SU1631580A2 - Method for word boundary and device thereof - Google Patents

Abstract

The invention relates to a technique for analyzing and recognizing speech signals and can be used in control, information and calculation and reference systems in a changing ambient noise environment. The purpose of the invention is to improve noise immunity in determining word boundaries by automatically correcting the values of the time parameters used. depending on the nature of the change in the level of surrounding unsteady noise. To do this, during constant time intervals of the analysis of the ambient noise environment, their level is measured. For the implementation of the method, an input signal conversion unit 3, a time value memory block 2, a boundary recorder 1 and a control unit 4 are used. 2 sec. f-ly, 7 ill.

Description

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The invention relates to a technique for analyzing and recognizing speech signals and can be used in control, information and computational and reference systems in a changing ambient noise environment,

The aim of the invention is to improve noise immunity in defining word boundaries by automatically correcting the values of temporal characteristics depending on changes in the level of ambient noise.

Fig. 1 shows the implementation principle of the proposed method by the example of correcting the time characteristic of Ti as a function of a change in the level of surrounding noise; in fig. 2 is a block diagram of a device for detecting word boundaries; FIG. 3 is a block diagram of a word boundary recorder; Fig. 4 is a functional block diagram of the control unit; in fig. 5 is a block diagram of a word storage unit; in fig. 6-functional input signal converter circuit; in fig. 7 is a functional diagram of a pulse timing device.

A device for detecting word boundaries contains a word boundary recorder 1, a characteristic memory unit 2, an input signal converter 3, and a control unit 4.

The first inputs of the word boundary recorder 1 and the converter 3 of the input signal are connected to the input bus of the analog signal of the device. The second input of the converter is connected to the first input of control unit 4 and the first auxiliary output of recorder 1, the second auxiliary output of which is connected to the corresponding second input of block 4, whose output connected to the third input of converter 3 and the first additional input of recorder 1. The output of converter 3 is connected to the input of block 2 of characteristics memory, the first to third g groups of outputs of which are connected respectively to the first - third additional groups of inputs of the recorder 1, the second input of which is connected to the second input of the device, and the output is connected to the output of the device,

The word boundary recorder 1 is designed to register word boundaries in the unsteady nature of the surrounding background noise (Fig. 3). Registrar 1 consists of a signal conditioner 5, a time ratio generator 6, and a word storage unit 7. The first input of the recorder 1 is connected to the input of the imaging unit 5, the first and

The second outputs of which are connected to the first and second inputs of the imager 6. The first additional input of the recorder 1 is connected to the third input of the imager 6.

The first - third additional groups of inputs of the registrar 1 are connected respectively to the first - third groups of inputs of the imaging unit 6, the fourth - the sixth inputs of which are connected respectively to the first - third outputs of the unit 7, the first output of the imaging unit 6 is connected to the first input of the unit 7 and the first additional output of the recorder 1 second

the output of the imaging unit b is connected to the second additional output of the recorder 1, the third to the sixth outputs of the imaging unit 6 are connected respectively to the second - fifth inputs of the block 7. The second input of the registrar 1 is connected to the information input of the block 7, the information output of which is connected to the output of the recorder 1. . 3 shows the initial setup of the recorder 1, which is connected to the sixth and

to the seventh inputs of the word storage unit 7 and the imaging unit 6 timing pulses, respectively.

Shaper 5 characteristic

The signals are designed to form two characteristic signals fA from the input audio signal and the functional diagram of the driver 5 fully corresponds to the prototype.

Shaper 6 pulses of time ratios (Fig. 7) is designed to generate the necessary signals used when the word boundary detection algorithm is adopted in the prototype, as well as

0 shaping the signals that control the moment of adjustment (adaptation) to the surrounding conditions. For this purpose, the shaper 6 has one additional output that is connected to the second additional

5 to the output of the recorder 1, i.e. to the second input unit 4 controls. In the event that a probable initial word boundary is detected and the truth of it is verified by shaper 6, due to the presence of this output, shaper 6 prohibits block 4 from generating a time correction enable signal. If the detected initial word boundary turned out to be false, then, due to the additional inputs of the imaging unit 6, the temporal characteristic values are corrected; otherwise, the specified correction will be made after reading the detected word from the word storage unit 7.

