RU2237261C2 - Method for detection of narrow-band radio signal - Google Patents

Abstract

FIELD: radio engineering, applicable in radio direction finders, dispersed reception systems functioning in the conditions of interference unknown intensity.

SUBSTANCE: the method consists in reception of a signal with the aid of a two-channel receiving device, whose channels are tuned to the signal frequency, amplitude detection and accumulation of squares of the signal envelope of each channel during the whole time of observation, at the same time the product of the signal envelope of the receiving channel is simultaneously produced and accumulated, the accumulated value is squared, divided by the product of the accumulated values of squares of the signal envelope of the receiving channels and compared with the threshold, whose value is preset proceeding from the permissible level of false alert and the quantity of non-correlated signal readouts, determined as the product of the time of observation by the width of the signal spectrum.

EFFECT: provided detection of narrow-band radio signals at an unknown intensity of noise with a probability of correct detection not worse than 0.9 at a probability of a false alert not exceeding 10^-2 -10^-3 and a signal-to-noise ratio being not less than 5 to 7.

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Description

The invention relates to radio engineering and can be used in direction finders, diversity systems, operating under conditions of interference of unknown intensity.

A known method of detecting a signal with unknown amplitude and phase, including receiving a signal, measuring its amplitude, for example, using correlation processing of quadrature components and determining the module of the correlation integral, comparing the measured amplitude with a threshold. [V.G. Repin, G.P. Tartakovsky. Statistical synthesis with a priori uncertainty and adaptation of information systems. M .: Sov. Radio 1977, p. 291].

The method is not applicable when the unknown noise intensity required to set the threshold. Uncertainty regarding noise intensity does not provide a given probability of false alarm, the value of which can vary by three orders of magnitude or more [A.P. Trifonov, V.I. Kostylev. Energy detection of narrowband radio signals against a background of noise with unknown intensity. University News. Radiophysics. T. XLV, 2002, p. 540]. Moreover, without additional information about the signal and noise, the optimal statistical solution to the problem of detecting a signal with unknown amplitude and phase in noise of unknown intensity is fundamentally impossible.

So, there is a known detection method, including receiving a signal, periodically measuring its amplitude, accumulating measurement results, comparing the accumulated amplitude with a threshold, which is established based on an estimate of the noise variance from the measured samples of the signal amplitude [RF Patent No. 2173468, G 01 S 7/292, 2001].

The disadvantages of this method include the limited scope of the range of low values of the signal-to-noise ratio, less than one hundredth, which should be a priori information. In addition, the input noise should be deliberately not Gaussian, but have less information uncertainty (entropy).

A known method for detecting narrowband radio signals against noise with unknown intensity, including receiving a signal, measuring its amplitude, comparing the measured value with a threshold, the noise intensity required to set a threshold, is measured before the signal detection process begins [A. Trifonov, V. I. Kostylev. Energy detection of narrowband radio signals against a background of noise with unknown intensity. University News. Radiophysics. T. XLV, 2002, p. 538-547].

The disadvantage of this method is associated with additional costs for measuring noise intensity. In addition, the sequential nature of the processes of measuring noise intensity and signal detection does not allow it to be used with the unsteady nature of the noise.

The closest in technical essence to the proposed one is a method for detecting a narrow-band radio signal, which includes receiving a signal using a two-channel receiving device, the channels of which are tuned to the frequency of the signal, phase detection of the signal received by one of the channels, using the second channel signal as the reference a signal shifted in phase by 90 °, amplitude detection with obtaining the envelope of the signal in each channel, the accumulation of the results of phase detection and squared bayuschey signal in each channel during the whole observation time, the accumulated sum of the squares of the envelope signal and twice the storage modulus results of phase detection, comparing the resulting sum with a threshold value which is set by the known noise intensity [V.G.Repin, G.P.Tartakovsky. Statistical synthesis with a priori uncertainty and adaptation of information systems. M .: Sov. Radio 1977, p. 381-385].

The method is not applicable when the unknown noise intensity required to set the threshold. In addition, the non-identical reception channels in amplitude and phase also destabilize the level of false alarm.

The objective of the invention is the provision of signal detection in noise of unknown, at the time of observation, intensity, including when the reception channels are not identical.

This is achieved by the fact that in the known method for detecting a narrow-band radio signal, which consists in receiving a signal using a two-channel receiving device, the channels of which are tuned to the signal frequency, amplitude detection and accumulation of the squares of the envelope of the signal of each channel during the entire observation time, at the same time, they additionally receive and accumulate the product of the envelope of the signal of the receiving channels, the accumulated value is squared, divided by the product of the accumulated values of the squares of the envelope with drove the receiving channels and is compared with a threshold value which is set based on the allowable level of false alarms and the number of uncorrelated signal samples, defined as the product of the time of observation by the width of signal spectrum.

