RU2253183C1 - Noise suppression device for broadband signal receivers - Google Patents

Abstract

FIELD: radio engineering; broadband signal communication systems.

SUBSTANCE: proposed device is characterized in optimal selection of energy level choice for broadband signal spectrum section where narrow-band noise is being suppressed. Proportion of cross-correlation coefficient of distorted and reference signals, as well as that of noise and signal is proposed to be used as index of noise immunity. Novelty is introduction of START button, RS flip-flop, frequency tuning unit, comparison circuit, first adder, two squarers, second adder, power meter, normalizing unit, converter, gating pulse shaper, pulse generator, selector switch, memory register, division unit, delay line, comparator, and regulator in prior-art device for detecting noise-affected spectrum of signal.

EFFECT: enhanced noise immunity in radio reception.

1 cl, 1 dwg

Description

The invention relates to the field of radio engineering and can find application in communication systems with broadband signals (SHPS).

A device for suppressing interference for receivers of broadband signals (according to the patent of Russian Federation No. 2034403, class N 04 B 1/10, N 04 L 7/02, publ. 30.04.95, bull. No. 12), containing two subtractors, two multipliers, two band-pass filters, two amplifiers, a signal copy generator, a phase shifter and an AGC detector.

The disadvantage of this device is the low noise immunity of the radio in conditions of external interference and internal signal distortion.

The closest in technical essence to the claimed invention relates to a noise suppression device for receivers of broadband signals (according to the patent of the Russian Federation No. 2034402, CL N 04 B 1/10, H 04 L 7/02, publ. 30.04.95, bull. No. 12) containing a band-pass filter, a synchronous filter, a limiter, a device with an adjustable transmission coefficient, a signal copy generator, two multipliers, a phase shifter and two subtractors.

The disadvantage of this device is the low noise immunity of the radio, since the suppression of interference in the signal spectrum band is carried out without taking into account the degree of signal distortion.

The main task, the solution of which the claimed device is directed, is to increase the noise immunity of the radio reception due to the optimal choice of the energy level of the spectrum portion of the broadband signal, which suppresses narrowband interference.

The interaction of the signal and interference in the time-frequency domain is estimated using the cross-correlation coefficient (CEC) of the distorted and reference signals g, and the signal distortions that inevitably occur when taking measures to suppress noise in the receiving path, using the cross-correlation coefficient of interference and the reference signal λ. Analytically, these cross-correlation coefficients are determined by the expressions

- функция, сопряженная по Гильберту с S_Э(t) (соответствует фазовому сдвигу сигнала на 90° по отношению к исходному); S_П(t) - аналитическое описание помехи; Т - период эталонного сигнала; r_H - нормирующий коэффициент, обеспечивающий равенство g=1 (λ=1) при полном совпадении спектров искаженного сигнала (помехи) и эталонного сигнала.where S _And (t) is an analytical description of the signal distorted in the measuring path; S _E (t) - analytical description of the reference (reference) signal;

- a function conjugate according to Hilbert with S _Э (t) (corresponds to the phase shift of the signal by 90 ° with respect to the initial one); S _P (t) - analytical description of the interference; T is the period of the reference signal; r _H is a normalizing coefficient ensuring the equality g = 1 (λ = 1) with the complete coincidence of the spectra of the distorted signal (noise) and the reference signal.

As a comprehensive indicator of the degree of signal protection from interference (taking into account the effectiveness of measures taken to suppress interference), it is proposed to use the ratio of these coefficients, i.e.

The greater the effect of interference on the signal, the greater the value of the coefficient λ, and therefore, the smaller the value of the complex indicator Ξ. The suppression of noise in the signal spectrum leads to a decrease in both the denominator and the numerator in the expression for Ξ, since the difference between the distorted and reference (reference) signals increases. Thus, the proposed indicator allows us to evaluate not only the signal's immunity to interference, but also take into account the side effect of the adopted anti-interference measure.

The specified technical result is achieved by the fact that in the known device for determining the signal spectrum affected by the interference, an “Start” button, an RS-trigger, a frequency tuning block, a detector, a comparison circuit and a first adder are additionally introduced for evaluation a comprehensive indicator of the noise immunity of the radio reception to the existing signal copy generator, two multipliers and a phase shifter, two integrators, two quadrators, a second adder are additionally introduced, will measure a power factor, a normalizing unit, a converter, a gate pulse generator, a pulse generator, a switch, a memory register and a division block, and to optimize the level of suppressed interference in the signal spectrum, a delay line, a comparator and a regulator are additionally introduced to the existing device with an adjustable transmission coefficient.

The drawing shows a structural electrical diagram of the device. The interference suppression device for broadband signal receivers contains a “Start” button 1, an RS-trigger 2, a frequency tuning block 3, a band-pass filter 4, a synchronous filter 5, a comparison circuit 6, a detector 7, a limiter 8, a first adder 9, and a device 10 with adjustable transmission coefficient, pulse generator 11, switch 12 with two keys, first and second multipliers 13 and 14, converter 15, memory register 16, signal copy generator 17, phase shifter 18, first and second integrators 19 and 20, first and second quadrants 21 and 22, second sou a mumator 23, a normalizing unit 24, a power meter 25, a gate pulse shaper 26, a division unit 27, a delay line 28, a comparator 29, and a controller 30.