The shaper 6 pulses of time ratios consists of the first - third registers 8-10, the first and second detectors 11 and 12 of the pulse front, the first - the third detectors 13-15 pulse decay, the first - fifth counters 16-20 time intervals, the first - the eighth flip-flops 21-28, the first - the fifth elements OR NOT 29-33, the first and second inverters 34 and 35, the first - the thirteenth elements AND 36-48, the first - the eleventh elements OR 49-59, the first and second elements 60 and 61 delays .

Registers 8-10 are designed to receive and store the values of the temporal characteristics of Ti-T3, respectively.

Counters 16-18 are designed to compare the parameters of the input audio signal with the values of the temporal characteristics stored in registers 8-10 when searching for the initial boundary of the layer.

The trigger 28 is used to form prohibitive correction of the temporal characteristics of the signals in those time intervals when the truth of the detected initial word boundary is checked or the final word boundary is searched.

Elements 36-39, detectors 13 and 14, elements OR-NOT 29-31 and element OR 49 are designed to overwrite the contents of registers 8-10 into counters 16-18 in the event that the detected initial word boundary was false and it became necessary to prepare shaper to the analysis of a new probable initial word boundary.

Element OR 51 and delay elements 60 and 61 are intended to provide a signal that permits the recording of information in registers 8-10 and counters 16-20.

The elements 43 and 44, the inverter 34, the element OR 52 and the trigger 23 are intended to form a second characteristic signal.

Counters 19 and 20, elements AND 45-47, elements OR-NOT 32 and 33, inverter 35, elements OR 53 and 56, triggers 24 and 25, and detector 12 of the pulse front implement the prototype word search algorithm adopted in the prototype,

Elements 40-42, elements OR 54-55, 57-58, and triggers 22, 26, and 27 are designed to issue control commands to the storage unit 7, Acceptance of the starting boundary, Initial blocking, Accepting the end boundary, Final blocking, Turning on.

The first input of the imaging unit 6 is connected to the third and first inputs of the elements And 43 and 44, respectively, the second input to the second input of the element And 37, the inputs of the detector 5 of the pulse front and inverter 34, the second input of the element And 43 and the third inputs of the elements And 45 and 47, and the third input - to the first and third inputs of the elements OR 51 and 52, respectively. ten

The first - third additional groups of inputs of the imaging unit 6 are connected to the information inputs of the registers 8-10, respectively.

5 The fourth input of the imaging unit 6 is connected to the third, second and first inputs of the And 37-39 elements, respectively, as well as to the first and fourth inputs of And 46 and 47 elements, respectively.

0 The th input of the imaging unit 6 is connected to the input of the installation in the unit of the trigger 27. The sixth input of the imaging unit 6 is connected to the third inputs of the elements OR 50 and 59, the first input of the element OR 55, and

5 to the second inputs of the elements OR 57 and 58.

The seventh input of the initial installation of the driver 6 is connected to the inputs of the R counters 16-20. the second inputs of the elements OR 51, 52, 55 and 59, the first inputs of the elements OR 53, 56-58 the first input of the element

And 43 and the fourth input element OR 50.

The outputs of registers 8 and 9 are connected

respectively to the information inputs

counters 16, 20 and 17, 19, and the outputs of the register

5 10 - to the information inputs of the counter 18. The output of the detector 11 is connected to the second inputs of the elements 40 and 41. The output of the inverter 34 is connected to the third inputs of the elements 38 and 46, the input of the detector 15, and

0 also with the second inputs of the element AND 44 and the element OR 53. The output of the element OR 51 is connected to the input of the first delay element 60, the output of which is connected to the inputs C of registers 8 and 9, as well as to the input of the second

5 elements 61 delays. The output of the delay element 61 is connected to the first inputs of the OR-NOT 29-31 elements, as well as to the second inputs of the OR-NOT elements 32 and 33. The output of the AND 43 element is connected to the installation input

