RU2675386C2 - Method and device for extracting signals in presence of interference - Google Patents

Abstract

FIELD: wireless communication equipment.SUBSTANCE: invention relates to the field of communication technology and can be used in communications with amplitude-or frequency-manipulated signals. In the method of extracting a signal in the presence of interference, an additive mixture of the signal and interference is processed in the linear path of the receiver, after which the signal is squared and a decision is made on the presence of a signal by comparing with a threshold. Signal after squaring is filtered by a low-pass filter (LPF), whose band is matched with the band of the signal, and simultaneously filtered by bandpass filter (BF), whose bandwidth is chosen the way the upper frequency of the BF corresponds to the upper frequency of the signal, the lower frequency of the BF is chosen as close as possible to zero, the selection of the low-pass filter and the BF is carried out with identical to the maximum degree of phase-frequency characteristics relative to each other and so, that provide the minimum possible value of the sum of the differences of the values of the amplitude-frequency characteristics of the LPF and BF taken for all frequencies by converting in the corresponding analog-to-digital converters (ADC), form samples of signals, passed the BF and LPF, these values are subtracted one from the other in the computing device, the values obtained are summarized and memorized, from the obtained amount the value of the interference power is subtracted, obtained by filtering the interference with the same low-pass filter, which filter the signal and interference mixture, and at the same time filtering the interference with the same BF, which are used to filter the mixture of signal and interference, by converting to the corresponding ADCs, they form samples of interference that passed through the LPF and BF, these values subtract one from the other, the obtained values are summarized and memorized, the given value of the interference power is obtained during the time interval of the analysis of the interference, which is located directly in front of the information symbol being processed and which contains only noise.EFFECT: technical result is the provision of the possibility of estimating the interference power for a time commensurate with the period of the signal change, and due to this, in improving the noise immunity of communication means by ensuring the selection of a signal in the presence of interference such as additive Gaussian noise and narrowband interference.2 cl, 3 dwg, 4 tbl

Description

The method and device relate to radio engineering and can find application in communications.

Known methods that are implemented by devices for suppressing narrowband interference described in AS No. 1688416 Н04 В1 / 10, as well as in RF patents No. 2034403 Н04В 1/10, No. 2204203 Н04В 1/10, a device for compensating narrow-band interference described in the article by Efimov V.P. “Evaluation of the effect of nonlinear conversion on the noise immunity of reception in satellite networks”, published in the journal “Electromagnetic waves and electromagnetic systems”, No. 1, vol. 3, 1998, p. 95, the disadvantage of which is the low degree of interference suppression.

Known methods that are implemented by devices for suppressing broadband interference described in patents RU 2115234, RU 2143783, RU 2190297, the disadvantage of which is the low degree of interference suppression.

Closest to the technical nature of the proposed method is the method of energy detection of Price-Urkovits described in the training manual "Fundamentals of the theory of radio systems. Tutorial. // IN AND. Borisov, V.M. Zinchuk, A.E. Limarev, N.P. Mukhin. Ed. IN AND. Borisov. Voronezh Scientific Research Institute of Communications, 2004 ", p. 75-76."

For the prototype method, the normalized statistics at the detector output has the form

where: T is the integration interval;

Here:

H ₁ - the hypothesis that there is both a signal S (t) and interference n (t) of the type of additive Gaussian (white) noise;

H ₀ is the hypothesis that there is only interference n (t).

An additive mixture of signal and noise is filtered and amplified in the receiver linear path (LTP), and then squared in the corresponding device, for example, by branching it into two identical signals and applying them to the corresponding inputs of the multiplication device. The received signal is integrated. Then a decision is made on the presence of a signal using a threshold comparison device. A decision on the presence of a signal is made if the voltage supplied to the comparison device exceeds a threshold, and a decision on the absence of a signal is made otherwise.

The disadvantage of the prototype method is the low noise immunity of communications in the presence of interference such as additive Gaussian noise, as well as the complexity of the practical implementation associated with the long time to evaluate the interference power.

The task is to increase the noise immunity of communications by providing a signal in the presence of interference such as additive Gaussian noise by providing the ability to estimate the interference power for a time comparable to the period of the signal change.

