RU2171549C1 - Device for discriminating acoustic signals in communication channels - Google Patents

Abstract

FIELD: electrical communications; voice signal detectors for multichannel communication systems such as telephone channels. SUBSTANCE: device has communication-channel matching unit 1, band filter 2, first, second, and third line detectors 3, 6, and 13, first, second, third, fourth, and fifths integration sections 4, 7, 10, 11, and 14, first, second, and third threshold elements 5, 9, and 16, first and second ratio calculating units 8, 15, subtracter 12, first and second AND gates 17, 19, register 18, and control timer 20. Device depends for its operation on calculation of series of solving statistics used as distinguishing specifiers to discriminate information-carrying acoustic signal from channel noise and spurious voice signals. Used as solving statistics are signal power estimate in data frequency band; input-signal energy distribution over frequency range, and degree of variation in envelope of input signal passed through band filter. Secondary processing is used for taking final decision on presence of acoustic signal in communication channel based on majority rule for sequential series of primary solutions. EFFECT: enhanced precision. 1 dwg

Description

 The invention relates to telecommunications, in particular to automatic means for receiving tonal signaling signals in multi-channel communication systems, and can be used, for example, to detect acoustic signals in telephone channels.

 The main problems of receiving tonal signaling signals are as follows. Reception of these signals often has to be carried out against the background of significant interference. The most typical here are smooth channel noises, impulse noise and spurious speech signals. In addition, the received signal can have a significant spread in frequency, and its shape may differ from the sinusoidal one due to the mismatch of the generators with the standards established in the communication technology.

 A device for receiving tonal signals, comprising a matching block with a channel, a band-pass filter, two resonant circuits connected in series, two linear detectors, two polarized relays, a threshold element and an actuator, is known. Here, the separation of the tonal (information) signal and the stray currents of speech frequencies is carried out through the use of two resonant circuits. Voltages removed from these circuits, after rectification, are applied to a polarized relay with two windings wound in the opposite direction. As a result, this receiver steadily selects a signal whose spectrum contains only spectral components in the information frequency band.

 However, this device cannot provide reliable selection of tonal signals subjected to significant distortion, as well as the information signal, which is received against the background of speech. In addition, in the case of a significant tune in the frequency of the tone generator, the operation of this receiver will be accompanied by frequent omissions.

 Also known is a receiver of tonal signals, comprising a matching unit with a communication channel, four one-vibrators, an inverter, two logical elements AND, an integrating element, an executive element. However, this device is also characterized by a low accuracy of extracting the information signal, which is associated with the possibility of processing the receiver on a spurious signal, as well as with a high probability of missing a distorted acoustic signal.

 Closest in technical essence to the claimed device is a device for separating acoustic signals in communication channels, comprising a matching unit with a communication channel, a bandpass filter, first, second and third linear detectors, first and second integrating links, first, second and third threshold elements , the first and second blocks of calculating the relationship, the peak detector, the first and second logical elements AND, register, control timer and actuator.

 The principle of operation of this device is based on the assessment of three decisive statistics, which are the hallmarks of recognition of an informational acoustic signal from channel noise and spurious speech signals. Here, the decisive statistics are used to estimate the signal power in the information frequency band, the distribution of the input signal power over the frequency range, and the peak factor of the input signal.

 However, when this device is operating, errors may also occur if the form of the received tone signal differs from the sinusoidal one. On the other hand, with an increase in the receiver threshold by the peak factor of the received signal, the probability of false alarms will inevitably increase, which is also unacceptable in alarm systems. In addition, the use of extreme statistics in the presence of significant channel noise also reduces the accuracy of the determination of acoustic signals.

 The purpose of the invention is to improve the accuracy of the allocation of acoustic signals in communication channels.