0 in the unit of the trigger 23, the input of which is set to zero is connected to the output of the element OR 52. The output of the element AND 44 is connected to the fourth input of the element OR 52. The single and zero inputs of the trigger 24 are connected respectively to the outputs of the element 45 and the element OR 53. Inverse the output of the trigger 24 is connected to the second input element And 45 and the input of the detector 12, the output of which is connected to the third input of the element OR-HE 33, the output of which

connected to the input V of the counter 20. The output of the trigger 23 is connected to the inverse of the fourth and first inputs of the elements And 37 and 38, the second input of the element And 39, as well as the input of the detector 14, the output of which is connected to the third input of the element OR 49 and the first inputs of the elements OR 50 and 59. The output of the detector 15 is connected to the first inputs of the AND 42 and 48 elements, as well as to the second input of the AND 36 element, the output of which is connected to the second input of the OR 49 element. The output of the OR 49 element is connected to the second inputs of the OR-NOT 29- elements 31, the outputs of which are connected to the inputs of the V counters 16-18 respectively -retarded. The output element And 37 connected to the input -1 of the counter 16, the output of which is connected to the inverse input S of the trigger 21. The output of the element 38 is connected to the input -1 of the counter 17, the output of which is connected to the inverse second inputs of the elements OR 50 and 59, the outputs of which are connected respectively, with the inputs R of the flip-flops 21 and 28. The direct output of the trigger 21 is connected to the first input of the element AND 40, the fourth input of the element 38 and the input of the detector 13. The output of the detector 13 is connected to the first input of the element OR 49. The inverse output of the trigger 21 is connected to the first the inputs of the elements And 36, 37 and 41 and W To the input of the element And 48. The output of the element And 39 is connected to the input -1 of the counter 18, the output of which is connected to the second inverse of the element OR 54, the first input of which is connected to the output of the element 40. The single and zero inputs of the trigger 22 are connected respectively to the outputs the elements OR 54 and 55. The inverse output of the trigger 22 is connected to the third input of the element AND 41, the output of which is connected to the third output of the driver 6 pulses, as well as to the input of the installation of the trigger 28 in the unit state. The output of the trigger 28 is connected to the second output of the driver 6. The output of the element 48 is connected to the fourth input of the element OR 59, the direct output of the trigger 22 is connected to the first output of the driver 6 of pulses, the second inputs of the elements 42, 46 and 47, the third inputs of the elements OR- NOT 2.9-31, the first input element OR 52 and the third inverse input element AND 43. The output element And 42 is connected to the fourth output of the imaging unit 6 pulses. The output of the element And 46 is connected to the input -1 of the counter 19 and the input S of the trigger 25. The output of the element OR NOT 32 is connected to the input V of the counter 19, the output of which is connected to the inverse of the third input of the element OR 56 and the inverse of the single input of the trigger 26. The output of the element And 47 is connected to the input

-1 counter 20 and the first input element And 45. The output of the counter 20 is connected to the input of the inverter 35, the output of which is connected to the second input of the element OR 56 and the third

the input element OR - NOT 32, the output of which is connected to the V input of the counter 19. The output of the element OR 56 is connected to the input R of the trigger 25, the output of which is connected to the first input of the element AND 47. The output of the element

OR 57 is connected to the input R of the trigger 26, the output of which is connected to the fifth output of the imaging unit 6 pulses, the fourth inverse input of the AND 46 element and the first inputs of the OR 32 and 33 elements. The output of the OR 58 element is connected to the input R of the trigger 27, the output of which is connected to the sixth output of the driver 6 pulses

The word storage unit 7 (Fig. 5) is intended to organize the recording of the input audio signal in the memory unit and then reading the detected word from the memory unit in its true bounds. The elements and connections of block 7 are completely identical to the prototype device, except that the driver 5 of the characteristic signals and the driver 6 of the temporal ratio pulses are made separately (Fig. 3), and the temporary ratio pulse generator is made with a number of additional inputs and outputs.

The word storage unit 7 comprises first to fourth switches 62, 63, 69 and 68,

a counter of 64 addresses, first and second registers 67 and 70 of address, first and second blocks 66 and 71 of comparison, block 65 of memory, and on. the inputs of the first and second switches 62 and 63 are given two types of clock signals, and their

the outputs are connected to the inputs of the counter 64 addresses. The output of the switch 62 is connected, in addition, with an additional output of the storage unit 7. The output of counter 64 is connected to the nepsoN J control input of block 65

a memory, the information input of which is connected to the information input of block 7, and the second control input is connected to the output of the first comparison block 66, as well as to the third output of block 7. Two inputs of the block

