RU2349996C1 - Compensating noise suppression method in multichannel antenna system - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: incident electromagnetic wave is received by two compensating antennas and N main antenna radiators. Amplitude and phase of received signal of the first compensating antenna are converted so that with non-interference, amplitude and phase of converted signal are equal to that of signal received with the second compensating antenna. The specified signals are subtracted thus forming output compensating signal. Output signals of N main antenna radiators are added to weight factors thus forming converted signal of main antenna. Amplitude and phase of output compensating signal are converted. Then output compensating signal is subtracted from converted signal of main antenna thus output signal of multichannel antenna system.

EFFECT: higher received noise-to-signal ratio due to noise suppression of certain receiver direction.

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Description

The invention relates to antenna technology and can be used in radio communication systems when receiving electromagnetic waves with a multi-channel antenna system under the influence of several interference, the directions of reception of which are known.

Known methods for actively dealing with interference, in particular methods for periodically compensating for interference. In a similar method [1, p.234], one antenna and one radio receiver are used to receive signal and interference. The method allows for the compensation of interference, which is periodically following non-overlapping pulses. A prerequisite for this is that the signal and interference are pulses with a repetition period T that occur at different times at this interval. The method is based on the fact that a sequence of interference pulses received in the absence of a signal is delayed by a time multiple of T, and then subtracted from the mixture of signal and interference. The disadvantages of this method include the fact that for its use it is necessary to know the temporal structure of the signal and interference, and the signal levels and interference must remain constant.

Known methods for compensating for interference by decorrelation [1, p.136], in which several linearly independent voltages are formed at the output of the receiver:

u _i (t) = u _ci (t) + u _ni (t); i = 1,2, ..., N,

where u _ci (t) are the components of the signal at the output of the main receiver, interconnected; u _ni (t) - component interference at the output of the main receiver; the number N can take different values, so in [1, p.136] N = 3, and in [4] N = 10.

Then, the voltages u _i (t) are converted in such a way that, eliminating the signal components u _ci (t) from them, to determine the unknown components of the interference u _ni (t) for their subsequent compensation. The disadvantage of this method is the need for the formation of linearly independent voltages u _i (t).

There is a method of amplitude interference compensation [1, p.214], which requires the use of the main and compensation receivers, and the input of the compensation receiver receives only interference from directions corresponding to the side lobes of the radiation pattern of the main antenna. A highly directional antenna is used for the main receiver, and a weakly directional antenna is used for the compensation receiver. The essence of the method of noise compensation is that by one means or another they provide the formation of jamming signals having the same duration and envelope and appearing simultaneously at the outputs of the detectors in the main and compensation receivers, and then subtract the signals of the main and compensation receiver. The disadvantages of this method is that in order to completely compensate for interference, the directivity patterns of the main and compensation antennas in the region of the side lobes, as well as the presence of non-linear signal distortions after detection, are necessary.

A known method of amplitude-phase noise compensation [1, p.220], in which to eliminate non-linear distortion of the signal, noise compensation is performed at the outputs of high-frequency amplifiers or intermediate frequency amplifiers of the main and compensation receivers. As in the case of amplitude interference compensation, for the full compensation of interference, coincidence of the radiation patterns of the main and compensation antennas in the region of the side lobes is required, which is a limitation of the method.

Closer in technical essence to the claimed method is a method of compensatory interference suppression in a two-channel antenna system, proposed in [3, p. 344]. It consists in the fact that they carry out the incident electromagnetic wave of the main pointed antenna and compensating weakly directed antenna. The amplitudes and phases of the signals received by the main and compensation antennas are then converted, so that in the absence of a signal, the interference components have equal amplitudes and phases, after which the converted signal of the compensation antenna is subtracted from the converted signal of the main antenna, forming the output signal of the two-channel antenna system.

The disadvantage of this method is that it allows the compensation of only one interference, the direction of reception of which is known. In addition, as a result of the operation of the two-channel antenna system, the signal level may decrease, due to the fact that the signal is received not only by the main antenna, but also by the compensation antenna.

The proposed method is aimed at eliminating the above disadvantages of the known methods and increasing the signal-to-noise ratio when receiving an incident electromagnetic wave by suppressing interference in multi-channel antenna systems.

Consider the essence of the proposed method.

