RU2148277C1 - Method for detection and correction of anomalous digital errors, when voice is transmitted using pulse-code modulation - Google Patents

Abstract

FIELD: digital processing of voice signals, which are transmitted through communication lines. SUBSTANCE: method involves detection of adjacent high-level doubled (having opposite signs) leaps in level of first derivative of voice signal by means of storing previous piece of voice signal, measuring mean absolute value of first signal derivative during this piece by means of accumulation of absolute values of difference between two adjacent PCM signal samples and setting two identical adaptive opposite-sign thresholds which are proportional to mean absolute value of first derivative. If two adjacent PCM signal samples exceed thresholds, anomalous digital error is detected and corrected by means of alternating inversion of high-order bits of PCM code, until doubled leaps of first derivative are removed. EFFECT: decreased requirements for noise protection of communication lines, decreased cable cost, or increased length of retransmission lines, or increased relative number of pairs to be compressed in cables, while keeping constant subjective perception quality of voice. 4 dwg

Description

 The present invention relates to techniques for digital processing of speech signals transmitted over communication lines by the method of pulse-code modulation (PCM) and can be used to increase the noise immunity of multi-channel digital telephony transmission systems.

 Known / 2 / is a method for detecting digital errors (false pulses) as part of a PCM code combination, based on the transmission of a bipolar quasitronic code (code with an NPS-alternation of pulse polarities) via a communication line. Violation of the bipolarity of the pulse sequence in the communication line indicates the presence of a digital error.

 The disadvantage of this method is the imperfection of the NIP code itself, which may contain pulse sequences with more than three spaces following in a row, which may lead to disruption of clock synchronization in the communication system.

 The closest technical solution (prototype) can be considered the method of / 1 / detection of digital errors (false pulses) as a part of PCM code combinations, based on the transmission via the communication line of a more advanced quasi-ternary code (a code with MPPI-alternating pulse polarities, in which violations bipolarity in the form of inserts of pairs of pulses of the same polarity). Violations of the bipolarity of the MPPI code are alternated in polarity, due to which it is possible to detect errors in the digital signal by violations of this alternation.

 The disadvantage of this method of detecting digital errors is the inability to correct false impulses on its basis due to the small redundancy of the quasi-ternary code with the MPPI.

The presence of digital errors causes the so-called false noise noise on the receiving side, which reduces the quality of digital telephone communications. Particularly dangerous / 1, 2 / are abnormal digital errors associated with the transformations of two high-order bits of a nonlinear PCM code. These errors are accompanied on the receiving side by pulse-like “clicks” that are unpleasant for subscribers and sharply worsen the quality of speech reproduction. The normalization of anomalous errors (at the level of not more than one “click” per minute) places high demands on the quality of communication lines designed for PCM speech transmission (the admissible error probability per one regeneration section should not exceed _Psh = 10 ^-6 ).

 Correction of anomalous digital errors will reduce the requirements for noise immunity of communication lines, use a cheaper cable, or increase the length of the regeneration sections, or increase the relative number of compressed pairs in the cable by PCM systems while maintaining the subjective perception of speech quality unchanged.

 The technical result of the invention is to improve the reception quality of voice signals transmitted digitally using PCM via communication lines with low noise immunity.

 The essence of the proposed method for detecting and correcting anomalous digital errors during PCM speech transmission is to monitor the successive increased double (different signs) level jumps of the first derivative of the speech signal based on storing the previous section of the speech signal, measuring the average module of the first derivative of the signal during this interval, by accumulating the difference modules of two adjacent PCM samples of the signal and setting two identical adaptive thresholds of different signs, p proportional to the average module of the first derivative, the excess of which in succession with two current differences of adjacent PCM signal samples allows us to detect a code combination containing an anomalous digital error, the correction of which consists in the inverse of one of the two upper bits of the PCM code until the double ones are eliminated "jumps" of the first derivative.

 In FIG. 1 (a-d) are timing diagrams of signal processing illustrating the proposed method for detecting and correcting anomalous digital errors in PCM speech transmission.

