RU2748934C1 - Method for measuring speech intelligibility - Google Patents

Abstract

FIELD: computer technologies.SUBSTANCE: method for measuring speech intelligibility provides for sequential measurement of theLcispeech signal levels andLMinoise levels for each octave band within the audible speech spectrum, as well as calculating the signal-to-noise ratio, where the values of the probability of hearing speech sounds for all octave bands are taken into account for calculating speech intelligibility, based on the normal distribution of a random variable, the probability of hearing speech sounds in each combination of octave bands, which make up a complete group of events, subject to the occurrence of events in which the octave bands may or may not participate in the calculations. The method is carried out using the product of the probability of hearing speech sounds in all combinationsP(Aj)by the probability of correct recognition of all words of the text, taking into account the audibility of speech sounds in all combinationsP(W | Aj).EFFECT: increased accuracy and reliability of measuring the level of speech intelligibility.1 cl

Description

The invention relates to measuring speech intelligibility and is intended to assess the protection of objects from unauthorized leakage of acoustic speech information.

One of the analogs of the proposed method for measuring speech intelligibility is the computational and experimental method of Professor Pokrovsky N.B., based on the sequential emission of individual tonal components of the audible spectrum at the place of transmission and determining by any experts the threshold of their audibility at the place of reception, and in fact, at the place of reception there may only microphones connected through amplifiers to expert headsets [1]. The level of acoustic radiation of each component is increased to the threshold of audibility by an expert. The fixed radiation levels are mathematically processed taking into account the human hearing curve and thus the minimum level of the speech signal is determined to obtain the desired speech intelligibility at the receiving site. The obtained information, of course, can also be used to determine the maximum level of the acoustic signal, at which speech at a given place of reception will be guaranteed to be illegible, i.e. the specified level of protection against leakage of acoustic information is provided.

However, this method is very time consuming as it requires the participation of many experts and time. In addition, the assessment of intelligibility is made not at the real level of acoustic signals, but at those that correspond to the hearing threshold at a given location. This is often unacceptable, since parasitic channels for transmitting acoustic information (walls, floors, windows, furniture, doors, etc.) usually weaken the frequency components of speech unevenly and the degree of information leakage protection calculated from the results of the described measurements may not correspond to the real ones.

The known method of operation of the device for measuring speech intelligibility [2], the essence of which is as follows.

The speech spectrum is divided into N contiguous bands with center and cutoff frequencies. For each band, the weighting coefficient κ _{i is} experimentally determined, which characterizes the probability of the presence of speech formants in a given octave band and the formant parameter ΔA _i , which characterizes the energy redundancy of a speech signal in a given adjacent band (redundancy is due to the presence of informal components in speech, which include fundamental tones, areas frequencies between formants and components depending on the individual characteristics of the speakers).

In each octave band, the levels of the speech signal L _ci dB are measured, and the noise levels L _wi dB, and the signal-to-noise ratio Q _{i is} calculated, taking into account the formant parameter ΔA _i and the probability of audibility of speech sounds p _i in all adjacent bands.

For each adjacent band, the spectral index of speech articulation R _{i is} calculated by multiplying the probability of hearing speech sounds p _i by the weighting factor κ _i . The sum of the spectral indices on all adjacent bands is the integral speech articulation index R, which is further used to calculate the speech intelligibility index W.

A significant disadvantage of this method is the possibility of obtaining an unreliable value of the speech intelligibility indicator in cases when:

deviations of the actual level of acoustic radiation from the preset in a previously unexplored room due to secondary acoustic signals reflected from the structural elements of the premises (walls, ceiling, window panes, furniture), from reverberation noise, from vibration, from magnetic, from formed in other ways, are not taken into account, for example, artificial acoustic interference created by equipment, engineering structures, human activities);

the signal-to-noise ratio in some adjacent (octave) bands will tend to zero (low signal-to-noise ratio).

One of the closest analogues of the proposed measurement method is the method for measuring speech intelligibility of Professor V.K. [3].

In this method, object correction of the measurement path is carried out, for which separate frequencies of the test signal of a given level are emitted in turn and at each frequency the actual levels of acoustic signals are measured at the place of their emission, the measured levels of acoustic signals are compared with the specified levels at the same frequencies, the deviations of the measured ones are determined. the levels of acoustic signals from the given ones and the frequency response of the measurement path is corrected to compensate for the difference between the given and measured levels of the test signals in the place of their actual radiation.

The proposed changes are allowed to eliminate one of the shortcomings of the previously described [2] method for measuring speech intelligibility, thereby increasing the accuracy of the result. However, at low signal-to-noise ratios, the results of calculating the speech intelligibility score will not be reliable.

The object of the present invention is to improve the accuracy and reliability of measuring the level of speech intelligibility.

