SU1764166A1 - Device for narrow band interference compensating - Google Patents

Abstract

The invention relates to telecommunications and can be used in broadband communication systems. The aim of the invention is to improve noise immunity. The device contains a signal copy generator 5, a reader 1. multipliers 2.1-2.4, barrier filters 3.1.3.2, broadband amplifier 7, adder 10, reference voltage source 11, amplitude detector 9 and band-pass filter 6. Input signal consisting of wideband useful signal and noise, is fed to the multiplier 2.3, to which a generator of the useful signal is supplied from the output of generator 5, and a subtractor 1. As a result of multiplication, the spectrum of the useful signal is narrowed, and the spectrum of interference is in accordance with the base B of the copy of the useful signal wider The subsequent processing of the signal in the barrier filter 3.1 and multiplier 2.4 results in that (1-1 / V) the original interference spectrum is formed at the output of the latter. As a result of the primary multiplication in multiplier 2.3, a useful signal is generated at the output of the bandpass filter and 1 / V of the interference spectrum. As a result of the secondary multiplication in the multiplier 2.4, the output of the amplitude detector 9 produces a negative voltage, which after amplification in the amplifier 8 goes to the adder 10, to which the source voltage 11 is applied. The output voltage of the adder is applied to the controlled attenuator 4, thereby causing the formation of an interference level corresponding to the interference envelope by. the input of the device, which is fed to the subtractor 1. 2 Il. (Ls xi o

Description

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The invention relates to radio engineering and can be used in broadband communication systems.

A device for the correlation processing of broadband signals (ed., No. 1338078, class H 04 V 1/10) is known, which contains a series-connected subtraction device, the first input of which is the input of the correlation processing device and the second input is connected to the output of the amplifier; multiplier, the second input of which is connected to the first output of the signal copy generator, and the output is connected to the input of the notch filter; integrator; a key, the control input of which is connected to the second output of the signal copy generator, and a comparison unit, to the input of which a threshold driver is connected; serially connected delay element, the input of which is connected to the output of the signal copy generator, an additional multiplier, the input of which is connected to the output of the notch filter, and the output is connected to the input of the amplifier.

However, the device has a low noise immunity associated with the lack of automatic jamming by compensating for its copy.

The closest to the invention according to the technical nature is a device for the correlation processing of wideband signals (ed. St. 1700754, class H 04 V 1/10). containing a series-connected subtractor, first multiplier, notch filter and second multiplier, the output of the first multiplier is connected to the input of the first filter, the second input of the first multiplier is connected to the output of the signal copy generator, and through the delay line to the second input of the second multiplier, synchronous-phase filter, the signal input of which is connected to the first input of the subtractor, the output with the second input of the subtractor, and the reference input with the output of the second multiplier.

This device also has low noise immunity.

The aim of the invention is to improve noise immunity.

For this, a narrowband interference compensation device containing a series-connected subtractor, a first multiplier and a band-pass filter, whose input is connected to the input of the second multiplier through a barrier filter, a third multiplier connected in series, a filter and a fourth multiplier, as well as a controlled attenuator, adder and copy generator signal output

which is connected to the corresponding inputs of the first, third and fourth multipliers, and the signal input of the first multiplier is connected to the first input

a subtractor, a wideband amplifier, a series-connected amplitude detector and a DC amplifier, as well as a source of reference voltage, are introduced, the filter is in the form of an EEG filter, the output of the fourth multiplier is connected to the second input of the subtractor through a series-connected wideband amplifier and a controlled attenuator control input

5 which is connected to the output of the adder, to the inputs of which are connected respectively the output of the voltage source and the output of the DC amplifier, the output of the second multiplier is connected to the input

0 amplitude detector, and the output of the signal copy generator is connected to the corresponding input of the second multiplier.

Figure 1 shows the structural diagram of the proposed device; Fig. 2, 5, and a diagram of stresses, which explain his work.