A comparative analysis of the claimed solution with the prototype shows that the proposed method differs from the known one by the presence of, firstly, new actions on the signal: additionally receive and accumulate the product of the envelope of the signal of the receiving channels, the accumulated value is squared, and secondly, new conditions for the implementation of actions: above the accumulation results for subsequent comparison with the threshold, when setting the threshold - based on the number of uncorrelated signal samples.

In the study of other well-known technical solutions in the art, the specified set of features that distinguish the invention from the prototype was not identified.

The results of statistical synthesis of a signal detector against a background of noise with uncertainty about the phase, signal amplitude, noise variance, complex transmission coefficients of the receiving paths show that, in addition to accumulating the squares of the envelope of the signal of the receiving channels (prototype), a significant operation of optimal processing is to obtain and accumulate the product of the envelope of the signal reception channels. The decisive statistics, defined in this case as the ratio of the square of the accumulated product of the envelope of the signal to the product of the accumulated values of the square of the envelope of the signal of the receiving channels, is invariant to the noise intensity and transmission coefficients of the receiving paths. The physical basis for the availability of an optimal statistical solution is an increase to two number of receive channels and the presence of a priori information about the constancy of the gain of the receive paths during the observation period.

It is the use of the constancy property of the ratio of the amplitudes of the signal in the receiving channels, in accordance with the proposed new actions on the signal and the conditions for their implementation, that makes it possible to detect with unknown noise intensity and differences in the gain of the receiving channels.

Figure 1 shows the structural diagram of a device that implements the proposed method, figure 2 is a histogram of the distribution of critical statistics, figure 3 is the detection characteristics.

A device that implements the proposed method contains two receiving channels, each of which includes a receiving antenna 1.1, 1.2, a receiver 2.1, 2.2 and an amplitude detector 3.1, 3.2, connected in series. In addition, the device includes: a sampler 4, quadrants 5.1, 5.2, 5.3, multipliers 6.1, 6.2, accumulating adders 7.1, 7.2, 7.3, a divider 8 and a threshold element 9. The outputs of the receivers 1.1, 1.2, through the sampler 4 are connected to the squares 5.1, 5.2 and to the multiplier 6.1. The outputs of the quadrants 5.1, 5.2 and the multiplier 6.1 are connected to the accumulating adders 7.1, 7.2, 7.3, respectively. The output of the accumulating adder 7.2 through the quadrator 5.3 is connected to the first input of the divider 8, to the second input of which the output of the multiplier 6.2 is connected, the inputs of which are connected to the outputs of the accumulating adders 7.1, 7.3. The output of the divider 8 is connected to the input of the threshold element 9, the output of which is the output of the device.

The time constant of the amplitude detectors 3.1, 3.2 is established based on the condition of uncorrelated signal samples in accordance with the sampling theorem (Kotelnikov): τ = 1 / 2F, where F is the passband of radio receivers, consistent with the signal spectrum width. Sampler 4 provides a reading of the uncorrelated values of the envelope of the signal in the reception channels with a period of τ. The threshold value in element 9 is fixed, it is set regardless of the noise intensity based on the given probability of false alarm and the number of uncorrelated signal samples for the entire observation time T, that is: N = T / 2F = T / τ.

In an embodiment, for example with respect to phase direction finders, the antenna system comprises more than two antennas. In this case, the device is supplemented by an antenna switch, providing a pair of antennas connected to the receivers, in accordance with the direction finder functioning algorithm. Connecting the antennas is carried out synchronously with obtaining samples in the sampler.

The principle of operation of the device is as follows.

The detectable narrow-band radio signal is received by antennas 1.1, 1.2, converted and amplified in receivers 2.1, 2.2.

The noise at the input of the reception channels of the Gaussian type is independent, have the same dispersion, which is typical for the same type of receiving devices and antennas. In the observation interval T, the gain in amplitude does not change, but may differ for the first and second reception channels due to the non-identical antennas or receivers. The phase transfer coefficient is constant on the sampling interval τ and varies between sampling cycles, for example, due to the difference in the phase incursions of the signal in the direction finder antennas or the presence of a small frequency detuning of the local oscillators and, accordingly, the signal frequency at the output of the receiving devices.