To solve the problem in the method, namely, that the additive mixture of signal and interference is processed in the linear path of the receiver, after which the additive mixture of signal and interference is squared and a decision is made on the presence of a signal by comparison with a threshold, according to the invention, the filter obtained after erection squared signal with a low-pass filter (low-pass filter), the band of which is matched with the band of the signal; at the same time, the received signal is filtered by a band-pass filter, the passband of which is selected so that the upper frequency of the band-pass filter corresponds to the upper frequency of the signal, the lower frequency of the band-pass filter is selected as low as possible; digitally form samples of signals that have passed the band-pass filter and low-pass filter, by converting them to the corresponding analog-to-digital converters (ADCs), these values are subtracted from one another in a computing device, the obtained values are added up, the sum of the differences of the samples obtained from this the same algorithm during the time interval of the interference analysis, which is located immediately before the processed information symbol, and which contains only interference.

The proposed method of signal extraction is as follows.

A description is given of a method for the case of operation at a fixed frequency. For the case of operation with frequency tuning, the process is carried out for each operating frequency as well as for a fixed frequency.

A narrowband signal or a wideband signal is used. The type of modulation is amplitude manipulation (AMN) or frequency manipulation (FMN). Information is transmitted in the form of information symbols, each of which contains several signals of various types. The types of signals are determined by the type of manipulation used.

Before the first information symbol and between the symbols, a time interval (interference analysis interval) is formed, which does not contain a signal, and which is used to determine the values of the interference parameters.

Each information symbol may contain several signals of the first and second type.

For AMN, a signal of the first type is a signal with a first amplitude value, a signal of a second type is a signal with a second amplitude value. For AMS, the comparison of the amplitude of the signal and interference mixture is carried out with a threshold, the value of which depends on the level of the signal amplitudes used and is specified at the stage of development and testing of communication equipment.

For FSK, a signal of the first type is a signal transmitted at a frequency of No. 1, a signal of a second type is a signal transmitted at a frequency of No. 2. Upon further consideration, it is considered that in the case of using the FSK, the same processing is carried out in each frequency channel. When making the decision, the signal amplitudes and interference (interference) of one of the channels are compared with the amplitude of the interference (signal and interference) of the other channel.

The duration of the information symbol and the interference analysis interval are determined at the development stage in accordance with the given technical requirements for the communication medium, one of which is the level of information transmission quality. A given quality level is understood to mean information transfer with a probability of at least a given level or with a number of errors not exceeding a predetermined value.

An additive mixture of noise and signal (hereinafter referred to as a mixture of noise and signal) is amplified, for example, in an intermediate frequency amplifier (IF), if the processing is carried out at an intermediate frequency. Then the mixture of noise and signal is divided into two identical signals by any known method, for example, in a splitter. The signals thus obtained are multiplied by each other, for example, using a mixer (multiplier).

The result of multiplying the signal mixture and interference on itself:

- the result of multiplying the signal by signal — the square of the signal amplitude — for the narrowband signal, the sum of the squares of the signal amplitudes (constant component) and the sum of the Raman components of the signal — for the broadband signal;

- the result of multiplying the components of the interference by themselves - the sum of the squares of the amplitudes of the interference (constant component) and the sum of the result of multiplying the components of the interference by the components of the interference (Raman component of the interference);

- the result of multiplying the components of the interference by the components of the signal is the sum of the combinational components of the signal and interference.

Multiplication results are filtered by a low-pass filter and at the same time (in parallel) by a band-pass filter.

The LPF band is aligned with the signal band, i.e. the upper frequency of the low-pass filter corresponds to the upper frequency of the signal, the lower frequency of the low-pass filter is close to zero.

The high frequency of the bandpass filter corresponds to the high frequency of the signal. The lower frequency of the band-pass filter is chosen as low as possible and so that the value of the suppression coefficient of the sum of squares of the signal amplitudes and noise is not less than a given level. The value of the suppression coefficient is determined at the design stage by modeling or experimentally.

Thus, only the combinational components of the noise, the signal and the combinational components of the noise and the differential frequency signal pass to the output of the bandpass filter. I.e

where: Nss, Nsp - the number of harmonic components of the signal and interference, respectively;

U _si , U _pi , ω _si , ω _pi , ϕ _si , ϕ _pi are the amplitudes, frequencies, and phases ix of the signal and interference components, respectively.

