RU2210193C2 - Facility to receive multifrequency signals - Google Patents

Abstract

FIELD: electric communication. SUBSTANCE: salient feature of invention lies in use of several evaluated information statistics employed to carry out stable detection and reception of multifrequency signal under conditions of its masking with parasitic signal and in presence of marked distortion of series of its parameters. EFFECT: increased accuracy of reception of multifrequency signals. 1 dwg

Description

 The invention relates to the field of telecommunications, in particular to automatic means for receiving multi-tone telephone signaling signals. This invention can be used, for example, in telecommunication systems for receiving telephone numbers transmitted by tone method code "2 of 8".

 A device for receiving multi-frequency signals, comprising a matching unit 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 (1).

 However, this device cannot provide reliable selection of multi-frequency signals. Errors in the reception of a multi-frequency signal here will be especially frequent in cases where reception has to be carried out against the background of a spurious speech signal.

 A multi-frequency signal receiver is also known, comprising a matching unit with a communication channel, four single-vibrators, an inverter, two logical elements AND, an integrating unit, and a display unit. 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 the high probability of missing a distorted acoustic signal (2).

 The aim of the invention is to improve the accuracy of reception of multi-frequency signals.

 To achieve this goal, a band-pass filter, a low-pass filter, an analog-to-digital converter, a linear detector, the first and second arithmetic are additionally introduced into the device for receiving multi-frequency signals, comprising a matching unit with a communication channel, an integrating element, a logical element And, and a display unit according to the invention blocks, first, second, third and fourth threshold elements, comb filter block, linear detector block, integrating unit block, controlled key block, control tie measures, the first and second adders, the first, second and third blocks of calculating the ratio, and the output of the matching block with the communication channel through a series-connected low-pass filter is connected to the input of an analog-to-digital converter, the output of which is connected through a series-bandpass filter to the input of the linear detector and the inputs of the comb filter unit, while the output of the linear detector through a series-connected integrating link and the first threshold element is connected to the first input of the logic element And, and the outputs of the comb filter block are connected to the corresponding inputs of the linear detector block, in turn, the outputs of the linear detector block are connected to the corresponding inputs of the integrating unit block, the outputs of which are connected to the corresponding inputs of the managed key block, and the control input of the managed key block is connected with control timer, and the outputs of the first four controlled keys are connected to the inputs of the first arithmetic block, and the outputs of the fifth, sixth, seventh and eighth control keys with odes of the second arithmetic unit, the first output of the first arithmetic unit connected to the first input of the first unit for calculating the ratio, the first input of the first adder and the first input of the display unit, while the second, third and fourth outputs of the first arithmetic unit are connected, respectively, with the first, second and third inputs the second adder, and the second output of the first arithmetic block is connected, in addition, with the second input of the first block calculating the ratio, similarly the first output of the second arithmetic block connected to the first input of the second unit for calculating the ratio, the second input of the first adder and the second input of the display unit, while the second, third and fourth outputs of the second arithmetic unit are connected respectively to the fourth, fifth and sixth inputs of the second adder, and the second output of the second arithmetic unit is connected , in addition, also with the second input of the second relationship calculation unit, wherein the output of the first relationship calculation unit through the second threshold element is connected to the second input of the AND gate, and the output the second unit for calculating the relationship through the third threshold element is connected to the third input of the logic element And, in turn, the output of the first adder is connected to the first input of the third unit for calculating the relationship, the second input of which is connected to the output of the second adder, and the output through the fourth threshold element with the fourth the input of the AND gate, and finally, the output of the AND gate is connected to the control input of the display unit.

 A device for receiving multi-frequency signals (see drawing) contains a block 1 matching with a communication channel, a low-pass filter 2, an analog-to-digital converter 3, a band-pass filter 4, a linear detector 5, an integrating link 6, the first threshold element 7, a comb filter unit 8.1 -8.8, block of linear detectors 9.1-9.8, block of integrating links 10.1-10.8, block of controlled keys 11.1-11.8, control timer 12, first arithmetic block 13, second arithmetic block 14, first block 15 for calculating the ratio, second threshold element 16, second block 17 computing relations, the third threshold element 18, the first adder 19, the second adder 20, the third block calculating the ratio of 21, the fourth threshold element 22, the logical element And 23, the display unit 24.

 The main problems of creating reliably working receivers of multi-frequency signals are as follows. As a rule, tonal signaling is used in telephony to encode and transmit discrete information directly in the speech frequency band of a communication channel. This circumstance, given the low quality of local telephone networks, often leads to the fact that the reception of multi-frequency signals has to be carried out against a background of very significant spurious (interfering) signals and interference of various physical nature. In addition, the task of correctly receiving the transmitted discrete information is greatly complicated by the possibility of superimposing speech signals from the microphone of the handset on a multi-frequency signal. So, for example, the transmission of a telephone number by the tonal method is usually done without disconnecting the microphone in the telephone set. All of the above explains the reason for the occurrence of quite frequent errors at the reception, and in most cases these errors are associated with false alarms of detectors on a spurious speech signal.