The device operates as follows.

When the “Start” button 1 is pressed, the voltage is sent to the R input of the RS-flip-flop 2, setting it to the logical “1” state. The voltage from the direct output of the RS-trigger triggers the frequency tuning block 3, which provides scanning of the bandpass filter 4 and synchronous notch filter 5 in the frequency range of the spectrum of the received broadband signal.

The output voltage of the narrow-bandpass filter 4 is supplied to the first input of the comparison circuit 6, to the second input of which the detected voltage of the entire broadband signal supplied to the input of the device, but with a level 8 limited in the limiter, is supplied from the output of the detector 7.

When tuning the band-pass filter 4 to the frequency of a powerful narrow-band noise, the level of which significantly exceeds the average signal level at the output of the detector 7, the signal from the output of the comparison circuit 6 receives a signal at the second input of frequency tuning block 3 to block it and at the S input of RS-flip-flop 2 it to the logical “0” state. Block 3 frequency adjustment ensures that the settings of the filters 4 and 5 are kept at the interference frequency.

At the same time, from the output of the synchronous filter 5, a signal with a “cut out” (cut) portion of the spectrum affected by the interference is received at the first input of the first adder 9. A selected portion of the spectrum of the signal with interference from the output of the band-pass filter 4 is fed through a device 10 with an adjustable transmission coefficient to the second input of the first adder 9. From the output of the first adder 9, a broadband signal with an adjustable energy level in the portion of the spectrum affected by the interference is fed to the output of the entire device.

The choice of the optimal level of the component of the spectrum of the NPS is carried out at the second stage of operation of the device as follows. The voltage of positive polarity from the inverse output of the RS-flip-flop 2 is supplied to the input of the pulse generator 11, which generates rectangular bipolar pulses with a duty cycle of 2. During the pulse duration of the positive polarity, the measurement of the interference voltage and signal λ is provided, and during the pulse duration of the negative polarity, the measurement KVK distorted and reference signals g.

The pulse of positive polarity from the generator 11, arriving at the switch 12, containing two keys, using the first key provides the connection of the output of the block 10 with an adjustable transmission coefficient to the second inputs of the multipliers 13 and 14, and with the second key of the switch 12 - connection of the output of the converter 15 s input register 16 memory.

сопряженного по Гильберту с эталонным сигналом S_Э(t).Thus, to the second inputs of the multipliers 13 and 14, interference S _P (t) is supplied, the level of which is controlled by the device 10, and the first signal of both multipliers receives the reference signal S _E (t) from the output of the generator 17 copies of the signal, and to the first multiplier 13 - directly, and to the second multiplier 14 through the phase shifter 18, which carries out the formation of the signal

Hilbert coupled with a reference signal S _E (t).

The results of the multiplication of the signals from the outputs of the multipliers 13 and 14 are fed to the information inputs of the corresponding integrators 19 and 20. After integration over a period of time equal to the duration t∈ [0, T], the output signals of the integrators 19 and 20 are fed through the squares 21 and 22 to the corresponding inputs second adder 23.

The signal supplied from the output of the adder 23 to the first input of block 24 is normalized to the power level of the reference signal measured in the power meter 25, the input of which is connected to the output of the signal copy generator 17. From the output of the normalizing block 24, the signal is fed to the information input of the converter 15 the control input of which is supplied with pulses from the first output of the gate generator 26.

The input of the driver 26 strobe pulses is connected to the inverse output of the RS-trigger 2.

The signal of the result of the measurement of the KVK λ of the interference and the signal described by expression (1) in the converter 15 is converted to digital form and, through the closed contacts of the switch 12, is supplied to the memory register 16 of the value of the KVK of the interference and signal. The strobe pulse from the second output of the shaper 26 is supplied to the control inputs of the integrators 19 and 20 to reset them to the zero state.

At the next stage of the device’s operation, after the end of the pulse duration of the positive polarity generated by the generator 11, a negative pulse appears at its output, which is supplied to the switch 12. In this case, the first switch in the switch 12 connects the output of the first adder 9 to the second inputs of the switches 13 and 14, and the second key is the output of the Converter 15 to the input of the division unit 27.

The received broadband signal S _AND (t) at the output of the first adder 9 will be distorted due to the rejection of the spectral regions in the frequency ranges where concentrated interference is present, and the replacement of this portion of the spectrum component with a level adjustable in the device 10.