The values of the amplitudes of the result of multiplying the signal mixture and the interference to itself, which have passed the bandpass filter and low-pass filter, are generated in digital form by conversion in the corresponding analog-to-digital converters (ADC)

It is believed that synchronization was made at the time of entering into communication, and the position in time of the beginning of the signal is known with sufficient accuracy for conversion to ADC.

The number of samples used to represent the signal is determined by mathematical modeling or experimentally.

In the computing device, the samples are the amplitudes of the results of multiplying the signal mixture and the noise itself, passing the band-pass filter and low-pass filter, taken at the same time, are subtracted from one another, the obtained values are summed. The sum of the differences of the samples obtained by the same algorithm during the time interval of the interference analysis, which is located directly in front of the processed information symbol, and which contains only the interference, is subtracted from the obtained value.

The type of signal is determined depending on the type of manipulation used by comparing the obtained value with the corresponding threshold.

When using AMN, the obtained value is compared with a threshold, the value of which depends on the level of signal amplitudes used and is specified at the stage of development and testing of communication facilities.

When using the FSK, the amplitudes of the signal and the interference (interference) of one of the channels are compared with the amplitude of the interference (signal and interference) of the other channel.

The results of evaluating the effectiveness of the proposed method were obtained by mathematical modeling on a computer using the MATLAB system.

As sources of interference, radio transmitting means, industrial interference caused by the operation of various electrical installations, as well as atmospheric interference are considered. These interferences affect the operation of radio receivers.

The interference during simulation is presented as a set of harmonic oscillations with random values of amplitudes (U _pi ) and phases (ϕ _pi ), which are distributed according to normal (amplitudes) and uniform (phases) laws (see, for example, the training manual “Fundamentals of the theory of radio engineering systems ". Textbook. // V.I. Borisov, V.M. Zinchuk, A.E. Limarev, N.P. Mukhin. Edited by V.I. Borisov. Voronezh Telecommunications Research Institute, 2004., p. 51, 68)

where Nsp is the number of harmonic components of the interference used to represent it (approximation);

ϕ _pi is the frequency of the ith component of the interference;

ϕ _pi is the phase of the i-th component of the interference;

U _pi is the amplitude of the ith component of the interference.

It is believed that for white noise type interference, the lifetime of the interference components is shorter than the time interval for taking samples in an analog-to-digital converter (ADC) (samples are independent random variables). For narrowband interference, it is believed that the lifetime of any component of the interference significantly exceeds the time interval for taking samples in the ADC.

Comparison of the effectiveness of the proposed method is carried out with the effectiveness of the prototype method, for the case when the interference power was estimated for one signal change period, that is, the information transfer rate for the proposed method and prototype method is the same.

When modeling, the following initial data were used:

- the number of implementations - 10 ³ ;

- type of manipulation - amplitude manipulation;

- signal amplitude:

signal of the first type (1 is indulged) - the signal amplitude is 1;

signal of the second type (0 is betrayed) - the amplitude of the signal is 2;

- the value of the threshold level for which a decision is made on the presence of a signal of the first or second type (if the reading amplitude does not exceed the value of the threshold level, then a decision is made on the presence of a signal of the first type, otherwise, a decision is made on the presence of a signal of the second type) - 1 ,8;

- the ratio of the values of the upper frequency of the bandpass filter of the intermediate frequency (IF) to the lower frequency of the bandpass filter of the IF - 2;

- the number of samples for the period:

for interference such as white noise - 1;

for narrowband interference - 10;

- the number of errors when deciding on the presence of a signal of the first or second type is 1 * 10 ^-3 .

The simulation results are shown in tables 1-4.

Modeling was carried out for a narrowband signal.

The simulation results for white noise are shown in Table 1.

In table 1, the following notation is used:

K _p - coefficient of suppression of the combination components of the signal and interference and interference (in%);

N _lane is the number of periods of the harmonic signal;

N _SP - the number of harmonic components of the interference used to represent it (approximation);

Q _ps - the ratio of the interference power and the signal for the proposed method, in which the number of errors when deciding on the presence of a signal of the first or second type is 1 * 10 ^-3 ;

Q _tf - the ratio of the interference power and the signal for the traditional method, in which the number of errors in deciding whether a signal of the first or second type is 1 * 10 ^-3 ;

Q _ps / Q _tf is the ratio of the interference power and the signal for the proposed and traditional methods.

