RU2196385C2 - Broadband noise suppression device - Google Patents

Abstract

FIELD: radio engineering; code-division communication and radar systems. SUBSTANCE: device functions to generate estimate of broadband noise using forward and inverse Fourier transforms followed by rejection of broadband noise from input mixture. In the process degree of broadband noise suppression is not reduced with increase in signal frequency uncertainty and with spectrum band extension of broadband noise, Device has delay circuits 1, 10, 13, 14, multipliers 2, 4, rejection filter 3, forward and inverse Fourier transform units 5 and 6, respectively, limiter 7, synchronizing unit 8, clock generator 9, subtracted 11, and limiting amplifier 12. EFFECT: enhanced reliability of noise suppression. 5 dwg

Description

 The invention relates to the field of radio engineering and can find application in communication systems with code division of channels, as well as in radar systems.

 Known devices for suppressing broadband interference described in patents RU 2020762, N 04 V 1/10 and 2000666, N 04 V 1/10, a common disadvantage of which is the low degree of suppression of broadband interference.

 The closest in technical essence to the claimed device is the device described in A.S. 1688416, H 04 In 1/10, which is selected as a prototype.

The structural diagram of the prototype is shown in figure 1, where the following notation is used:
1 - the first multiplier;
2 - a pseudo-random sequence generator (PSP), consisting of a clock generator 2 ₁ and a shift register with feedback 2 ₂ ;
3 - the second multiplier;
4 - notch filter;
5 - subtractor;
6 - first attenuator;
7.8 and 12 - the first, second and third delay elements;
9 - band-pass filter;
10 - key;
11 - second attenuator;
13 is a comparison block with a threshold.

The prototype device has the following functional relationships: a first multiplier 1, a notch filter 4 and a second multiplier 3 connected in series, the second input of which is connected to the output of the second delay element 8, the input of which is connected to the second input of the first multiplier 1 and the output of the pseudo-random sequence generator (PSP) 2, consisting of a series-connected shift register with feedbacks 2 ₂ and a clock generator 2 ₁ ; the output of the second multiplier 3 is connected to N frequency channels, each of which consists of a band-pass filter 9, the output of which through the comparison unit with threshold 13 is connected to the control input of the key 10 and is also connected to the signal input of the key 10, the output of which is connected through the second attenuator 11 and the third delay element 12 is connected to one of the N inputs of the subtractor 5, the output of which is the output of the device; the first attenuator 6 and the first delay element 7 are connected in series with the (N + 1) th input of the subtractor 5, while the input of the first attenuator 6 is connected to the first input of the first multiplier 1 and is also the input of the device.

 The prototype device operates as follows.

 An input mixture containing a useful broadband signal and a broadband (or narrowband) interference is fed to the (N + 1) -th input of block 5 through series-connected blocks 6 and 7.

 At the same time, the input mixture enters block 1, where, by multiplying with the synchronous reference signal of block 2, the useful broadband signal is collapsed into a narrow-band signal, which is edited in block 4. At the same time, the broadband interference in block 1 receives additional manipulation of the reference signal of block 2, which then removed in block 3 due to multiplication with the same reference signal, while part of the extended interference spectrum is rejected in block 4.

 That is, the useful signal to the output of block 3 does not pass, and the broadband (or narrowband) interference in block 1 is superimposed by additional manipulation of the broadband reference signal of block 2, which is then removed by multiplying the extended interference spectrum with the same reference signal that is supplied from block 2 through block 8, as a result of which the broadband interference is restored and fed to the inputs of N frequency channels, each of which opens if the interference level exceeds the permissible value (threshold).

 In block 5, only narrow-band interference that has passed through open frequency channels is subtracted from the input mixture arriving at its (N + 1) -th input. Thus, a signal passes to the output of block 5, and narrowband interference is suppressed. When exposed to powerful broadband interference, all N frequency channels open, and broadband interference is compensated.

 The disadvantage of the prototype is the low noise immunity to broadband interference.

 To eliminate this drawback, a device containing series-connected first multiplier, notch filter and second multiplier, first, second and third delay elements, a subtractor and a clock pulse generator contains series-connected limiter, fourth delay element, direct Fourier transform unit, inverse Fourier transform unit and an amplifier-limiter, the output of which is connected to the reference input of the first multiplier and through the third delay element to the reference input of the second a multiplier whose output is the output of the device. The output of the limiter through the second delay element is connected to the first input of the subtractor, and the output of the limiter is connected to the second input of the subtractor, the output of which is connected to the signal input of the clock synchronization unit, the reference input of which is connected to the output of the clock generator, and the output of the clock synchronization unit pulses are connected to the reference inputs of the direct Fourier transform block and the inverse Fourier transform block. In addition, the interconnected inputs of the limiter and the first delay element are also the input of the device.