0 66 comparisons are connected respectively to the output and the input of the register 67 of the address connected to the output of the counter of 64 addresses. First, second and third, fourth inputs of block 7 are connected in pairs, respectively, to the inputs of the third 68 and fourth 69 switches, the outputs of which are connected to the inputs of the corresponding registers 67 and 70. The output of the second register 70 is connected to the first input of the second block 71, the second input of which is connected the output of counter 64 and the input of the second register 70, and the third input to the control inputs of the first 62, second 63 and fourth 69 switches, the third input of the memory unit and the fourth input of the storage unit 7. The output of the second unit 71 is connected to the second output of the unit 7 and the fourth input of the unit 65, the second input of which is connected to the third output of the storage unit 7. The fifth input of the storage unit is connected to the third input of the first unit 66. The information output of the unit 65 is connected to the information output of the unit 7.

Characteristic memory unit 2 is designed to store various values of the used temporal characteristics. On a command from the converter 3 of the input signal, it connects to the recorder 1 word boundaries of such values of the used temporal characteristics that best suit the level of the surrounding background noise. The input of memory block 2 is connected to the output of the converter 3 of the input signal, and the three outputs of memory block 2 are connected to the corresponding second and fourth additional inputs of the recorder 1.

The input signal converter 3 is designed to continuously measure the level of the ambient noise background during the TA analysis time intervals and after each such noise analysis interval of the address generation environment, according to which the time characteristics corresponding to this noise level are read from memory block 2. In the event that a true initial word boundary is detected, the device stops estimating the level of the input audio signal and resumes the measurement of the noise level upon detection of the true final word word. In this case, if the probable initial word boundary is announced, the assessment of the level of the input audio signal does not stop, and if this initial word boundary turns out to be false, then correction of the temporal characteristic values occurs, and if the detected initial margin is confirmed, then the measurement results The level of the input audio signal is annulled and the process of measuring the level of the input audio signal is resumed after the detection of the true probable final word boundary.

The input signal converter 3 (Fig. 6) consists of a generator 72 synchronous pulses, a counter 73 of the time interval Td, a trigger 74, an input amplifier 75, a detector 76. an integrator 77, an analog-digital converter 78, a register 79, 5 of the first - third elements And 80-82, the first - the sixth elements OR 83-88. first - second delay elements 89-90 and block 91 elements; And the first input of converter 3 is connected to the input of amplifier 75, the output of which is connected to the input of detector 76, the output of which is connected to the input of integrator 77, the output of which is connected to the input of analog-digital converter 78 The output of which is connected to the information input of the register 79, the output of which is connected to the second inputs of the element block / 91, the output of which by the output of the converter 3 The second converter 3 is connected to the first input of the element OR 87 you — from which inen with the inputs of the setup B.ulip counter 73 and register 79 a Tgzhe with the second inputs of the elements OR 83 and 68 1 the input of the converter 3 is connected to the second input

5 elements and 80 ne ;. the first input element And 82 and the second input e- | and 81. Input The initial installation of the converter 3 is connected to the second input of the element OR 87, as well as to the input of the generator 72, the output of which is connected to the counting input of the counter 73, the output of which is connected to the first inputs of the elements 80 and 81 of the output of the element 80 connected to the input of the delay element 89, the first input of the element OR 86 and the second

5 to the input element IL - 85 8, the element SE 81 is connected to the input S of the flip-flop 74, the first input of the element OR 85 and the second input of the element OR 86 The output of the element OR 83 is connected to the input R of the trigger 74, output

0 which is connected to the second input of the element And 82 and the third inverse input of the element AND 80. The output of the epiment And 82 is connected to the first input of the element OR 83, as well as to the second input of the element OR 84,

5 the first input of which is connected to the output of the delay element 89 The output of the OR element 84 is connected to the first inputs of the block of elements AND 91. The output of the OR 85 element is connected to the input of the delay element 90,

0 whose output is connected to the first input of the element OR 88, the output of which is connected to the input C of the integrator 77 The output of the element 86 is connected to the input C of the register 79