Analysis of the data shown in table 1 allows us to conclude that the effectiveness of the proposed method is more than 3 times higher than the efficiency of the prototype method in the presence of white noise type interference, depending on the values of the method parameters.

Table 2 shows the results of evaluating the degree of compensation for interference of white noise type.

In table 2, the following notation is used:

K _p - coefficient of suppression of the combination components of the signal and interference and interference;

N _lane is the number of periods of the harmonic signal;

N _SP - the number of harmonic components of the interference used to represent it (approximation);

R _bk - the value of the interference power without compensation;

R _pc - the value of the interference power after compensation, in which the number of errors when deciding on the presence of a signal of the first or second type is 1 * 10 ^-3 ;

R _bk / R _pc - the ratio of the values of the interference power without compensation and after compensation, respectively.

From the analysis of the data given in table 2, it follows that the reduction in the noise power of the white noise type due to its compensation exceeds 17, depending on the values of the method parameters.

The simulation results for narrowband interference are shown in Table 3.

The designations used in table 3 are similar to the designations used in table 1.

Analysis of the data shown in table 3, allows us to conclude that the effectiveness of the proposed method is almost 5 times higher than the efficiency of the prototype method in the presence of narrow-band interference.

Table 4 shows the results of evaluating the degree of compensation of narrowband interference.

The designations used in table 4 are similar to the designations used in table 2.

From the analysis of the data given in table 4, it follows that the reduction in the power of narrow-band interference due to its compensation is over 37, depending on the values of the parameters of the method.

Thus, the use of the proposed method can significantly increase the noise immunity of communications by compensating for interference by estimating the amplitude of the combination components of the signal, interference and signal and noise in the channel in which the bandpass filter is used, as well as preliminary estimating the sum of squares of the amplitudes of the interference components carried out in a time interval containing only interference.

Known devices for suppressing narrowband interference described in A. with. No. 1688416 Н04 В1 / 10, as well as in RF patents No. 2034403 Н04В 1/10, No. 2204203 Н04В 1/10, narrow-band interference compensation device described in the article by Efimov V.P. “Evaluation of the effect of nonlinear conversion on the noise immunity of reception in satellite networks”, published in the journal “Electromagnetic waves and electromagnetic systems”, No. 1, vol. 3, 1998, p. 95, the disadvantage of which is the low degree of interference suppression. Known devices for suppressing broadband interference described in patents RU 2115234, RU 2143783, RU 2190297, the disadvantage of which is the low degree of interference suppression.

The closest analogue in technical essence to the proposed one is a multiplicative device for protection against narrow-band interference, described in RF patent No. 2287899 H04 B1 / 10, adopted as a prototype.

The block diagram of the prototype device is shown in FIG. 1, where indicated:

1 - intermediate frequency amplifier (UPCH);

2 - splitter;

3 - multiplication block;

4 - band-pass filter;

9 - amplifier.

The prototype device contains a series-connected amplifier 1, a splitter 2, a multiplication unit 3, a bandpass filter 4, an amplifier 9, the output of which is the output of the device, the second output of the splitter 2 is connected to the second input of the multiplication unit 3, the input of the amplifier 1 is the input of the device.

The prototype device operates as follows.

An input signal containing an additive mixture of signal and interference, which contains N ₁ frequency components of the signal and N ₂ frequency components of the interference, from the input of the device passes through the amplifier 1, where it is amplified, to splitter 2, where the mixture of signal and interference is divided into two identical components that go to the corresponding inputs of the multiplier 3. The result of multiplying the additive mixture of the signal and the interference by itself is the sum of the squares of the interference amplitudes and squares of the signal amplitude, the combination components of the interference, drove and interference differential frequency arrives at the band-pass filter 4.

The filter band is selected so that the band-pass filter 4 passes the signal in the frequency range fn ... fv, where:

The notation used in formulas (5), (6) is given above. That is, the band-pass filter 4 passes the combinational components of the interference and the differential frequency signal

and combinational components of the difference frequency signal

where U _C1 , U _C2 , U _P , ω _C1 , ω _C2 , ω _P , ϕ _C1 ϕ _C2 , ϕ _P are the amplitude, frequency and phase of the frequency components of the signal and narrowband interference, respectively.

