RU2327183C1 - Noise compensator - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to radio engineering systems of signal (noise) suppression coming from the side lobes of the multilobe directional pattern (MLDP). The said noise suppression device described herein incorporates a primary antenna, two auxiliary antennas, two subtractors, five multipliers, three readout adders, two dividers, two complex integrators interconnected in a certain manner.

EFFECT: higher level of noise suppression.

2 dwg

Description

The present invention relates to suppression devices used in radio engineering systems for suppressing signals (interference) coming from the side lobes of the antenna radiation pattern (BOTTOM), and can be used in other systems that eliminate unwanted signals.

Of the known noise suppression devices received along the side lobes of the bottom beam, the closest in technical essence is the device described in patent RU No. 2247407 C2, bulletin No. 6 dated 02.27.05, the structural diagram of which is shown in figure 1. This device contains series-connected the second auxiliary antenna 11, the second subtractor 12, the complex pairing device 2, the first multiplier 3, the first adder samples 4, the divider 5, the second multiplier 6 and the first subtractor 7, the second input of which is connected n with the output of the main antenna 8, and sequentially connected the main antenna 8, the third multiplier 9, the second adder samples 10, the output of which is connected to the second input of the divider 5, while the second inputs of the first 3 and second 6 multipliers are connected to the output of the second subtractor 12, the second input of the third multiplier 9 is connected to the output of the complex interface device 2, and the second input of the second subtractor 12 is connected to the output of the first auxiliary antenna 1. The output of the first subtractor 7 is the output of the device VA interference suppression.

The disadvantage of this device is the low level of interference suppression due to fluctuations in the weight coefficient W relative to the optimal value due to the correlation between the components of the useful signal from the output of the main antenna 8 and the interference signal from the output of the second subtractor 12.

The technical result of the invention is to increase the level of noise suppression with the help of a noise compensation device.

The essence of the invention lies in the fact that in the interference suppression device containing a second auxiliary antenna, a second subtractor, a complex coupler, a first multiplier, a first adder of samples, a divider, a second multiplier and a first subtractor, the second input of which is connected to the main output antennas, and series-connected main antenna, third multiplier, second adder samples, the output of which is connected to the second input of the divider, while the second inputs the first and second multipliers are connected to the output of the second subtractor, the second input of the third multiplier is connected to the output of the complex conjugation device, the second input of the second subtractor is connected to the output of the first auxiliary antenna, the fourth and fifth multipliers, the third sample adder, the second divider and the second device are additionally introduced complex conjugation, the first input of the third multiplier being disconnected from the main antenna and connected to the output of the first auxiliary antenna, the first and second the inputs of the fourth multiplier are connected respectively to the outputs of the second auxiliary antenna and the first complex conjugation device, and the output of the fourth multiplier is connected to the input of the third adder of samples, the first and second inputs of the second divider are connected respectively to the outputs of the second and third adders the second complex conjugation device, the first and second inputs of the fifth multiplier are connected respectively to the outputs of the first divider and the second complex device conjugation, and the output of the fifth multiplier coupled to the input of the second multiplier.

The figure 2 presents a structural diagram of the proposed device to compensate for interference received on the side lobes.

The device for compensating for interference received along the side lobes of the bottom of the bottom of the bottom contains sequentially connected devices: a second auxiliary antenna 11, a second subtractor 12, a first complex coupler 2, a first multiplier 3, a first adder of samples 4, a first divider 5, a fifth multiplier 17, and a second multiplier 6 and a first subtractor 7, the second input of which is connected to the output of the main antenna 8, and the first auxiliary antenna 1, the third multiplier 9, the second adder of the samples 10, the output to the second is connected to the second input of the first divider 5, while the second inputs of the first 3 and second 6 multipliers are connected to the output of the second subtractor 12, the second input of the second subtractor 12 is connected to the output of the first auxiliary antenna 1 and the second auxiliary antenna 11 connected in series, the fourth multiplier 13, the third adder of samples 14, the second divider 15 and the second complex conjugation device 16, the output of which is connected to the second input of the fifth multiplier 17, while the second inputs of the third 9 and fourth of the multipliers 13 connected to the output of the first complex conjugation unit 2, the second input of the second divider 15 is connected to the output of the second adder 10. The output of the first subtractor 7 is the output of interference canceler.

The device operates as follows. The signal from the output of the main antenna 8 V _M = S + U, which is the sum of the radar signal S received by the main lobe of the BOTTOM and the interference U received by the side lobes of the BOTTOM, is fed to the first subtractor 7, to the other input of which a weighted signal WV _O from the output of the second multiplier 6.

The first auxiliary antenna 1 is omnidirectional with a directional coefficient determined by the level of the side lobes of the beam of the main antenna 8. The first auxiliary antenna 1 is offset relative to the main antenna 8 by a distance d, which leads to a phase shift of the interference signal received by this antenna relative to the interference signal, received by the main antenna 8, by the value φ = 2π (d / λ) sinα, where α is the direction of arrival of the interfering signal, counted from the normal to the base of the antennas - the line connecting the main 8 and the first 1 atelnuyu antenna. Based on the foregoing, the signal at the output of the first auxiliary antenna 1 can be written in the form:

,

,

where S _OSL is the attenuated useful signal at the output of the first auxiliary antenna 1. The presence of the attenuated useful signal is due to the fact that the first auxiliary antenna 1 has a certain directional coefficient in the direction of arrival of the useful signal. In this case, we believe that the useful signal comes from the direction perpendicular to the base of the antennas.