 To achieve this goal, a device for separating acoustic signals in communication channels, comprising a matching unit with a communication channel, a bandpass filter, first and second integrating links, first and second logic elements AND, first, second and third linear detectors, first and second calculation units relations, the first, second and third threshold elements, the register and the control timer, according to the invention, the third, fourth and fifth integrating links and the subtractor are additionally introduced, the output of the matching unit with the communication channel is connected to the inputs of the band-pass filter and the first linear detector, the output of the first linear detector through the first integrating link is connected to the second input of the first unit for calculating the ratio, the output of which through the second threshold element is connected to the first input of the first logical element And, while the output of the band-pass filter through the second linear detector is connected to the input of the second, third and fourth integrating links, in turn, the output of the second integrating link is connected to the first input of the first unit In order to calculate the relationship, to the second input of the second unit for calculating the relationship and through the first threshold element to the second input of the first logical element And, in addition, the output of the third integrating link is connected to the first input of the subtractor, and the output of the fourth integrating link to the second input of the subtractor, while the output a subtractor through a series-connected third linear detector and a fifth integrating element is connected to the first input of the second unit for calculating the ratio, the output of which is through the third threshold element of the connection nen with the third input of the first logical element And, the output of the first logical element And is connected through the register to the input of the second logical element And, and the outputs of the control timer are connected with the control inputs of the first and second elements I.

 A device for extracting acoustic signals in communication channels (see drawing) comprises a matching unit 1 for a communication channel, a bandpass filter 2, a first line detector 3, a first integrating link 4, a first threshold element 5, a second linear detector 6, a second integrating link 7, the first ratio calculating unit 8, the second threshold element 9, the third integrating element 10, the fourth integrating element 11, the subtractor 12, the third line detector 13, the fifth integrating link 14, the second ratio calculating unit 15, the third threshold element 16, the first the second logical element And 17, the register 18, the second logical element And 19 and the control timer 20.

 The functioning of the claimed device is based on the calculation of a number of crucial statistics, which are the hallmarks of recognition of an informational acoustic signal from channel noise and spurious speech signals. Here, the decisive statistics are used to estimate the signal power in the information frequency band, the energy distribution of the input signal over the frequency range, and the magnitude of the non-uniformity of the envelope of the input signal filtered in the band-pass filter.

 To make the final decision about the presence of an acoustic signal in the communication channel, secondary processing is used, which is based on the application of the majority rule for a sequential series of primary decisions. Secondary processing is introduced into the inventive device to prevent false alarms from a spurious speech signal. It uses the property of significant non-stationarity of the speech signal, which is also a hallmark in relation to the tonal signal.

 The analyzed signal from the output of the communication channel, passing through block 1 matching with the communication channel, is fed simultaneously to the input of the bandpass filter 2, as well as to the input of the first linear detector 3.

 Moreover, in blocks 2-4, an estimate of the power of the incoming signal is generated in the entire frequency band of the communication channel, for which the original signal is rectified in the first linear detector 3 and accumulated in the first integrating link 4.

 An approximate estimate of the signal power limited by the information frequency band is formed by means of blocks 2,6,7. For this, the input signal first passes through a bandpass filter 2, and then is also detected by the second linear detector 6 and accumulated in the second integrating link 7.

 An estimate of the input signal power limited by the information frequency band is used in the inventive device as the first decisive feature when making the initial decision on the presence of a tone signal in the channel. Therefore, the signal from the output of the second integrating link 7 is fed to the first threshold element 5, where it is compared with the boundary value. The result of the comparison goes to the first input of the first logical element And 17.

 To obtain the second feature, the signal from the output of the second integrating link 7 is fed to the second input of the first unit 8 of the ratio calculation. At the first input of the ratio calculation unit 8, a signal is received from the output of the first integrating link 4.

 As a result, at the output of the first relationship calculating unit 8, we have a value characterizing the distribution of the energy of the input signal over the frequency range of the communication channel. In other words, the estimate generated by the first ratio calculating unit 8 is approximately equal to the ratio of the signal power at the output of the bandpass filter 2 to the signal power at the input of the device. In this case, the well-known property of the harmonic signal is used, consisting in the fact that there is a certain dependence between the power of such a signal and the average modulus of the difference. The value thus obtained is compared in the second threshold element 9 with a boundary value. The comparison result in the form of a logical "0" or "1" is fed to the second input of the first logical element And 17.