Thus, the combinational components of the interference and the differential frequency signal pass through the bandpass filter 4 and the sum of the squares of the interference amplitudes and the squares of the signal amplitude and the Raman components of the signal do not pass, since they are outside its passband.

If only the signal and narrowband interference are present at the input of the receiver, the resulting signal at the output of the multiplication device 3 can be written as follows:

Using the assumption that the amplitudes of the frequency components of the signal are the same and the amplitudes of the frequency components of the interference are the same, taking into account the fact that the combinational components of the interference are filtered out, and averaging provided that the phases of the frequency components of the interference are random, after the corresponding transformation of expression (8), the expression for the signal at the output of the bandpass filter 4 is written as:

In the case of using amplitude signal manipulation, as a measure of the degree of discrimination between two signals with different amplitudes, the ratio of the amplitudes of these signals at the output of the bandpass filter 4 can be used. Using expression (9), we obtained

After a simple conversion, the final expression for the ratio of the amplitudes of these signals at the output of the band-pass filter 4 is written as

From the expression (11) it follows that when the interference power tends to infinity, the ratio of the amplitudes of these signals at the output of the bandpass filter 4 tends to

and does not depend on the level of interference within the dynamic range of the receiver.

If there is not only narrow-band interference at the input of the receiver, or when the frequency difference between narrow-band interference exceeds the lower value of the passband of the bandpass filter 4, the expression for the ratio of the amplitudes of the signals at the output of the bandpass filter 4 can be obtained using expressions (9) and (10)

That is, it is no different from the case of using traditional signal processing schemes (see, for example, G. Van Tris, “Theory of Detection, Estimation, and Modulation, vol. 1, M. Sov. Radio, 1972, p. 39, 53).

The disadvantage of the prototype device is that this device provides effective suppression of narrowband interference only when there is information about the values of the upper and lower frequencies of the interference, and has low efficiency otherwise.

The task is to expand the functionality by increasing the efficiency of suppressing narrowband interference for the case when information on the values of the upper and lower frequencies of the interference is absent, as well as providing compensation for interference such as white noise.

To solve the problem, a device containing a series-connected intermediate frequency amplifier (IFA), a splitter, a multiplication unit and a band-pass filter, the second output of the splitter connected to the second input of the multiplication unit, the input of the converter is the input of the device according to the invention, the first connected in series an analog-to-digital converter (ADC) and a computing device whose output is the output of the device, in addition, a low-pass filter (LPF) and a second th ADC, the output of which is connected to the second input of the computing device, the input of the first ADC is connected to the output of the bandpass filter, the input of the low-pass filter is connected to the output of the multiplication unit.

The block diagram of the inventive device is shown in FIG. 2, where indicated:

1 - intermediate frequency amplifier (UPCH);

2 - splitter;

3 - multiplication block;

4 - band-pass filter;

5, 6 - the first and second analog-to-digital converter (ADC);

7 - computing device (WU);

8 - low-pass filter (low-pass filter).

The proposed device contains a series-connected amplifier 1, a splitter 2, a multiplication unit 3, a band-pass filter 4, a first ADC 5 and a computing device 7, the output of which is the output of the inventive device. In addition, the second output of the splitter 2 is connected to the second input of the multiplication unit 3, the output of which is connected through a low-pass filter 8 and the second ADC 6 to the second input of the computing device 7, the input of the amplifier 1 is the input of the inventive device.

The proposed device operates as follows.

A harmonic (narrowband) signal or a wideband signal is used. The type of modulation is amplitude manipulation (AMN) or frequency manipulation (FMN). Information is transmitted in the form of information symbols, each of which contains several signals of various types, depending on the type of manipulation used. Before the first symbol and between the symbols, a time interval (the interval of interference analysis) is formed, which does not contain a signal, and which is used to analyze the values of the interference parameters. Each information symbol may contain several signals of the first and second type. For AMN, a signal of the first type is a signal with a first amplitude value, a signal of a second type is a signal with a second amplitude value. For FSK, a signal of the first type is a signal transmitted at a frequency of No. 1, a signal of a second type is a signal transmitted at a frequency of No. 2.