5Block 4 control is intended for

control of device adaptation moments to changing noise conditions; Control unit 4 consists (Fig 4) of time interval counter 92 T, trigger 93, pulse generator 94 of pulse decay detector 95, first to third elements OR 96-98, first to third elements AND 99-101. The first input of block 4 is connected to the first input of the element OR 97, the second input of the element OR 96 and the element AND 101, as well as to the third input of the element AND 100, the Second input of block 4 is connected to the second and first inputs of the elements 99, 100 and 102, respectively, as well as to the input of the detector 95, the output of which is connected to the third input of the element AND 101. The input The initial installation of block 4 is connected to the first inputs of the generator 94 and the element OR 96, the output of the generator 94 is connected to the counting input of the counter 92, the input of which is set to zero the output of the element OR 96, and the output - with ne With the primary and second inputs of the And 99 and 100 elements, respectively, the Single and zero inputs of the trigger 93 are connected to the outputs of the And 100 and OR 97 elements, respectively. The output of the trigger 93 is connected to the first input of the element AND 101, the output of which is connected to the second inputs of the elements OR 97, 98 and 100. The output of the element AND 99 is connected to the first input of the element OR 98, the output of which is connected to the output of the control unit 4.

The requirement for the stationarity of ambient noise in the prototype makes it possible to consider the expectation and variance of these random variables stable over time. Using a constant in time, the average value of the duration of the pulses and pauses of the characteristic signals, using a given algorithm, compare these characteristics with constant values The time characteristics of the sound signal Ti, T2, and Tz, where Ti is the maximum duration of non-speech-like sound interference at the input; Ta is the maximum duration of the section of the deaf link of the speech signal, the level of which does not exceed the level of stationary sound noise; Ts is the minimum duration of the inherent speech time interval from the moment of sound occurrence to the appearance of a blind link.

FIG. 1., a, b depict the probability density of the duration of the emission of a noise signal with the expectation m {Tim} and the duration of the emission with the expectation m {Tip}. The choice of the magnitude of the characteristic Ti with a certain reliability is used to classify the input signal emissions into noise and speech. The double hatching area in FIG. 1, and corresponds to the case of a false classification of the noise emission as a speech for the prototype. Similarly, T and T3 values are selected for analysis of the input signal. All the temporal characteristics of the Ti-T3 remain constant throughout the entire period of operation. However, the actual acoustic noise is not stationary. The random characteristics of such noise vary over time. Comparison of these characteristics with constant values of TI - T3 values leads to deterioration of the device performance. So, increase

0, the noise level leads to a shift to the right of the mathematical expectation of the duration of the emission of the noise signal (Fig. 1, a), which, due to the constancy of TI, entails an increase in false classifications of noise emissions as speech (see the horizontal shaded area in Fig. 1, and ), This circumstance leads to an increase in the number of false positives of the device. In the case where the noise level

0 decreases, a shift to the left of the expected value of the noise emission relative to the threshold levels occurs. Favorable conditions are created to reduce the number of passes by the device.

5 true boundaries of the word. However, in the prototype. This does not occur, since the speech signal is compared with a fixed value of Tg (see the vertical hatching area in Fig. 1, b). Thus, fixing the temporal characteristics Tg Tz, which are designed to separate the speech signal from the noise, deprives the prototype of its flexibility and ability to self-adapt to changes in the surrounding noise environment. As a result, the prototype has low confidence values in the definition of word boundaries when operating under real unsteady ambient noise conditions. In the proposed method

0 additionally measures the level of ambient noise during a fixed time interval of the analysis of the ambient noise environment, and using the results of this analysis, the values of the used time characteristics Tr-Tc are corrected. Thus, if an increase in the noise level is observed, which leads to a shift to the right of the density graph of the probability of the duration of the noise emissions above the threshold level, then

0 if, in proportion to this bias, to increase the value of the temporal characteristic T, there will be a decrease in the likelihood of determining false word boundaries (Fig. 1, a). If during

5 time analysis of the background noise level, a decrease in its magnitude is observed, which leads to a shift to the left of the probability density plot of the ejection noise above the threshold level, then, if proportional to this displacement,

A decrease in the value of the time characteristic of Ti will decrease the likelihood of skipping the word boundaries (Fig. 1, b). When correcting the values of the temporal characteristics of Tu and Tz, similar reasoning is taken into account.