As in the prototype, the incident electromagnetic wave is received using a multi-channel antenna system and the received signals are converted. However, unlike the prototype method, the incident electromagnetic wave is received using two compensation antennas and N emitters of the main antenna, the amplitude and phase of the received signal of the first compensation antenna are converted so that, in the absence of interference, the amplitude and phase of the converted received signal of the first compensation antenna are equal to the amplitude and phase of the signal received by the second compensation antenna. Then, the converted signal of the first compensation antenna is subtracted from the signal received by the second compensation antenna, forming an output compensation signal. The output signals N of the emitters of the main antenna are summed with weighting factors w _n (n = 1,2, ..., N) that satisfy the criterion:

;

;

where f _n (θ) is the radiation pattern of the n-th emitter of the main antenna;

θ ₀ is the direction of reception of the useful signal; θ _m is the direction of reception of the m-th interference (m = 1,2, ..., M);

;

;

;

;

F _k1 (θ) and F _k2 (θ) are the radiation patterns of the first and second compensation antennas, respectively; while forming the converted signal of the main antenna. After that, the amplitude and phase of the output compensation signal are converted, the output compensation signal is subtracted from the converted signal of the main antenna, forming the output signal of the multi-channel antenna system.

A comparative analysis of the claimed method and prototype shows that the claimed method is different in that the set of actions is changed:

an action related to the reception of an electromagnetic wave by two compensation antennas is introduced;

the action associated with the formation of two output signals of the compensation antennas is introduced;

The action associated with the conversion of the output compensation signal is introduced.

In addition, the order of execution of the action: conversion of the signal of the main antenna.

The structural diagram of a device operating according to the proposed method is presented in figure 1.

The figure 2 shows the dependence of the signal / noise ratio from the direction of arrival of the interference, characterizing the gain achieved by the implementation of the proposed method.

Consider the proposed method of compensatory interference suppression in a multi-channel antenna system. Given the structural diagram of the interference suppression device shown in figure 1, we will carry out a theoretical justification of the proposed method.

The electromagnetic field created by the sources of signal and interference near the receiving antenna excites at its output a time-varying emf, the amplitude and phase of which, up to a constant factor, is proportional to the electric field strength. In accordance with the principle of superposition, electromagnetic fields from various sources in free space are added up, which allows us to represent the voltages at the outputs of the first, second compensation antennas and the nth emitter of the main antenna, respectively, in the form:

where s _{0 the} time dependence of the signal received from a given direction θ ₀ ; n _m is the time dependence of the mth interference coming from some known direction θ _m (m = 1,2, ..., M); F _k1 (θ), F _k2 (θ) and f _n (θ) are the radiation patterns of the first, second compensation antennas and the nth emitter of the N-element main antenna.

We form the output compensation signal Δu _k in such a way as to exclude information about the useful signal s _{0 from it} .

To do this, first we get the converted output signal of the first compensation antenna in the form:

Where

The coefficient C _k1 determines the conversion of the amplitude and phase of the output signal of the first compensation antenna u _k1 .

When subtracting the converted signal of the first compensation antenna from the output signal of the second compensation antenna, we obtain the output compensation signal described by the expression:

Here, ΔF _k (θ) is the differential DN of the compensation antennas.

The peculiarity of the output compensation signal is that it does not depend on the signal s ₀ .

Now we will make a weighted summation of the output signals of the emitters of the main antenna and get the converted signal of the main antenna in the form:

where w _n (n = 1,2, ..., N) are weighting factors.

Subtract the output compensation signal Δu ' _k from the converted output signal of the main antenna u ₀ and obtain the output signal of the multi-channel antenna system in the form:

Where

- coefficient of proportionality;

- The bottom of the main antenna.

The maximum signal / noise ratio is provided provided that the weighting factors w _n satisfy the criterion:

Expressions (10) and (11), taking into account the notation (9), can be represented as an optimization problem:

Where

The solution of the optimization problem (12) is reduced to a system of linear algebraic equations of the form:

which contains N unknowns and M + 1 equations.

Since the coordinates of each emitter of the main antenna are different from the others, all the equations in (14) are linearly independent.

It follows that if M + 1 = N, then the system of equations (14) has a unique solution. In the case when M + 1 <N, there is an infinite number of solutions to this system of equations. If the system of equations (14) is overdetermined (i.e., M + 1> N), then an approximate solution can be found that, using the least squares method, will satisfy criterion (12).

The operation of the device operating according to the proposed method can be illustrated using figure 1. The mixture of the useful signal and interference is received by the first and second compensation antennas 1 and 2, respectively. At the output of the first compensation antenna 1, a voltage u _k1 is induced, which is fed to the input of the signal conversion unit 3 of the first compensation antenna. The voltage u _k2 is induced at the output of the second compensation antenna. At the output of the conversion unit 3 of the first compensation antenna, a converted output signal u ' _{k1 is formed} . The amplitude and phase of this signal is converted in such a way that, in the absence of interference, the amplitude and phase of the converted signal of the first compensation antenna are equal to the amplitude and phase of the signal received by the second compensation antenna. After that, the converted output signal of the first compensation antenna u ' _k1 and the output signal of the second compensation antenna u _k2 are input to a subtractor 4, in which the converted signal of the first compensation antenna is subtracted from the signal received by the second compensation antenna, and as a result, the output compensation signal is generated Δu _k . The mixture of useful signal and interference is also received by N emitters forming the main antenna 5. The output signals of N emitters u ₀₁ , u ₀₂ , ..., u _0N are sent to the main antenna output signal generating unit 6, in which they are summed with weight coefficients, and the converted signal of the main antenna u _{0 is formed} .