The narrowband interference compensation device contains a subtractor 1, made, for example, on resistors; first 2.1.

0 second 2.2, third 2 3 and fourth 2.4 multipliers, first 3.1 and second 3.2 barrier filters made, for example, in the form of series-connected high and low frequency filters

5 with cut-off frequencies equal respectively to the lower and upper boundaries of the barrier line; a controlled attenuator 4, made, for example, on p-i-n-diodes; generator 5 copies of the signal; strip

0 filter 6; broadband amplifier 7; DC amplifier 8; amplitude detector 9; an adder 10, made, for example, on resistors; reference voltage source 11, made, for example, in

5 point constant voltage source with adjustable level. In this case, a third multiplier 2.3 is connected in series, the first input of which is the input of the device, the first barrier filter

3.1, the fourth multiplier 2.4. a broadband amplifier 7, controlled by an attenuator 4, an output connected to the second input of the subtractor 1, the first input of which is connected to the first input of the third multiplier 2.3; The first multiplier 2.1 is connected in series, the first input is connected to the output of subtractor 1, and the output is also connected to the input of bandpass filter 6, the output of which is the device output, the second surge filter 3.2, the second multiplier 2.2, amplitude detector 9, DC amplifier 8 and the adder 10, the second input of which is connected to the output of the source 11 of the direct voltage, and the output connected to the control input of the controlled attenuator 4, the output connected to the second input of the subtractor 1; the output of the generator 5 copies of the signal is connected to the combined second inputs of the first 2.1, second 2.2, third 2.3 and fourth 2.4 multipliers.

The device works as follows.

The input signal consists of a wideband wanted signal Pc with a spectrum width rs.sh and a narrowband interference Pn with a spectrum width Fn y. arrives at the first combined inputs of the subtractor 1 and the third multiplier 2.3, the second input of which from the output of the generator 5 is supplied with a pseudo-random sequence (SRP) with the number of elementary pulses T / g, where T is the duration of the SRP; g - the duration of the elementary symbol PSP. At the output of the third multiplier 2.3, the spectrum of the useful wideband signal Pc narrows down and becomes Fc.y 1 / T, the spectrum of narrowband interference Pn expands B times and becomes equal to Rp.r Fn.y B 1 / g, and the energy of the useful the signal and the spectral power density of the interference are respectively equal to Ec Pc T and Mp RP g From the output of the third multiplier 2.3 the transformed components of the useful signal Pc and interference Pn are fed to the input of the first barrier filter 3.1 with the attenuation band Fn C 1 / T tuned to the frequency of the useful signal. As a result of the selection of the interference spectrum with the width Fn 1 1 / T, at the output of the first barrier filter 3.1 there remains a part of the interference spectrum D TL.R Shch - Fn

one

(1 - 1 / B), that

accordingly, it also causes a decrease in the power spectral density interference by 1 / V part. From the output of the first barrier filter 3.1, the selected part of the interference with the spectral width DRpp Rpp (1 - 1 / V) is fed to the first input of the fourth multiplier 2.4, the second input of which from the generator output 5 receives the SRP signal.

As a result of secondary multiplication at the output of the fourth multiplier 2.4, the signal of narrowband interference with the spectral width A Ff, .y Fn.y (1 - 1 / V) and the power level of NR Fny (1 - 1 / V) collapses into narrow-speed interference, which arrives to the input of the wideband amplifier 7. After amplification by the amplifier 7, the interference signal D Pn through controlled attenuator 4 is fed to the second input of the subtract 5 5.

