio engineering, 2007, p. 89], which contains a series-connected compensation antenna, a multiplier and an adder, the second input of which is connected to the main antenna, and the output to the first input of the correlator, the second input of which is connected to the output of the compensation antenna, and the output is connected to the second input of the multiplier, the output of the adder is the output devices.

Active noise interference received by the main antenna through the adder is fed to the first input of the correlator, to the second input of which comes the interference received by the compensation antenna. The correlator produces a weighting coefficient for the mutual correlation of interference received by the main and compensation antennas. The interference from the output of the compensation antenna is multiplied in the multiplier by the weight coefficient and fed to the adder, where it is subtracted from the interference received by the main antenna.

The presence of correlation feedback allows the device to tune to the characteristics of the interference and provide its suppression. However, in the absence of interference, the device accumulates the noise of the main and compensation channels even in the absence of external interference.

Thus, the disadvantage of this device is the decrease in the sensitivity of the radar due to the noise of the compensation receiving channel.

The closest in technical essence (the prototype of the present invention) is a noise compensation device [Patent No. 2363014 of the Russian Federation. Interference Compensation Device / V.D. Anokhin, E.V. Anokhin, V.N. Zakharov, V.G. Kildyushevskaya, F. Simohammed (RU). - No. 2008114805/09 (016401). Priority 04/15/2008. Zareg. GRI RF 07/27/2009], containing a series-connected main antenna and an adder, the output of which is connected to the first input of the first correlator, the second input of which is connected to the output of the compensation antenna and the first input of the multiplier, the second input of which is connected to the output of the first correlator, a third correlator, a second envelope detector, a threshold device and a key, the second input of which is connected to the output of the multiplier, and the output to the second input of the adder, are connected to the output of the main antenna in series the adder’s output is the output of the device, the second input of the third multiplier is connected to the output of the compensation antenna, the delay antenna is also connected to the output of the main antenna, the second correlator, the first envelope detector, the output of which is connected to the second input of the threshold device, the second input of the second correlator is connected to the output compensation antenna.

The interference from the output of the main and compensation antennas goes to the third correlator. The voltage from the output of the third correlator is detected by the second envelope detector and fed to the second input of the threshold device. In addition, the interference from the output of the main antenna through the delay line enters the first input of the second correlator, the second input of which receives interference from the compensation antenna. The delay time in the delay line is selected on the basis of ensuring decorrelation of interference received by the main and compensation antennas, i.e. τ ₃ > 1 / P, where P is the passband of the receive path. The voltage from the output of the second correlator is detected by the first envelope detector and applied to the first input of the threshold device, where it is used as a threshold voltage. If uncorrelated noise is present at the outputs of the main and compensation antennas, the threshold device does not work, the key will be closed, disconnecting the multiplier output from the second adder input. Noise of the compensation channel will not be received in the receiving path. If correlated interference is present at the outputs of the main and compensation antennas, the voltage amplitude at the output of the second envelope detector will significantly exceed the voltage at the output of the first envelope detector [Theoretical fundamentals of radar. Ed. Shirmana Y.D. Textbook for universities. - M .: Owls. Radio, 1970, p. 509], the threshold device will work and connect the output of the multiplier to the second input of the adder. The noise received by the main antenna through the adder enters the first input of the first correlator, the second input of which receives the noise received by the compensation antenna. The first correlator produces a weighting coefficient for the mutual correlation of interference received by the main and compensation antennas. The interference from the output of the compensation antenna is multiplied in the first multiplier by the weight coefficient and fed to the adder, where it is subtracted from the interference received by the main antenna. The presence of correlation feedback allows the device to tune to the characteristics of the interference and provide its suppression. After the end of the action of correlated interference, the voltage at the output of the second envelope detector does not exceed the threshold level of the threshold device and the key closes, disconnecting the compensation channel from the adder. In this case, the internal noise of the compensation channel does not pass to the adder output, which eliminates the decrease in the radar sensitivity in the absence of mutually correlated interference at the inputs of the compensator.

However, the presence of a delay line at the radio frequency complicates the practical implementation of the device, and can also lead to the appearance of interference edges, which increases the likelihood of a false alarm.

Thus, a disadvantage of the device is the presence of interference edges at the output of the device.

The problem to which the invention is directed, is to eliminate the edges of the interference.

The technical result is to reduce the likelihood of a false alarm by eliminating the edges of interference.