The structural diagram of the inventive device is shown in figure 2, where the following notation is used:
1,10,13 and 14 - the first, second, third and fourth delay elements;
2 - the first multiplier;
3 - notch filter;
4 - the second multiplier,
5 - block direct Fourier transform;
6 - block inverse Fourier transform;
7 - limiter;
8 - block synchronization of clock pulses;
9 - clock generator;
11 - subtractor;
12 - amplifier limiter.

 The inventive device comprises a series-connected first delay element 1, a first multiplier 2, a notch filter 3 and a second multiplier 4, the output of which is the output of the device; the reference input of the second multiplier 4 is connected to the output of the third delay element 13, the input of which is connected to the reference input of the first multiplier 2 and through the limiter amplifier 12 to the output of the inverse Fourier transform block; the input of the first delay element 1 is also the input of the device and is connected to the input of the limiter 7, the output of which is connected to the fourth delay element 14, the direct Fourier transform unit 5 and the inverse Fourier transform unit 6, the reference input of which is connected to the reference input of the direct Fourier transform unit 5 and the output of the clock synchronization unit 8, the reference input of which is connected to the output of the clock generator 9, and the signal input of the synchronization unit 8 is connected to the output itatelya 11, a first input coupled to an output limiter 7 and a second input of subtractor 11 via a second delay element 10 is coupled to an output limiter 7, respectively.

 The inventive device operates as follows.

 The input mixture, containing a powerful broadband phase-manipulated periodic interference (hereinafter referred to as broadband interference) and a weak useful signal (broadband or narrowband), enters through the block 1 to the signal input of block 2, where it is multiplied with a copy (estimate) of the noise received at the reference input of the block 2 from the output of block 6 through block 12. As a result of multiplication, the powerful broadband interference turns into a narrow-band interference, which is edited in block 3 and therefore does not pass to the output of the device. At the same time, the manipulation of copies of broadband interference is superimposed on the useful signal in block 2, which is then removed from the useful signal in block 4 due to multiplication with the same copy of broadband noise coming to the reference input of block 4 and from the output of block 6 through series-connected blocks 12 and 13.

 Thus, the broadband interference does not arrive at the output of the device, and the useful signal passes almost without distortion due to the fact that the part of the signal spectrum that is detected by block 3 is negligible. The narrowness of the notch band is determined by the fact that block 3 rejects the result of the convolution of two correlated processes of broadband interference and its copy, while the copy of the broadband interference differs from the most broadband interference only in the initial phase.

 The formation of a copy of the broadband interference is as follows.

 The input mixture enters block 7, where a powerful broadband interference suppresses a weak useful signal, while the level of broadband interference is normalized. From the output of block 7, the broadband interference through block 14 is fed to block 5, where it is subjected to the direct Fourier transform procedure, which is carried out using clock pulses synchronous with broadband interference received at the reference input of block 5 from block 8. From the output of block 5, the voltage characterizing the spectrum of broadband interference, goes to block 6, where the inverse Fourier transform is performed using the same clock pulses supplied to the reference input of block 6 from block 8. At the output of block 6, highlight a copy of the broadband interference synchronous with the interference in the input mixture, which is amplified in block 12.

 The selection of clock pulses synchronous with broadband noise in the input mixture is as follows.

 From the output of block 7, the constant-level broadband noise goes directly to the first input of block 11, and to its second input through block 10, the delay value of which τ is equal to the period T of the broadband interference. At the output of block 11, a radio pulse of duration T is allocated, which represents one period of broadband interference.

The allocation of the radio pulse broadband interference is illustrated in figure 3, where indicated:
a) the input periodic broadband interference (in this case, the numbers indicate the pulse sequence numbers of the code sequence, the number of elements of which, for the purpose of simplification, was chosen equal to 4;
b) input broadband interference delayed by τ = T;
c) a dedicated broadband interference radio pulse of duration T at the output of block 11.

 The selected interference radio pulse is fed to the signal input of block 8, to the reference input of which clock pulses are fed from the output of block 9.

The block diagram of block 8 is shown in figure 4, where the following notation is used:
81 - switch;
82 ₁ , 82 ₂ , ... 82 _N , 82 _N-1 - delay elements;
83 ₁ , 83 ₂ , ... 83 _N - direct Fourier transform block;
84 ₁ , 84 ₂ , ... 84 _N - amplitude detector;
85 is a crucial unit.

 Block 8 works as follows.

 A broadband interference radio pulse of duration T allocated at the output of block 11 is supplied simultaneously to the inputs of the N channels of block 8, in each of which a direct Fourier transform procedure is performed in block 83, due to which a voltage characterizing the interference spectrum that is transmitted to the block is allocated at the output of each channel 84, where the envelope of the spectrum stands out.