с выходов перемножителей 13 и 14 поступают на информационные входы соответствующих интеграторов 19 и 20, затем - квадраторов 21 и 22, после чего - на входы второго сумматора 23. С выхода последнего суммарный сигнал, пройдя через нормирующий блок 24, является результатом измерения коэффициента взаимной корреляции g искаженного и эталонного сигналов, описываемого выражением (2).The distorted signal S _AND (t) from the output of the first adder 9 is fed to the second inputs of the multipliers 13 and 14, to the first inputs of which a reference signal S _E (t) is supplied from the generator 17: directly to the multiplier 13; to the multiplier 14 through the phase shifter 18. Then, by analogy with the first stage of the device, the results of the multiplication of signals S _AND (t) · S _E (t) and

from the outputs of the multipliers 13 and 14 are fed to the information inputs of the respective integrators 19 and 20, then to the squares 21 and 22, and then to the inputs of the second adder 23. From the output of the latter, the total signal, passing through the normalizing unit 24, is the result of measuring the cross-correlation coefficient g distorted and reference signals described by expression (2).

This KVK measurement result g is converted in block 15 into digital form and, through the closed elements of the second switch key 12, is fed to the second input (numerator input) of the division unit 27, the first input (denominator input) of which is supplied with information from the memory register 16 of the KVK value λ interference and signal.

The results of jx measurements of the coefficient ratios Ξ _j = g _j / λ _j , which are an indicator of the degree of signal protection from interference, are used for sequential optimal correction of the level of the signal spectrum component affected by concentrated interference. To this end, the measurement result Ξ _j from the output of the division unit 27 is supplied through the delay line 28 to the first input of the comparator 29, and to the second input of the comparator 29 directly from the division unit 27. The comparator 29 compares the current value of the measurement result of the indicator Ξ received at the second input with the value of the indicator Ξ _j-1 measured at the previous period of the generator 11 and received with a delay at the first input of the comparator 29.

If Ξ _j > Ξ _j-1 , then from the first output of the comparator 29 to the first information input of the controller 30 a signal will be received, with the help of which the controller 30 controls the decrease in the level of the signal-to-noise sum in the device 10. If Ξ _j < Ξ _j-1 , then from the second output of the comparator 29, a signal is supplied to the second information input of the controller 30, which ensures such control of the device 10, in which the previous level of the mixture (sum) “signal + interference” in the spectrum of the broadband signal is restored. If Ξ _j = Ξ _j-1 , then at both outputs of the comparator 29 there are signals preventing the state of the device 10 from changing by the controller 30.

Thus, the proposed device allows not only to suppress interference in the spectrum of a broadband signal, but also to take into account the resulting distortion of the spectrum of the signal. This allows you to optimize the level of the suppressed mixture “interference + signal” within the area of the NPS spectrum according to the criterion of maximum noise immunity of the radio reception.

Claims (1)

An interference suppression device for broadband signal receivers, comprising a limiter, a bandpass filter, a synchronous filter, a variable transmission coefficient device, serially connected signal generator and a first multiplier, a phase shifter and a second multiplier connected in series, characterized in that the Start button is additionally introduced, RS-trigger and frequency tuning unit, the output of which is connected to the control inputs of the band-pass and synchronous filters, the information inputs of which are are dined with the input of the limiter and are the input of the entire device, the first adder, the first input of which is connected to the output of the synchronous filter, and the second input of the second adder is connected to the output of the device with an adjustable transmission coefficient, the information input of which is connected to the output of the bandpass filter, the detector, the input of which is connected to the output of the limiter, a comparison circuit, the first input of which is connected to the output of the bandpass filter, and the second output of the comparison circuit is to the output of the detector, the output of the comparison circuit is connected to the second input of the block and the frequency tuning and S input of the RS-trigger, the pulse generator, the input of which is connected to the inverse output of the RS-trigger, a switch containing two keys, the control input of which is connected to the output of the pulse generator, connected in series to the first integrator, the first quadrator, the second adder, normalizing a block, a gating block and a converter, a second integrator and a second quadrator connected in series, the output of which is connected to the second input of the second adder, a memory register connected in series, a block Power line, delay line, comparator and controller, the output of which is connected to the control input of the device with an adjustable transmission coefficient, the output of which is connected to the first input of the first switch key, the second input of the first switch key is connected to the output of the first adder, and the output of the first switch key is connected with the second inputs of both multipliers, the outputs of which are connected to the information inputs of the respective integrators, the input of the second key as part of the switch is connected to the output of the transform device, the first input of the second switch key is connected to the input of the memory register, the second input of the switch key is connected to the second input of the division unit, the output of which is connected to the first input of the comparator via a delay line and to the second input of the comparator directly, the first and second outputs of the comparator are connected to the corresponding inputs a regulator, a power meter, the input of which is connected to the output of the signal generator, and the output of the power meter is connected to the second input of the normalizing unit, x pulses, the input of which is connected to the inverse output of the RS-flip-flop, and the outputs of the gate pulse shaper are connected: the first output is to the control input of the gate block, the second output is to the control input of the converter, the third output is to the control inputs of both integrators, and the input of the phase shifter is connected to the output of the signal copy generator.