Simultaneously, from the output of the subtractor 1, the same wideband input signal of the RS together with the narrowband interference Pn is fed to the first input of the first multiplier

10 2.1, to the second input of which, from the output of the generator 5, a signal is transmitted. At the output of the first multiplier 2.1, the spectrum of the wideband useful signal is narrowed by V and becomes equal to Fc.y 1 / T, the spectrum

15 narrowband interference Pn is expanded by a factor of F and increases to a value of Rf.r Fn yxB1 / g, and the energy of the desired signal and the spectral power density of the interference respectively become equal to Ec PCX

0 x T and Nn Pn f. From the output of the first multiplier 2.1, the transformed components of the useful signal Pc and narrowband interference Pn are fed to the input of the second barrier filter 3.2 and the band-pass filter 6

5 with attenuation and transparency bands, respectively, equal to F3.n 1 / Т. At the output of the bandpass filter 6, a narrowband useful signal and a 1 / V part of the interference spectrum are generated, since Fn.m: Fc.y 1 / g: 1 / T B, and

0 at the output of the second barrier filter 3.2, an interference signal is generated with a spectral width ΔPp.sh Fn š - Rp.z Fn ø 0 - 1 / H), which leads to a decrease in the power spectral density of the interference by

5 1 / In part. From the output of the second barrier filter 3.2, the selected part of the interference with the width of the spectrum DRPS RPS (1 - 1 / V) is fed to the first input of the second multiplier 2.2, to the second input of which

0 of the output of the generator 5 receives the signal of the SRP. As a result of the secondary multiplication at the output of the second multiplier 2.2, a signal of narrowband interference is formed with the width of the spectrum FND (1 - 1 / V)

5, the power level of the PND Nn-Fny (1-1 / V), which is fed to the input of the amplitude detector 9, At the output of the amplitude detector 9, a negative voltage Ui is formed (Fig. 2a), which, after amplification

0 by the DC amplifier 8 is fed to the first input of the adder 10. To the second input of the adder 10c of the output of the source 11, the reference voltage Ua is applied (Fig 26), which, in order to expand the dynamic

5 of the narrowband interference suppression range, corresponds to the maximum attenuation of the controlled attenuator A. As a result of the addition of opposite voltages Ui and U2 on you / humidifier 10, the resulting voltage 11z (Fig. 2c) decreases, which also causes a decrease attenuator attenuation 4. At the same time, at the output of controlled attenuator A, an interference level is formed corresponding to the level of narrowband interference at the device input, which is fed to the second input of the subtractor 1. By appropriate selection The amplifiers Kup t and Ksh of the dc amplifier 8 and the wideband amplifier 7, respectively, in the subtractor 1 (1 - 1 / V) of the interference spectrum of the input signal and (1 - 1 / V) of the spectrum from the output of the controlled attenuator A are compensated, and the output of the subtractor 1 remains only 1 / V of the interference spectrum, which, after multiplying in the first multiplier 2.1, with the SRP signal, is re-suppressed by a factor of. Therefore, as a result of double suppression of narrowband interference, its level is reduced by a factor of. .

Thus, the proposed technical solution in comparison with the prototype allows suppressing the level of interference by B, which, with an appropriate choice of base B of the wideband signal, increases the noise immunity of the device by several tens of times.

Claims (1)

Claims: A narrowband interference compensation device comprising a series-connected subtractor, a first multiplier and a band-pass filter whose input is connected to the input of a second multiplier through a barrier filter, a third multiplier connected in series, a filter and a fourth multiplier, as well as a controlled attenuator, adder and signal copy generator whose output is connected to the corresponding inputs the first, third and fourth multipliers, and the signal input of the first multiplier is connected to the first subtractor input, characterized in that, in order to improve the noise immunity, a broadband amplifier, an amplitude detector and a dc amplifier, as well as a source of reference voltage, are introduced into it, the filter is designed as a barrier filter, while the output of the fourth multiplier is connected to the second input of the subtractor through a series-connected broadband amplifier and a controlled attenuator, the control input of which connected to the output of the adder, the inputs of which are connected respectively to the output of the voltage source and the output of the DC amplifier; the output of the second multiplier is connected to the input amplitude detector, and the output of the signal copy generator is connected to the corresponding input of the second multiplier. about -LT ™ -Ep FIG. 2