The technical result is achieved by the fact that in the known device for the compensation of active interference, containing a series-connected main antenna, a first adder, a first correlator, a multiplier and a key, the output of which is connected to the second input of the first adder, a second correlator, a first envelope detector and a threshold device are connected in series, the output of which is connected to the second input of the key, while the first input of the second correlator is connected to the output of the main antenna, and the second input to the output of the compensation antenna connected to the second inputs of the multiplier and the first correlator, the output of the first adder is the output of the device, a second envelope detector, a second adder, as well as a third envelope detector, the input of which is connected to the output of the compensation antenna, and the output to the second the input of the second adder, the output of which is connected to the second input of the threshold device, and the input of the second envelope detector is connected to the output of the main antenna.

The essence of the invention is based on the formation of a threshold voltage by incoherent summation of interference received by the main and compensation antennas.

The structural diagram of the proposed device is shown in the figure.

The proposed active interference compensation device consists of a main antenna 1, a second envelope detector 2, a second adder 3, a second correlator 4, a first envelope detector 5, a threshold device 6, a first adder 7, a third envelope detector 8, a compensation antenna 9, a multiplier 10, a key 11, the first correlator 12 connected as shown in the figure.

The key 11 is designed to connect the compensation channel during the action of the correlated interference received by the main antenna 1 and the compensation antenna 9, in the initial state, the key 11 is closed, the key 11 is controlled by the output voltage of the threshold device 6.

The device operates as follows.

The interference from the output of the main antenna 1 and the compensation antenna 9 is supplied to the second correlator 4. The voltage from the output of the second correlator 4 is detected by the first envelope detector 5 and supplied to the first input of the threshold device 6. At the same time, the interference from the output of the main antenna 1 through the second envelope detector 2 and from the output of the compensation antenna 9 through the third envelope detector 8 is supplied to the corresponding inputs of the second adder 3. The voltage from the output of the second adder 3 is supplied to the second input of the threshold device 6, where ts as a threshold voltage. If uncorrelated interference is present at the outputs of the main antenna 1 and compensation antenna 9, the threshold device 6 will not work, since the voltage at the output of the first envelope detector 5 does not exceed the threshold voltage specified by the second adder 3, the key 11 will be closed, disconnecting the output of the multiplier 10 from the second input of the first adder 7. Noise compensation channel in the receiving path will not come. If correlated noise is present at the outputs of the main antenna 1 and compensation antenna 9, the voltage amplitude at the output of the first envelope detector 5 will significantly exceed the voltage at the output of the second adder 3, the threshold device 6 will work and connect the output of the multiplier 10 to the second input of the first adder 7. Interference received by the main antenna 1 through the first adder 7, enters the first input of the first correlator 12, the second input of which receives interference received by the compensation antenna 9. The first correlator 1 2 generates a weighting coefficient for the mutual correlation of interference received by the main 1 and the compensation antenna 9. The interference from the output of the compensation antenna 9 is multiplied in the multiplier 10 by the weight coefficient and fed to the first adder 7, where it is subtracted from the interference received by the main antenna 1. The presence of correlation feedback Allows the device to tune to interference characteristics and to suppress it. After the action of correlated interference ends, the voltage at the output of the first envelope detector 5 does not exceed the response level of the threshold device 6 and the key 11 closes, disconnecting the compensation channel from the first adder 7, while the noise of the compensation channel to the output of the first adder 7 does not pass.

Since the threshold voltage is formed not due to a temporary shift of the interference oscillations received by the main and compensation antennas using the delay line at the radio frequency, but by their incoherent summation, this simplifies the practical implementation of the device and eliminates the presence of interference edges at the output of the device.

Thus, the proposed device eliminates the presence of interference edges at its output.

The proposed technical solution is new, because from publicly available information, devices are unknown that can ensure the detection of targets at maximum range in a rapidly changing interference environment.

The proposed technical solution is practically applicable, since standard equipment, devices and materials of widespread technology can be used for its implementation. The device can be technically implemented both in digital processing and in analog signal processing.

Claims (1)

An active interference compensation device comprising a series-connected main antenna, a first adder, a first correlator, a multiplier and a key whose output is connected to the second input of the first adder, a second correlator, a first envelope detector and a threshold device whose output is connected to the second key input are connected in series, wherein the first input of the second correlator is connected to the output of the main antenna, and the second input to the output of the compensation antenna, also connected to the second inputs of the multiplier and the first correlator, the output of the first adder is the output of the device, characterized in that the second envelope detector, the second adder, and the third envelope detector, the input of which is connected to the output of the compensation antenna, and the output to the second input of the second adder, the output of which are additionally connected in series connected to the second input of the threshold device, and the input of the second envelope detector is connected to the output of the main antenna.