 In FIG. 1a shows an initial transmitted sample sequence of a speech signal, and FIG. 1b is a distorted received sequence of samples of a speech signal due to erroneous reception of the highest (sign) bit of the PCM code of one of the samples. The transformation of the reference sign in this case led to the appearance of impulse noise of a significant level, perceived by ear as an unpleasant click.

 The pause in the signal (“silent mode”) in FIG. 1a corresponds to the appearance of a click in FIG. 1b due to distortion of the second bit of the PCM code (high-order bit of the signal reading module).

 Thus, abnormal digital errors (in the two high-order bits of the code) lead to significant impulse noise both in talk mode and in speech pauses. Studies / 2 / showed that the distortions of the remaining six least significant bits of the nonlinear PCM code do not cause pulse noise such as clicks, but are perceived as a relatively small noise, the disturbing effect of which is much weaker. Therefore, the elimination of abnormal digital errors will lead to a marked increase in the quality of speech perception in digital transmission.

In FIG. 1c shows a graph of a first derivative of a speech signal proportional to the difference of two adjacent samples. As can be seen from the figure, the anomalous error is accompanied by two jumps in the first derivative of a signal of a different sign, one after the other. In the absence of such errors, the double jumps of the first derivative of an increased level are not observed in natural speech. This is due to strong correlation between adjacent samples of the speech signal. According to / 2 /, such relations cover up to ten consecutive samples, since speech has a lot of redundancy. The energy spectrum of the speech signal is sharply uneven, has a rise in the frequency range (400-500) Hz and a fast decline (with an average speed of 9 dB per octave) in the frequency range (500 - 4000) Hz. Since the repetition rate of the signal samples at PCM f _d = 8 kHz is significantly higher than the frequency range in which the main speech energy is concentrated, the signal changes relatively slowly and the average changes are insignificant during the action of two neighboring samples. In other words, large levels of the first derivative in the speech signal are not expected. Studies on real speech show that the average module of the derivative of the speech signal for male voices is 4-5 times, and for female and children's voices 3-4 times less than the average signal modulus. Moreover, the distribution of instantaneous values of the first derivative of the speech signal is well approximated by the normal law with a zero mean value and dispersion, on average, 10-20 times less than the variance (power) of the speech signal.

 Adaptive thresholds for the acceptable values of the first derivative of the speech signal should be selected from compromise considerations. On the one hand, the thresholds should be high enough so that rare natural increases in the instantaneous values of the first derivative of speech are not mistaken for an anomalous digital error and are corrected, which will lead to distortions in the speech signal. On the other hand, the thresholds should be lowered as far as possible in order to more reliably detect and further correct all significant digital errors that are perceived as “clicks” by ear.

 This contradiction can be resolved due to the fact that in the speech signal there are practically no double jumps of the first derivative of a different sign, accompanied by a double jump in the level of the second derivative, the graph of which is shown in FIG. 1g As studies on real speech signals showed, the average module of the second derivative of speech was comparable with the average module of the first derivative of speech.

 Thus, a double excess of the first derivative of speech of two adaptive thresholds of a different sign is equivalent to a single excess of the second derivative of a double threshold (Fig. 1d), which is completely unrealistic. This is confirmed by the fact that in natural speech, no realizations that are perceived by ear as “clicks” are ever observed.

Assuming that the distribution of instantaneous values of the first derivative of the speech signal is normal, it is advisable to set adaptive thresholds (Fig. 1c) at the level of the order of ± (2-3) U _Eff , where U _Eff is the effective (effective) value of the first derivative of the speech signal, measured in the previous signal. Since the measurement of the effective value of a random process is associated with significant difficulties, it is much easier to measure the average signal modulus U _cf proportional to the effective value. For a normal process, the relationship is known:

Hence the value of the adaptive threshold:
U _then = (2-3) U _eff = (2.5-3.75) U _cf
Thus, the detection of “clicks” is directly related to the formation of adaptive thresholds with which the current values of the first derivative of the speech signal are compared. The average value of the modulus of the first derivative U _cf should be measured in advance at the previous analysis interval T _{a of the} speech signal.