A method for measuring speech intelligibility, providing for sequential measurement of speech signal levels L _ci and noise levels L _shi for each octave band within the audible speech spectrum, as well as calculating the signal-to-noise ratio, and characterized in that the values of the probability of hearing sounds are taken into account to calculate speech intelligibility speech for all octave bands based on the normal distribution of a random variable, the probability of audibility of speech sounds in each combination of octave bands that make up a complete group of events, provided that events occur in which octave bands may or may not participate in calculations, and is carried out with using the product of the probability of audibility of speech sounds in all combinations P (A _j ) by the probability of correct recognition of all words of the text, taking into account the audibility of speech sounds in all combinations P (W | A _j ).

The proposed method for measuring speech intelligibility is new because it does not use the existing formant approach.

This method uses the following features, which are applied for the first time:

the probability of audibility of speech sounds for all octave bands is carried out using the probability integral, which makes it possible to take into account the coefficients depending on the type of signal, type of noise and individual characteristics of auditors on the basis of the normal distribution of a random variable;

the probability of audibility of speech sounds in each combination is determined by the full group of events. The calculation takes into account all values (including low) of the signal-to-noise ratio for the combination of octave bands.

To carry out speech intelligibility measurements in this way, an acoustic signal receiver that calculates the acoustic signal level and active protection means (s) in the dedicated room is required.

The method for measuring speech intelligibility is carried out in the following sequence:

In each octave band, the level of the speech signal L _ci dB and the noise level L _shi dB are measured, and the signal-to-noise ratio q _i , dB is calculated:

In accordance with the calculated signal-to-noise ratios (q _i ), the probabilities of audibility of speech sounds in each octave band are determined by the formula:

- интеграл вероятности;Where:

- the integral of the probability;

q _i - signal-to-noise ratio in the i-th octave band, dB;

Q ₁ and Q ₂ are coefficients depending on the type of signal, type of noise and individual characteristics of auditors.

Based on the obtained probabilities of audibility of speech sounds, the probabilities of audibility of speech sounds for all combinations of octave bands P (A _j ) are calculated using the following formula:

where: B _i = P _i (Δf _i ) - an event in which the i-th octave band is present in the combination A _i ;

B _i = [1-P _i (Δf _i )] - an event in which the i-th octave band is absent in the combination A _i ;

P _i is the probability that the operator will hear speech sounds in the i-th octave band with the measured signal-to-noise ratio in the octave band equal to q _i .

The calculation of the probabilities for each combination is determined by the full group of events, in which all octave bands are included in the calculation, and represent the following formulas.

Next, the total speech intelligibility W is calculated using the formula:

where: W _j - verbal speech intelligibility for the case when the operator hears speech sounds in A _j combination;

P (A _j ) is the probability that the operator will hear speech sounds in A _j combination with the signal-to-noise ratio in octave bands equal to q _i ;

P (W | A _j ) - the probability that the operator correctly recognizes all words of the text, provided that he hears the sounds of speech in A _j combination. These values of probability are determined on the basis of experimental studies in accordance with the method of Professor N.B. Pokrovsky. [one];

n is the number of combinations of octave bands;

N is the number of octave bands.

The obtained value is compared with the required value of the speech intelligibility indicator and a conclusion is made about the effectiveness of the protection of acoustic speech information and the completeness of the applied information protection means.

For the practical implementation of the proposed technical solution, it is necessary to use two types of tools:

acoustic or acoustic vibration measuring devices (sound level meters or vibration meters) that measure the level of an acoustic signal;

active protection means that protect information from its leakage through technical channels in a dedicated room.

Thus, the proposed method made it possible to increase the accuracy and reliability of measuring the level of speech intelligibility due to:

determining the probability of audibility of speech sounds for all octave bands using the probability integral, which made it possible to take into account the coefficients depending on the type of signal, type of noise and individual characteristics of auditors on the basis of the normal distribution of a random variable;

use of low values of the signal-to-noise ratio in calculations;

determining the probability of correct recognition of words in the text.

Information sources:

1 Pokrovsky N.B. Calculation and measurement of speech intelligibility. - M .: Svyazizdat, 1962 .-- 391 p.

2 Utility model RU No. 27259, published 10.01.2003.

3 RF patent RU No. 2284585, published 09/27/2006, Bul. # 27 - prototype.

Claims (1)

Method for measuring speech intelligibility involving sequential measurement of speech signal levels Lci and noise levels LMi for each octave band within the audible speech spectrum, as well as the calculation of the signal-to-noise ratio, and characterized in that for calculating speech intelligibility, the values of the probability of audibility of speech sounds for all octave bands are taken into account based on the normal distribution of a random variable, the probability of audibility of speech sounds in each combinations of octave bands that make up a complete group of events, subject to the occurrence of events in which octave bands may or may not participate in calculations, and is carried out using the product of the probability of audibility of speech sounds in all combinations P (Aj ) on the probability of correct recognition of all words of the text, taking into account the audibility of speech sounds in all combinations P (W | Aj).