 In blocks 10-16, the formation of the third information feature is carried out - an assessment of the unevenness of the envelope of the filtered signal. This feature is introduced into the inventive device to prevent false alarms on a spurious speech signal. Indeed, as you know, the envelope of a speech signal changes rapidly. In practice, the length of the "pseudo-stable" portion of the speech envelope very rarely exceeds 200 ms. At the same time, tone generators are characterized by the stability of the average output level.

 To assess the unevenness of the envelope, the signal from the output of the second linear detector 6 is fed simultaneously to the third and fourth integrating links 10 and 11, which differ in the value of the integration time. Comparison of the obtained values is performed in the subtractor 12. Next, the obtained value is detected (the magnitude modulus is calculated) in the third unit 13 for calculating the absolute value and averaged in the fifth integrating link 14. Then, the obtained value in the second unit for calculating the ratio 15 is normalized to the average level of the filtered signal, the estimate of which there is at the output of the second integrating link 7. The resulting value is compared in the third threshold element 16 with a boundary value. The result of the comparison in the form of a logical "0" or "1" is fed to the third input of the first logical element And 17.

 The primary decision on the presence of an informational acoustic signal in the communication channel is carried out periodically at regular intervals by a command from the control timer 20 by the control signal transmitted to the first logical element And 17.

 If all three decisive signs indicate the presence of an acoustic signal in the communication channel, i.e. logical “1” is fixed at the output of blocks 5.9 and 16, then logical “1” is also fixed at the output of the first logical element AND. This means that an initial decision is made to receive an acoustic signal.

 Further, the adopted primary decision is checked for stationarity. In this case, a priori information is used that the minimum duration of the transmission of the acoustic signal obviously exceeds the duration of the pseudo-stationary voiced portion of the speech signal.

 Implemented secondary processing using register 18, which accumulates a sequence of primary decisions about the presence of an information signal in the communication channel. If the length of the sequence of primary positive decisions about the presence of an acoustic signal reaches a value of N, then in the second logical element And 19 a secondary decision is formed on the detection of a tone signal.

 The duration of the input signal processing procedure in this device is set by means of a control timer 20, which is connected to both the first and second logical elements And 17, 19.

 The inventive object can be built using existing electronic means and components of communication equipment or implemented on the basis of computer technology, or using signal processors. This device may find application in the hardware and software of a telephone exchange.

Sources of information
1. Zayonchkovsky E. A., Pshenichnikov A. P., Romantsov V. M. Automatic long-distance communication .- M .: Radio and communication, 1984, p. 111-115.

 2. Copyright certificate N 441681, H 04 M 1/46, 03.01.73.

 3. Copyright certificate N 2118067, H 04 B 3/46, 08.20.98.

Claims (1)

 A device for detecting acoustic signals in communication channels, comprising a matching unit with a communication channel, a bandpass filter, first and second integrating links, first and second logic elements AND, first, second and third linear detectors, first and second blocks for calculating the ratio, first, second and third threshold elements, a register and a control timer, characterized in that a third, fourth and fifth integrating unit and a subtractor are additionally introduced into the device, the output of the matching unit being connected to the communication channel with the inputs of the band-pass filter and the first linear detector, the output of the first linear detector through the first integrating link is connected to the second input of the first unit for calculating the ratio, the output of which through the second threshold element is connected to the first input of the first logical element And, while the output of the band-pass filter through the second linear detector connected to the inputs of the second, third and fourth integrating links, the output of the second integrating link is connected to the first input of the first unit for calculating the relationship, to the second the input of the second unit for calculating the ratio and through the first threshold element to the second input of the first logical element AND, the output of the third integrating link is connected to the first input of the subtractor, and the output of the fourth integrating link to the second input of the subtractor, while the output of the subtractor is connected through the third linear detector and the fifth an integrating unit is connected to the first input of the second unit for calculating the relationship, the output of which through the third threshold element is connected to the third input of the first logic element And, an output of first AND gate is connected through the register to the input of a second AND gate for generating the secondary solutions for detection of acoustic signals in the communication channels, and outputs a control timer associated with the control inputs of the first and second elements I.