The choice of T _as well is determined by compromise considerations. On the one hand, the analysis interval should be sufficiently large and contain many samples of the speech signal for reliable averaging of the module of the first derivative and for obtaining a reliable value of U _cf and a proportional threshold level of U _pores . On the other hand, during the time T _{a, the} parameters of the speech signal should not noticeably change, that is, the information on the threshold value obtained in the previous analysis interval should not become obsolete during the entire subsequent analysis interval T _a .

It is known that the interval of stationarity of the speech signal T _st , during which the speech parameters remain virtually unchanged, approximately coincides with the duration of the shortest sound and is (20 - 30) m • s. The choice of the interval T _{a of the} order of half T _st , T _a = T _st / 2 = (10-15) m • s is optimal. During this time, (80-120) PCM samples of the speech signal pass, which is quite enough for reliable averaging of the first derivative module. At the same time, on the interval 2T _a = T _article information about the value of the adaptive threshold U _then remains reliable.

 After detecting a double jump of the first derivative, which is expressed in the successive exceeding of both thresholds of a different sign, it is necessary to correct the anomalous digital error. To do this, you need to determine which of the two upper bits of the PCM code is distorted.

 If the communication channel is in silent mode, an unambiguous conclusion will follow that the second bit of the nonlinear code has undergone distortion, that is, the senior bit of the signal sample module, since the distortion of the sign of low-level samples does not lead to large jumps in the derivative. Inversion of the second bit of the code will prevent unpleasant impulse noise during speech pauses.

 If the communication channel is in active mode, that is, a speech signal is transmitted through it, the task of correcting the “false bit” is somewhat more complicated. And in this case, sometimes, for some reasons, it is possible to avoid enumeration of two possible alternatives and unambiguously indicate the number of the inverted code bit.

 So, for example, if the sign of the detected count differs simultaneously from the signs of the previous and subsequent counts, a decision will be made on the inversion of the sign digit of this count.

 If the sign of the detected sample coincides simultaneously with the signs of the previous and subsequent samples, the decision will be made on the inversion of the second bit of the code, namely the highest bit of the signal sample module.

 If the sign of the detected count coincides with the sign of the previous one and is opposite to the sign of the subsequent (or vice versa), then it will not be possible to immediately make an unambiguous conclusion about the number of the distorted discharge. In this case, it is necessary to invert the signs of the first and second digits of the code. After the first inversion, a check is made to see whether the double jump of the first derivative of the signal, exceeding the set thresholds, is preserved or not. If the jump has disappeared, the conclusion will be that the “click” correction is complete. If the double jump of the first derivative of the signal is preserved, it will be concluded that the first inversion of the sign was erroneous, it should be canceled and invert another bit of the code.

Literature:
1. Golubev A.N., Ivanov Yu.P., Levin L.S. and other equipment PCM - 120. - M .: Radio and communications, 1989. - 256 p.

 2. Gurevich V.E., Lopushnyan Yu.G., Rabinovich G.V. Pulse code modulation in multichannel telephony. - M .: Communication, 1973. - 336 p.

Claims (1)

 A method for detecting and correcting anomalous digital errors in speech transmission by pulse-code modulation (PCM), characterized in that they track the successive increased doubles of different signs of “jumps” in the level of the first derivative of the speech signal based on storing the previous speech signal segment, measuring the average module of the first derivative of the signal over this segment by accumulating the modules of the difference of two adjacent PCM samples of the signal and installing two identical adaptives thresholds of different signs proportional to the average modulus of the first derivative, exceeding which in succession with two current differences of adjacent PCM signal samples allows us to detect a code combination containing an anomalous digital error, the correction of which consists in the inverse of one of the two highest bits of the PCM code until until the double jumps of the first derivative are eliminated.