The voltage from the outputs of the blocks 84 ₁ . .. 84 _N are supplied to the inputs of block 85. The clock pulses necessary for performing the direct Fourier transform procedure are fed to block 83 ₁ from the reference input of block 8 directly; to the input of block 83 ₂ through block 82 ₁ with a delay of τ ₀ = T / N; to block 83 ₃ - through block 82 ₂ with a delay of 2 τ ₀ and so on; to block 83 _N , through block 82 _(N-1) with a delay of (N-1) τ ₀ , where N is the number of channels in block 8, which determine the accuracy of synchronization.

The amplitudes of the spectral envelopes at the outputs of blocks 84 ₁ ÷ 84 _N depend on how much of the broadband interference pulse allocated at the output of block 11 overlaps with the time interval T _Ф , during which the direct Fourier transform procedure is performed, with Т _Ф = Т.

 The foregoing is illustrated in FIG. 5, where, for the sake of simplicity, N = 4 is selected.

On figa) shows a pulse of broadband interference at the input of block 8;
in FIG. 5b) - reference clock pulses from block 9 to the reference input of block 8 (to block 83 ₁ );
in FIG. 5c), d) and e) are the reference clock pulses arriving at the inputs of blocks 83 ₂ , 83 ₃ and 83 ₄ , delayed in blocks 82 ₁ , 82 ₂ and 82 ₃ by τ ₀ , 2τ ₀ , 3τ _0, respectively. The hatched parts of the pulses are the coincidence pulses of the input and reference pulses. 5d) corresponds to the case of synchronization of the reference clock pulses with the input broadband interference.

Block 85 can be made in the form of N comparison blocks with a threshold, each of which is supplied with voltage from the corresponding block 84. Commands for exceeding (not exceeding) the thresholds are sent to the corresponding control inputs of block 81, the signal inputs of which are supplied with clock pulses from the reference input block 8 directly and through blocks 82 ₁ , ... 82 _N-1 . Block 81 is executed in the form of N keys, to the control input of which from N keys there is a command to exceed the threshold from the corresponding output of block 5, and to the signal inputs of the keys - clock pulses directly from the reference input of block 8 and delayed clock pulses for a time τ ₀ , 2τ ₀ , ... (N-1) τ ₀ in blocks 82 ₁ , 82 ₂ , ... 82 _(N-1) .

The same clock pulses arrive at the reference inputs of the channels of blocks 83 ₁ , 83 ₂ ,. . . 83 _N. The output of block 81 passes clock pulses arriving at the input of the channel in which the threshold is exceeded in block 85, that is, clock pulses corresponding to the maximum envelope of the spectrum.

Blocks 5 and 83 can be made in the form of series-connected blocks of an analog-to-digital converter (ADC) and processor, while the sampling interval (T _d ) in the ADC is chosen equal to the time interval at which the direct and inverse Fourier transform (T _f ) are performed. Thus T _d = T _f = T.

 Block 6 can be made in the form of a series-connected processor and a digital-to-analog converter (DAC) block (see the monograph by Y. D. Shirman and V.K. Manzhos. Theory and technique of processing radar information against the background of interference, Moscow, Radio and Communications, 1981 ., pp. 154-160; monograph by Gold B. and Rabder Ch. Digital signal processing, Moscow, Sov. radio, 1973, pp. 203-206; monograph by Vodyakho A.I. et al. Data processing systems, Moscow , Higher School, 1977, p. 63, Fig. 2.9).

 Blocks 1, 13 and 14 are adjustable during adjustment, their values are selected in such a way as to ensure time alignment of the broadband noise and its copy, taking into account the delay in the equipment.

 In the prototype, with increasing the transmission rate of the useful signal, as well as its frequency uncertainty, the notch band of the notch filter increases, which leads to a distortion of the generated copy of the broadband noise, and, therefore, to a decrease in the degree of its suppression.

 In the proposed device, a copy of the interference is formed through the application of the direct and inverse Fourier transform over the input mixture in which the useful signal is suppressed, followed by the use of a copy of broadband interference for rejecting wideband interference in the input mixture.

 With this processing, the efficiency of suppressing broadband interference does not depend on the parameters of the useful signal, and the distortion of the useful signal can be neglected due to the extreme narrowness of the band of the notch filter.

Claims (1)

 A broadband interference suppression device comprising a first multiplier, a notch filter and a second multiplier connected in series, as well as a first, second and third delay elements, a subtractor and a clock generator, characterized in that a limiter, a fourth delay element and a direct Fourier transform unit are introduced , the inverse Fourier transform unit and the limiter amplifier, the output of which is connected to the reference input of the first multiplier and through the third delay element with the input of the second multiplier, the output of which is the output of the device, the output of the limiter through the second delay element connected to the first input of the subtractor, and the output of the limiter connected to the second input of the subtractor, the output of which is connected to the signal input of the clock synchronization unit, the reference input of which is connected with the output of the clock generator, and the output of the clock synchronization unit is connected to the reference inputs of the direct Fourier transform block and the inverse transform block Fourier analysis, in addition, the interconnected inputs of the limiter and the first delay element are also the input of the device, and the signal enters through the first delay element to the signal input of the first multiplier.

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