The duration of the information symbol and the interference analysis interval are determined at the development stage in accordance with the given technical requirements for the communication medium, one of which is the level of information transmission quality. In this case, a predetermined quality level is understood as information transmission with a probability of at least a predetermined level or with a number of errors not exceeding a predetermined value.

In the case of using FSK, the same processing is carried out in each channel. When making the decision, the signal amplitudes and interference (interference) of one of the channels are compared with the amplitude of the interference (signal and interference) of the other channel.

For AMS, the comparison of the amplitude of the signal and interference mixture is carried out with a threshold, the value of which depends on the level of the signal amplitudes used and is specified at the stage of development and testing of communication equipment.

An additive mixture of noise and signal is amplified in the amplifier 1 and fed to a splitter 2, where this mixture is divided into two identical components, which are fed to the corresponding inputs of the multiplier 3.

The result of multiplying the signal mixture and interference on itself:

- the result of multiplying the signal by the signal: the sum of the squares of the amplitudes of the signal and the sum of the results of multiplying the components of the signal by the components of the signal (combinational components of the signal) for a broadband signal, or the square of the signal amplitude for a narrowband signal (constant component);

- the result of the multiplication of the components of the interference themselves: the sum of the squares of the amplitudes of the interference (constant component), the sum of the result of the multiplication of the components of the interference by the components of the interference (combinational components of interference);

- the result of multiplying the components of the interference by the components of the signal (combinational components of the signal and interference).

These multiplication results are applied to the bandpass filter 4 and to the low-pass filter 8.

The band of the bandpass filter 4 is matched with the band of the signal, i.e. the value of the upper frequency of the bandpass filter 4 corresponds to the value of the upper frequency of the signal. The lower frequency of the band-pass filter 4 is selected as low as possible and, so that the value of the suppression coefficient of the sum of squares of the amplitudes of the signal and the interference is not less than a predetermined level. This value of the suppression coefficient is determined at the development stage by modeling or experimentally. Thus, only the combinational components of the interference, the signal and the combinational components of the interference and the differential frequency signal pass to the output of the bandpass filter 4. I.e:

where N _ss , N _sp - the number of harmonic components of the signal and interference, respectively;

U _si , U _pi , ω _si , ω _pi , ϕ _si , ϕ _pi are the amplitudes, frequencies, and phases ix of the signal and interference components, respectively.

The LPF band 8 is aligned with the signal band. The output of the low-pass filter 8 passes the result of multiplying the signal mixture and the interference by itself - the sum of the squares of the signal amplitudes and the noise and the combination components of the signal, signal noise and noise of the difference frequency.

It is believed that synchronization was made at the time of entering into communication, and the position in time of the beginning of the signal is known with sufficient accuracy.

The signal is the result of multiplying the signal mixture and the interference by itself, which passed to the output of the low-pass filter 8, goes to the input of the second ADC 6, where the values of the amplitudes that are fed to the second input of the VU 7 are generated in digital form.

The combinational components of the noise and the combinational components of the noise and signal that passed through the bandpass filter 4 are fed to the input of the first ADC 5, where digital samples are generated that are received at the first input of the VU 7.

The number of samples used to represent the signal is determined by mathematical modeling or experimentally.

In WU 7, the values of these samples are subtracted from one another, the obtained values are summed.

During the interference analysis interval, which is located immediately before the information symbol being processed, similar interference processing is performed. That is, the second input of the VU 7 receives from the output of the ADC 6 in digital form the samples of the result of multiplying the interference by itself. At the first input of the VU 7 from the output of the ADC 5, digital samples of the sum of the combination components of the interference are received. In WU 7, the difference of these values is determined - the sum of the squares of the amplitudes of the interference components and the amplitudes of uncompensated combination interference components. Uncompensated Raman components of interference is the difference between the samples of Raman components of the noise passed to the output of the low-pass filter 8 and the samples of the Raman components of the noise that passed to the output of the bandpass filter 4. The obtained values of the differences are summed. This value is stored in WU 7.

When processing the signal and interference mixture, the stored value of the sum of the squares of the amplitudes of the interference components and the amplitude values of the uncompensated Raman components is subtracted from the total values of the differences in the amplitudes of the mixture of the interference signal and the amplitudes of the Raman components of the noise, the signal and the Raman components of the noise and the signal.