For example, with an increase in the noise level, an increase in the average emission duration of the random noise signal is observed. This is equivalent to a shift to the right of the probability density distribution of the duration of the emissions, which is approximated by the straight lines y - ax + b and is an equilateral triangle (Fig. 1, c). The horizontally shaded area in FIG. 1, and corresponds to the case of incorrect classification by the prototype of the duration of the ejection relative to the constant value of the time characteristic TV.

The quantitative estimation of the number of incorrect classifications of the input signal of the prototype and the parameter Ti are determined as follows:

B + s

A / (-ax + b + bi) dx, (1)

where the expression y (-ax + b + bi), a, b, bi 0 is the equation of the direct approximation of the right-hand side of the density distribution curve of the probability of the duration of the emissions (Fig. 1, c);

bi is the magnitude of the shift to the right of the density distribution graph of the probability of the duration of emissions of the noise signal.

The limits of integration of expression (1) are obtained from the joint solution of the equations describing the right and left sides of the probability distribution diagram of the durations of noise and speech emissions, respectively, as well as when constructing an approximating noise density distribution function

tg, (2)

a + ar

where a, b and ap lp are positive coefficients in the direct equations that approximate the probability density curves of the duration of the emissions of noise and speech, respectively.

b + bi

 (Kbi + c) 2 (3)

where k

a + af 4a2

(four)

an b - a bp ,

с --- - constant coefficients

you.

Thus, the classification error of the parameter Ti depends on a quadratic law on the magnitude of the shift of the average duration of emissions of the noise signal bi. Therefore, such an offset needs to be compensated for by a proportional offset of the time parameter TL used.

Then the corresponding number At - the number of false classifications of the input signal by the prototype according to the parameter Ti will look like

h + s

(- ah b f- bi) dx

i 3

1 b + bn + Ы

(five)

thirty

(6)

Where

4a2 3p b - a bp

c 17T

constant coefficients.

As follows from the comparison of the constants K and «1, the number of false positives AI in the second case is less than D in the first case

Similarly, it is possible to show the possibility of achieving a positive effect while reducing the noise level and shifting to the left as a result of this graph of the average duration of the emissions of the noise signal.

The device for detecting word boundaries under the conditions of unsteady sound noise operates as follows.

After initial device installation

0 (not shown in Fig. 2) all the blocks are reset (all operations occurring in each block according to the Initial Setup signal will be described below as the operation of this block is described). AT

5, as a result of performing the specified initial setting from the output of the parameter memory block 2, the initial values of the time characteristics Tr-Tz will be read into the word boundary recorder 1. The input audio signal or its parameters in digital

the form begins to flow into recorder 1, where it is written to the memory block. At the same time, the same audio input signal in analog form is fed to the input of converter 3 of the input signal and to the input of boundary recorder 1, where it is used to generate the first and second characteristic signals. In the converter of the input audio signal, the level of ambient noise is measured during fixed time intervals analyzing the ambient noise level TA. These equal time intervals are formed by the control unit 4; Each reasonable value of the surrounding acoustic noise level is a priori one-to-one correspondence between the values of the time parameters T3 in the characteristics memory block 2. After the TA analysis time has elapsed, the digitized value of the input audio signal during the TA time appears at the output of converter 3. This digital code is an address at which the new corrected values of the used time parameters Ti –Tc are read out from block 2 of the characteristics memory for further processing in registrar 1. Thus, according to the signal from block 4, the device is adjusted or self-adapted to the changed external conditions. In case recorder 1 has a probable initial word boundary and its validity is performed, all adjustment is prohibited by block 4 before the end of this test devices. However, the measurement of the input signal level during the TA interval in the input signal converter 3 continues. Upon completion of this TA analysis interval, the input signal level is stored in the output register of the converter 3, followed by the measurement of the input signal level at the next TA analysis interval. If the verification of the detected initial word boundary ends in, the recorder 1 has a negative result, then, according to its signal, the control unit 4 immediately adjusts the values of the time parameters Tm - Tz, without waiting for the end of the current analysis time interval. For this, the noise level data stored in the output register of converter 3 is used. If it turns out that the detected initial word boundary is such, then by the signal Initial Lock, which from recorder 1 is fed into unit 4 of control and converter 3

of the input signal, the formation of time intervals of the TA analysis and the measurement of the input signal level are forbidden, and the contents of the output register and level gauge of converter 3 are reset to zero. As soon as recorder 1 detects the true final word boundary, it will allow block 4 and converter 3 to resume formation

0 time intervals for the analysis of ambient noise and measurement of the magnitude of their level during these intervals. However, before the end of the first after detection of the end of the word analysis interval TA registrar 1

5 will use those values of the time parameters Tz, which were written into it immediately before detecting the beginning of a word. In the subsequent cycle of operation of the device is repeated.