 The essence of this invention consists in the use of several estimated information statistics, with the help of which stable detection and reception of a two-frequency signal is carried out under conditions of its possible masking by a spurious signal, as well as in the presence of significant distortions of a number of its parameters.

 This device provides a stable selection of a useful signal from a mixture of channel noise and spurious speech signals using frequency selection of the input signal, selecting two frequency components with a maximum level, calculating the ratio of the level of these two components to the total level of other components, estimating the signal power in the information frequency band and calculating the ratio of the first and second maximums for each of the two groups of signal frequencies. Thus, in the claimed device, in addition to the frequency selection of the input signal to determine the code two-frequency combination provides for several additional checks. These tests are based on a priori data on the characteristics of a real information multi-frequency signal. The final decision on the reception of a dual-frequency code message is made only after the entire set of conditions has been verified that distinguish the information signal from the spurious signal.

 Before starting the description of the operation of the claimed device, it is necessary to make one more significant remark. Hereinafter, we will consider the most common multi-frequency coding system today, namely, a two-frequency system in which two working frequency groups are used, and in any permitted code combination there is one frequency component from each frequency group. Such a system is used, for example, in telephone sets with tone dialing. However, the claimed device, in principle, can be used to receive multi-frequency signals with other coding systems.

 The inventive device operates as follows.

 The analyzed signal from the output of the communication channel, passing through the matching unit 1 with the communication channel and through a low-pass filter 2, enters the analog-to-digital Converter 3, the output of which takes the form of a sequence of digital samples. This digital sequence is subjected to bandpass filtering in the bandpass filter 4 and is fed to the input of the linear detector 5.

 At the same time, in blocks 5-7, an estimate of the power of the incoming signal in the information frequency band is formed, for which the absolute value of the initial signal is calculated in the linear detector, and then the average rectified value of the signal is estimated in the integrating link 6.

 An estimate of the input signal power limited by the information frequency band is used in the claimed device as the first information statistics when deciding whether there is currently a useful signal in the communication channel. For this, the power estimate obtained at the output of the integrating link is compared with the threshold value in the threshold element 7. If a signal appears in the communication channel of a sufficient level (exceeding a certain fixed boundary value), the value corresponding to the logical unit is set at the output of the first threshold element 7. Thus, the claimed device provides protection against false alarms caused by weak spurious signals and the appearance of which can be explained by inter-channel penetrations.

 At the same time, a sequence of digital samples of the input signal from the output of the bandpass filter 4 is fed to the input of comb filter banks 8.1-8.8. The comb filter 8.1-8.8 is a combination of eight resonant filters tuned to the nominal frequencies of the useful information signal. Here is the frequency selection of the input signal. Further, the signals from each of the eight sections of the comb filter pass through the corresponding linear detectors 9.1-9.8, which, in turn, are connected to the corresponding integrating links from the block of integrating links 10.1-10.8. Thus, by means of blocks 8.1-8.8, 9.1-9.8 and 10.1-10.8, the spectrum of the input signal in the information frequency band is estimated.

 The decision on the presence of an information signal (two-frequency code messages) and its decoding is carried out periodically at regular intervals by a command from the control timer 12. The values accumulated in the block of integrating links 10.1-10.8 through the corresponding sections of the managed keys of the block of managed keys 11.1-11.8, are read into the first and second arithmetic blocks 13 and 14. In this case, the spectral components of the first frequency group are processed in the first arithmetic block 13, and the second in the second arith eticheskom block 14. These arithmetic units 13, 14 for each of the frequency bands are determined first and second numbers of spectral maxima block sections and fixed components integrating links 10.1-10.8, which have been achieved absolute maximums envelopes.

 Thus, we can say that each arithmetic unit essentially performs a permutation in the descending order of the four values of the spectral components obtained in the integrating links 10.1-10.4 and 10.5-10.8, and then distributes them to the corresponding outputs. So, for example, the highest value obtained in one of the four filters of the first frequency group (10.1-10.4) will be fed to the first output of the arithmetic unit 13, the second largest value to the second output, etc. Similarly, the distribution is made in the second arithmetic unit 14. In principle, for the correct operation of the claimed device, the distribution of only the first two quantities is important, and the last two values can be distributed between the third and fourth outputs in an arbitrary way.