The second auxiliary antenna 11 is offset relative to the first auxiliary antenna 1 along the base of the antennas by a distance d and has a directional coefficient determined by the level of the side lobes of the main antenna 8. The signal at the output of the second auxiliary antenna 11 has the form:

.

.

This signal is fed to a second subtractor 12, to the other input of which a signal is output from the output of the first auxiliary antenna 1.

. Этот сигнал поступает на первое устройство комплексного сопряжения 2, а также первый 3 и второй 6 умножители. С выхода устройства комплексного сопряжения 2 сигнал поступает на входы первого 3, третьего 9 и четвертого 13 умножителей. На другой вход третьего умножителя 9 поступает сигнал с выхода первой вспомогательной антенны 1. Сигналы с выходов первого 3, третьего 9 и четвертого 13 умножителей поступают соответственно на на первый 4, второй 10 и третий 14 сумматоры выборок.Given the designations introduced, the signal at the output of the second subtractor 12 has the form:

. This signal is supplied to the first complex coupler 2, as well as the first 3 and second 6 multipliers. From the output of the complex pairing device 2, the signal is supplied to the inputs of the first 3, third 9 and fourth 13 multipliers. At the other input of the third multiplier 9, a signal is output from the output of the first auxiliary antenna 1. The signals from the outputs of the first 3, third 9, and fourth 13 multipliers are respectively sent to the first 4, second 10, and third 14 sample adders.

The inputs of the first 4 and second 10 adders are fed to the inputs of the first divider 5, and the signals from the outputs of the second 10 and third 14 adders are fed to the inputs of the second divider 15. The signal from the output of the second divider 15 is fed to the second complex coupler 16 and then to the input of the fifth multiplier 17, the other input of which receives the signal from the output of the first divider 5.

, а весовой коэффициент, получаемый на выходе второго делителя 15, равен

. На выходе второго устройства комплексного сопряжения 16 получаем комплексно-сопряженное значение весового коэффициента

.The weight coefficient obtained at the output of the first divider 5 is equal to

, and the weight coefficient obtained at the output of the second divider 15 is

. At the output of the second complex conjugation device 16, we obtain the complex conjugate value of the weight coefficient

.

The weight coefficient obtained at the output of the fifth multiplier 17 is determined by the expression:

- операция математического усреднения. С учетом введенных обозначений получаем:where the sign * means a complex conjugate,

- operation of mathematical averaging. Taking into account the introduced notation, we obtain:

.

.

The output signal of the compensator is determined by the expression:

.

.

The value of the weight coefficient obtained in the prototype is:

where ρ is the coefficient of cross-correlation of the useful signal from the output of the main antenna 8 and the interfering signal from the output of the second subtractor 12, σ ² _C , σ ² _P is the dispersion of the useful and interfering signals. An analysis of the latter expression shows that the presence of a correlation between the useful and interfering signals leads to fluctuations in the weight coefficient relative to the optimal value, which reduces the level of noise suppression.

In the proposed device in the formation of the weight coefficient does not participate components of the useful signal from the output of the main antenna 8.

Thus, the proposed device eliminates the effect of correlation between the components of the useful signal from the output of the main antenna 8 and the interfering signal from the output of the second subtracting device 12 on the level of interference suppression.

All elements of the proposed device can be implemented on a modern element base.

The use of the invention in this regard allows to increase the level of suppression of interference received on the side lobes of the bottom.

Claims (1)

A device for suppressing interference received along the side lobes of the antenna radiation pattern, comprising a second auxiliary antenna, a second subtractor, a first multiplier, a first adder of samples and a first divider, as well as a series of a first auxiliary antenna, a third multiplier and a second adder of samples, the output of which connected to the second input of the first divider, while the second inputs of the first and third multipliers are connected to the output of the first complex tension, and the input of the first complex conjugation device and the first input of the second multiplier are connected to the output of the second subtractor, the second input of the second subtractor is connected to the output of the first auxiliary antenna, the output of the main antenna is connected to the first input of the first subtractor, the second input of which is connected to the output of the second multiplier, characterized in that it additionally introduced the fourth and fifth multipliers, the third adder samples, the second divider and the second device complex tension, and the input of the second complex conjugation device is connected to the output of the second divider, and the output is from the first input of the fifth multiplier, the second input of which is connected to the output of the first divider, the output of the fifth multiplier is connected to the second input of the second multiplier, the first input of the fourth multiplier is connected to the output of the second auxiliary antenna, and the output with the input of the third adder samples, the output of the third adder samples connected to the first input of the second divider, the second input of which is connected to the output of the second adder rock, the second input of the fourth multiplier is connected to the output of the first complex conjugation device, the output of the first subtractor is the output of interference canceler.

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