0 Registrar 1 (Fig. 3) works as follows

The input audio signal is fed to the input of the imager 5 characteristic signals, the signals fA and fA from the output of which

5 are fed to the input of the imaging unit 6 of the timing pulses.

The shaper 6 pulses of time ratios (Fig. 7) works as follows

0 Signal The initial installation goes through the elements OR 50, 55, 52.53, 56, 57, 58 and 59, respectively, to the zero inputs of the flip-flops 21, 22, 23, 24, 25, 26, 27 and 28 and sets them to zero, except Moreover, the effect on the R-inputs of the counters 16-20, resets their contents to zero, and also, passing through the OR 51 element and the delay element 60, writes to the registers 8-10 the values of the initial time parameters Tg - Tz. The magnitude of the delay is chosen such that at the output of the characteristics memory block 2 (FIG. 2) or, equivalently, at the information inputs of registers 8-10 (phi 7) the transient

5 processes associated with the operation of the characteristics memory block. In addition, the Initial Setup signal, passing through the delay element 61, the value of which compensates the response delay of the registers 80 10, and the OR-NOT elements 29-33 and the inputs V of the corresponding counters 16-20, writes the contents of the registers 8-10 into them, the outputs of which are connected to the information inputs of the counters. Counters 165 20 are subtractive binary counters that have the ability to record information in parallel code. Thus, in the counters 16 and 20, the value of the time characteristic T i is recorded in

the counters 17 and 19 are the values of the time characteristic T2, and the counter 18 is the value of h, and the counters 16-18 are involved in finding the initial word boundary, and the counters 19-20 are in the final one, after bringing the former 6 to the initial (initial) state it is awaiting the arrival of pulses from the first characteristic signal fA. Upon the arrival of a pulse of the first characteristic signal, the following occurs: through element I 37, the subtracting input of counter 16 begins to receive pulses CHi, reducing its content from Ti to zero; The detector 11 of the pulse front through the element AND 41 forms the signal Acceptance of the initial boundary, the further processing of which in the word storage unit 7 is identical to the prototype. The same signal Accepting the initial boundary, arriving at the S-input of the trigger 28, sets it to one state, thereby prohibiting the control unit 4 to adapt the device to external conditions until the end of the truth test of the detected initial boundary. If the pulse duration of the first characteristic signal is shorter than the duration of Trg, i.e. the counter 16 does not have time to count to zero, as the pulse of the first characteristic signal ends, its decline, passing through the inverter 34, detector 15, open valve 36, element IL AND 49 and elements IL AND E 29-31, will overwrite the information in the counters 16-18. In addition, the signal from the output of the detector 15 passes through the open valve 48 to the zero input of the trigger 28, overturns it to the zero state, which corresponds to the removal of the prohibition to correct the used temporal characteristics previously set by the control unit. Thus, the probable initial word boundary did not pass the truth test on the TV time characteristic. If the pulse duration of the first characteristic signal is longer than the time interval Ti, then at the output of counter 16 a low level signal is formed, which, arriving at the single input of the trigger 21, sets it to the single state. The signal from the inverted trigger output 21 prevents the passage of sync pulses through the element 37 to the input of counter 16, as well as the passage of signals through the elements 36, 41 and 48. The unit potential from the direct output of the trigger 21 allows the signal to pass through the element 40 and also the flow synchrompulses through the element 38 to the counting input of the counter 17. After the end of the pulse of the first characteristic signal, the indicated pulses will begin to flow through the completely. unlocked element 38 to the subtracting input of the counter 17. If the pause of the characteristic the signal will exceed the duration T2, then at the output of the counter 18, the overflow signal appears, which through the OR 50 and 59 elements sets the triggers 21 and 28 to the initial zero states. At the moment of switching the trigger 21 from the single state to the zero, the pulse decay detector 13 connected to its direct output will generate a pulse that will record the values through the OR 49 element and the OR-NOT 29-31 elements