Weighting factors w _n (n = 1,2, ..., N) must satisfy the criterion:

We clarify that

;

;

The output compensation signal Δu _{k is} supplied to the input of the output compensation signal conversion unit 7, in which the amplitude and phase of the output compensation signal Δu _{k are} converted, and the output compensation signal Δu ' _k is generated at the output of the output compensation signal conversion unit 7.

Transformed primary antenna signal u ₀ and the output compensation signal Δu _'k to the inputs of the subtractor 8, which is subtracted output compensation signal Δu' _k from the main antenna transformed signal u ₀ and an output signal of multi-channel antenna system _O u.

Blocks 1, 2 are low-directional antennas, each of which consists of one or more emitters.

Blocks 3 and 7 of the conversion of the output compensation signal are sequentially connected controlled phase shifter and attenuator (amplifier) and can be implemented similarly to the prototype.

Blocks 4 and 8 are an adder, the first input of which is connected to the output of the phase shifter or phase inverter.

Block 5 is an antenna array of N emitters.

The unit 6 for generating the output signal of the main antenna is a summation circuit of the antenna array with controlled phase shifters and attenuators (amplifiers).

Thus, a device that implements the proposed method consists of standard units, the implementation of which is described in the known literature [3, 4].

To evaluate the effectiveness of the proposed method, numerical studies were carried out, during which the signal-to-noise ratios at the output of a linear antenna array (AR) with uniform excitation, phased in the direction of signal reception, were compared with an antenna system that implements the proposed method of compensation interference suppression in a multi-channel antenna system . The gain in noise immunity was estimated using an indicator of the form:

where F _LAR (θ _m ) is the value of the linear arterial pathway in the direction of the mth interference.

Figure 2 shows the dependence of the signal-to-noise ratio W (θ _m ) on the direction of arrival of the interference, calculated for a 16-element linear and main AR. The selection of weighting coefficients was carried out taking into account the fact that the number of interference M coincides with the number of observation points in the area of the side lobes of the main antenna beam. An analysis of the results shows that for the considered example, the implementation of the proposed method provides a gain in signal / interference ratio of more than 20 times compared to a uniformly excited AR for all observation points in the area of the side lobes of the main antenna array.

Thus, the introduction of new actions and changing the order of execution of the action associated with the conversion of the signal of the main antenna, which provide the implementation of the proposed method, allows to increase the signal-to-noise ratio when receiving an incident electromagnetic wave by a multi-channel antenna system by suppressing interference coming from directions corresponding to area of the side lobes of the main antenna.

Information sources

1. Maximov M.V. Radio interference protection. - M .: Owls. Radio. 1976, 496 p.

2. Patent 2235392 (Russia) H01Q 3/26. A method of suppressing interference when receiving an electromagnetic wave of circular polarization by a biorthogonal antenna system / E.N. Mishchenko, S.E. Mishchenko, V.V. Shatsky // 2004, BI No. 24.

3. Erokhin G.A. Antenna feeder devices and radio wave propagation. - 2nd ed., Rev. - M .: Hot line - Telecom. 2004, 491 p.

4. Resurrection D.I. Antennas and microwave devices (design of phased antenna arrays). - 2nd ed., Additional and revised. - M .: Radio and communication. 1994, 592 p.

Claims (1)

The method of compensatory interference suppression in a multi-channel antenna system, based on the fact that the incident electromagnetic wave is received by the main highly directional antenna and the compensation weakly directional antenna, the amplitudes and phases of the received signals of the main and compensation antennas are converted, and the converted compensation antenna signal is subtracted from the converted signal of the main antenna the fact that the incident electromagnetic wave is received by two compensation antennas and N emitters the main antenna, the amplitude and phase of the signal received by the first compensation antenna are converted so that, in the absence of interference, the amplitude and phase of the signal of the first compensation antenna are equal to the amplitude and phase of the signal received by the second compensation antenna, the converted signal of the first compensation antenna is subtracted from the signal, received by the second compensation antenna, forming the output compensation signal, the output signals of N emitters of the main antenna are summed with weight coefficients w _n (n = 1, 2, ..., N) satisfying the criterion

;

,
where f _n (0) is the radiation pattern of the n-th emitter of the main antenna;
θ ₀ is the direction of signal reception; θ _m is the direction of reception of the m-th interference (w = 1, 2, ..., M);

;

;
F _k1 (θ) and F _k2 (θ) are the radiation patterns of the first and second compensation antennas, respectively;
generating the converted signal of the main antenna, the amplitude and phase of the output compensation signal are converted, and then the output compensation signal is subtracted from the converted signal of the main antenna, forming the output signal of the multi-channel antenna system.

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