 To prevent false alarms of the detector on a spurious speech signal, blocks 15-18 are introduced into the device, with the help of which the ratios of the first and second spectral maxima for each of the two frequency groups are estimated. In this case, a statistical difference in the properties of the speech and multi-frequency signal is used, consisting in the fact that the difference between the levels of the first and second maximum in the multi-frequency signal in the vast majority of cases is significantly greater than for the speech signal. Comparison of the levels of the first and second spectral maxima of the first frequency group is carried out using the first block 15 calculating the ratio, and for the second frequency group in the second block 17 calculating the ratio. A corresponding choice of thresholds in the second and third threshold elements 16, 18 provides a distinction between the useful signal (two-frequency transmission) from spurious signals. Here, a priori information about the useful signal is used, consisting in the fact that the possible difference in the levels of the first two spectral maxima cannot exceed a certain fixed value. Otherwise, the signal is considered an interference. In the case when the above conditions are met, the logical units are set at the output of the corresponding threshold elements.

 The third information feature, which is used in the claimed device for protection against false alarms, is to assess the distribution of the input signal power over the frequency range. This check is based on the well-known fact that immediately at the time of receiving a two-frequency sending of a useful (information) signal, the total power of two useful (information) frequency components significantly (at least 6-12 dB) exceeds the total power of the signals taken from the other six sections are comb filter. At the same time, in the vast majority of cases, spurious signals, for example, speech signals, are not characterized by the presence of two pronounced spectral maxima.

 To conduct such a check, in the first adder 19, the two frequency components (one from each frequency group) are added, which have the greatest power, and the second adder 20 is the addition of all the other six frequency components. Then, in the third block 21 of calculating the relationship, their ratio is evaluated. If the obtained value is greater than some fixed boundary value specified in the fourth threshold element 22, then the result of the verification by the third sign is considered positive and the value corresponding to the logical unit is set at the output of the fourth threshold element 22.

 The final decision on the appearance of a two-frequency combination of an information signal is made when all four inputs of the logical element And 23 contain signals corresponding to logical 1. Then, the corresponding input for converting the two-frequency combination into the digit of the dialed number is sent to the control input of the display unit 24.

 The implementation of this device is most appropriate to implement on the basis of traditional digital circuitry ("hard logic") or using signal microprocessors.

Sources of information
1. Zayonchkovsky E. A., Pshenichnikov A. P., Romantsov V. M. Automatic long distance communication. -M .: Radio and communications, 1984. Pages 11-113.

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

Claims (1)

 A device for receiving multi-frequency signals, comprising a matching unit with a communication channel, an integrating element, an AND logic element and a display unit, characterized in that a band-pass filter, a low-pass filter, an analog-to-digital converter, a linear detector, the first and second arithmetic are additionally introduced into the device blocks, first, second, third and fourth threshold elements, comb filter block, linear detector block, integrating unit block, controlled key block, control timer, first and second s matrices, the first, second and third blocks of calculating the ratio, and the output of the matching block with the communication channel through a series-connected low-pass filter is connected to the input of an analog-to-digital converter, the output of which through a series-connected bandpass filter is connected to the input of the linear detector and the inputs of the comb filter unit, wherein the output of the linear detector through series-connected integrating element and the first threshold element is connected to the first input of the logical element And, and the outputs of the block g The loop filters are connected to the corresponding inputs of the block of linear detectors, in turn, the outputs of the block of linear detectors are connected to the corresponding inputs of the block of integrating links, the outputs of which are connected to the corresponding inputs of the block of controlled keys, and the control input of the block of controlled keys is connected to the control timer, and the outputs of the first four managed keys are connected to the inputs of the first arithmetic unit, and the outputs of the fifth, sixth, seventh and eighth managed keys are connected to the inputs of the second arithmetic unit, and the first output of the first arithmetic unit is connected to the first input of the first unit for calculating the ratio, the first input of the first adder and the first input of the display unit, while the second, third and fourth outputs of the first arithmetic unit are connected, respectively, with the first, second and third inputs of the second adder and the second output of the first arithmetic block is connected, in addition, with the second input of the first block of calculating the ratio, similarly, the first output of the second arithmetic block is connected to the first input the house of the second ratio calculating unit, the second input of the first adder and the second input of the display unit, while the second, third and fourth outputs of the second arithmetic unit are connected respectively to the fourth, fifth and sixth inputs of the second adder, and the second output of the second arithmetic unit is connected, in addition, also with the second input of the second unit for calculating the relationship, while the output of the first unit for calculating the relationship through the second threshold element is connected with the second input of the logical element And, and the output of the second unit of calculating relations through the third threshold element is connected to the third input of the logic element And, in turn, the output of the first adder is connected to the first input of the third block calculating the relationship, the second input of which is connected to the output of the second adder, and the output through the fourth threshold element is connected to the fourth input of the logical element And, and finally, the output of the logical element And is connected with the control input of the display unit.