Then the voltage at the output of the receivers 2.1, 2.2 is an additive mixture of the useful signal and noise, which at the sampling intervals τ (n-1) <t <τn, where n = 1, 2, ..., N is the number of the sampling cycle, can present in the following form:

- полезный сигнал и шумы на входе приемников в n-м цикле дискретизации;Where

- useful signal and noise at the input of the receivers in the nth sampling cycle;

k, φ _n are the transmission coefficients of the second channel in amplitude and phase, normalized relative to the first channel.

In amplitude detectors 3.1, 3.2, the received mixture (1) is converted into a sequence of uncorrelated values of the envelope of the signal of the receiving channels:

Here, the values of complex correlation integrals are determined by the relations:

where f ₀ is the frequency of the signal at the output of the receiving devices.

The set of values of the correlation integrals (3) is described by the normal distribution law:

where σ ² is the noise variance at the input of the receiving channels in the frequency band F.

At the end of the interval nτ, the obtained (2) envelope values through the sampler 4 are fed to the subsequent processing. The essence of the processing is determined by the results of statistical synthesis based on expression (4) and provides the following operations on the values of the envelope:

envelope values S _n , R _n are squared (blocks 5.1, 5.2) and accumulated (in adders 7.1,7.3);

simultaneously the same values are multiplied in the multiplier 6.1 and accumulated in the adder 7.2.

At the final stage of processing using the quadrator 5.3, the multiplier 6.2 and the divider 8, we obtain the decisive statistics Z, which in block 9 is compared with the threshold C:

The decision on the presence of a signal (hypothesis H ₁ ) is made when the threshold is exceeded.

The threshold value is set fixed regardless of the variance of the noise and gain of the reception paths, based on the given probability of false alarm according to the Neumann-Pearson criterion:

where W (Z) is the probability density of the decisive statistics (in the absence of a useful signal at the input).

In accordance with the results of the analysis, the decision statistics has a β-distribution:

where G (x) is the gamma function;

x = 1 / 4ρ;

I _v (x) is the modified vessel order Bessel function;

ρ is the signal-to-noise ratio at the output of the receiving channels (signal amplitude to the root mean square noise value).

In the presence of a signal, when ρ> 0, formula (7) corresponds to a variant of receivers with the same gain k = 1.

An example of a histogram w (Z) of the distribution of the value Z obtained as a result of modeling is shown in Fig. 2 for the number of sampling cycles N = 9. The solid line is in the absence of a signal at the input (ρ = 0), the dashed line is for a signal-to-noise ratio of 5. From Fig. 2, significant differences in the statistical properties of Z in the presence and absence of a signal are visible, which serves as the basis for the decision in the threshold element 9.

From formulas (6), (7) and FIG. 2 it can be seen that in the absence of a signal, the decisive statistics Z is determined only by the number of measurements N, therefore, the detection threshold depends only on this parameter and the admissible probability of false alarm, which simplifies the procedure for its practical calculation and installation.

The effectiveness of the invention is expressed in providing detection of narrowband signals with unknown noise intensity in the receiving channels, due to the implementation of the optimal method for processing radio signals.

The probability of correct detection by the proposed method is determined by an expression similar to (6):

where W (Z) is the probability density of the decisive statistics in the presence of a useful signal when ρ> 0.

The detection characteristics provided by the proposed method at N = 9 and calculated by formulas (7), (8) are shown in Fig. 3 in the form of a dependence of D on ρ. The solid line corresponds to the probability of false alarm 10 ^-2 (C = 0.914), and the dashed line corresponds to the probability of false alarm 10 ^-3 (C = 0.954). It can be seen from the presented results that the method provides effective, with a probability of at least 0.9, detection of a narrow-band radio signal in noise of unknown intensity at typical signal-to-noise ratios greater than 5-7 for the operating conditions of known direction finders. An additional advantage of the method relative to the prototype is its relative simplification due to the exclusion of phase detection operations and subsequent processing of the detection results.

Claims (1)

A method for detecting a narrow-band radio signal, which consists in receiving a signal using a two-channel receiving device, the channels of which are tuned to the frequency of the signal, amplitude detection and accumulation of squares of the envelope of the signal of each channel during the entire observation time, characterized in that they simultaneously receive and accumulate the product of the envelope of the signal receive channels, the accumulated value is squared, divided by the product of the accumulated values of the squares of the envelope of the channel signal n reception and compare with a threshold, the value of which is set based on the acceptable level of false alarm and the number of uncorrelated samples of the signal, defined as the product of the observation time and the width of the signal spectrum.

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