An illustrative example illustrating the operation of the device is shown in FIG. 3. Here are the amplitude-frequency characteristics (AFC) of the band-pass filter 4 and the low-pass filter 8.

Computing device 7 can be made in the form of a programmable logic integrated circuit (FPGA), and is implemented, for example, on an XC2V3000-6FG676I or FPGA XCV400 series from Xilinx, or in the form of microprocessor devices (or as a single microprocessor device) with appropriate software for example, a processor series TMS320VC5416 from Texas Instruments;

The first ADC 5 and the second ADC 6 can be implemented on the THS1403IPFB chip.

As sources of interference, any radio transmitting means, industrial interference caused by the operation of various electrical installations, as well as atmospheric interference, are considered. These interferences affect the operation of radio receivers. The interference during simulation is presented as a set of harmonic oscillations with random values of amplitudes (U _pi ) and phases (ϕ _pi ), which are distributed according to normal (amplitudes) and uniform (phases) laws (see, for example, the training manual “Fundamentals of the theory of radio engineering systems ". Textbook. // V.I. Borisov, V.M. Zinchuk, A.E. Limarev, N.P. Mukhin. Edited by V.I. Borisov. Voronezh Telecommunications Research Institute, 2004., pg. 51, 68). An analytical description of the interference is given above.

Moreover, it is believed that for white noise type interference the lifetime of the component noise is less than the time interval for taking samples in the ADC. For narrowband interference, it is believed that the lifetime of any component of the interference significantly exceeds the time interval for taking samples in the ADC.

The results of evaluating the effectiveness of the proposed method were obtained by mathematical modeling on a computer using the MATLAB system.

The simulation results are shown in tables 1-4 of the description.

From the analysis of the data given in Tables 1-4, it follows that the functionality has been enhanced by increasing the efficiency of suppressing narrow-band interference, for the case when there is no information about the values of the upper and lower frequencies of the interference, and the efficiency of white noise interference compensation has been improved noise.

Claims (2)

1. The method of signal isolation in the presence of interference, namely, that the additive mixture of the signal and interference is processed in the linear path of the receiver, after which the signal is squared and a decision is made on the presence of the signal by comparison with a threshold, characterized in that the signal after erection squared filtered by a low-pass filter (low-pass filter), the band of which is consistent with the band of the signal; at the same time, the signal after squaring is filtered by a band-pass filter, the passband of which is selected so that the upper frequency of the band-pass filter corresponds to the upper frequency of the signal, the lower frequency of the band-pass filter is selected as close to zero as possible; the choice of the low-pass filter and the band-pass filter is carried out with the maximum identical phase-frequency characteristics relative to each other and so that the minimum possible value of the sum of the differences of the amplitude-frequency characteristics of the low-pass filter and the band-pass filter taken for all frequencies is provided; form in digital form, by converting in the corresponding analog-to-digital converters (ADCs), samples of signals that have passed the band-pass filter and low-pass filter, these values are subtracted from one another in the computing device, the obtained values are added up and stored, the interference power value is subtracted from the received amount, which is obtained as follows: filter the interference with the same low-pass filter with which the signal and noise mixture are filtered, at the same time filter the interference with the same band-pass filter with which the signal and noise mixture is filtered, forming digitally, by converting to the appropriate ADC, the samples of the interference that passed the low-pass filter and the band-pass filter, these values are subtracted from one another, the obtained values are summarized and stored, this value of the interference power is obtained during the time interval of the interference analysis, which is located immediately before the processed information symbol and which contains only interference. 2. A device for isolating signals in the presence of interference, containing a series-connected amplifier of an intermediate frequency (IF), a splitter, a multiplication unit and a bandpass filter, while the second output of the splitter is connected to the second input of the multiplication unit, the input of the IF is the input of the device, characterized in that a first analog-to-digital converter (ADC) is connected in series and a computing device in which the samples of the mixture signal and interference, or interference after they are squared, subtract one from the other, The values obtained are summarized and stored, the output of the computing device is the output of the device, in addition, a low-pass filter (LPF) and a second ADC are connected in series, the output of which is connected to the second input of the computing device, the input of the first ADC is connected to the output of the bandpass filter, the input of the LPF is connected to output of the multiplication block.

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