5 time parameters stored in registers. 8-9. In the event that the measured pause of the first characteristic signal expires before the overflow of the counter 17, then at the moment this pause ends at

0, the output of the detector 11 is a Wits pulse, which, having passed through the valve 40 unlocked by the trigger 21 and the element OR 54, sets the trigger 22 to one state, thereby forming the Initial signal

5 block, after which the former 6 goes to search for the final word boundary. According to the algorithm of the prototype, if after the appearance of the first characteristic signal by ° C the second characteristic signal, the device measures the input audio signal by the parameter Тз. In the former 6 with the simultaneous appearance of two characteristic signals at the output

Element 5 And 43 in terms of unit potential that sets trigger 23 to one. The signal from the direct output of this trigger will block the And 37 and 38 elements and unlock the And 39 element.

0 passing the clock to the counting input of the counter 18. In the event that before the overflow of the counter 18, the first characteristic signal disappears after the loss

5 of the second characteristic signal, a signal will be generated at the output of the AND LA element, which, through the IL AND 52 element, will set the trigger 23 to the zero state. As a result, blocking occurs.

0 valve 39 and unlocking of the valves 37 and 38. Connected to the output of the trigger 23, the detector 14 pulse decay at the time of resetting the trigger to zero will generate a pulse that will reset to zero the trigger 21, as well as through

5 element OR 49 and elements OR-NOT 29-31 will regenerate the lost information by counters 16-18 by writing the contents of registers 8-10 from them. In the event that the input audio signal satisfies the parameter T3, the output of the counter

1B shows the overflow signal, which, through the OR 54 element, will force the trigger to generate the Initial Blocking signal. The dacha signal through the third inputs of the elements OR — NOT — records the contents of registers 8-10 into the counters and prohibits the operation of these counters for the entire duration of their existence, i.e. until reading the detected word from the recorder 1. In addition, the Start block signal unlocks the And 42, 46 and 47 element, blocks the And 43 element. At the time the first characteristic signal is lost by the detector 15, the receive signal No, which is fed to the registrar 1 processing identical to the prototype. In addition, from this time point through the fully unlocked element I 46, synchro pulses start to be sent to the counting input of the counter 19, the first of which sets t The player 25 is in the unit state, which allows unlocking the first input of the element AND 47. If the pause of the first characteristic signal lasts longer than the T2 value recorded in the counter 19, then the overflow signal from the output of this counter resets the element OR 56 t of the rigger 25 and setting the trigger 26 in the single state, forms the signal Equal lock. However, if at the moment of counting the pause of the first characteristic signal, a pulse arrives at the input of the imager 6, it prohibits the passage of clock signals to the counting input of counter 19, but unlocking the fourth input of the And 47 element, allows these pulses to pass to the counting input of counter 20, which sets through the element 45 And the trigger 24 in the unit. If the duration of this pulse, Зу, em is greater than the duration of Ti, that is, more than the capacity of the counter 20, this means that the device has detected a false end boundary and the search for the end of the word must be repeated. In this case, the overflow signal from the output of the counter 20 through the inverter 35 and the OR element 56 sets the trigger 25 to the initial zero state and, besides the goy, writes the contents of the register 9 to the counter 19 OR OR NOT 32. the first characteristic signal trigger 24 is set to zero by the output signal of the inverter 34, which will lead to the formation at the output of detector 12 of a pulse that, through the OR element 33, records information in the counter 20, In the case when the pulse duration of the first character eristicheskogo signal okazhets less duration Tr,

counter 19 is restarted via unlocked AND 46, and counter 20 is used to rewrite information due to resetting trigger 24 to zero. Thus, if the pulse of the first characteristic signal returns again, the counter 20 will start working again until the final word boundary is found true. In this case, the readout signal arrives at the fifth input of the generator 6, which will set the trigger 27 to one the state that the Enable signal enables the reading of the detected word from the word memory storage unit 7. Upon the expiration of this process, the sixth input of the imaging unit 6 will receive the End of Reading signal, which will cause the imaging unit 6 to return to its initial state by setting the corresponding triggers 21, 22, 26, 27 and 28 through the OR 50, 55, 57, 58, and 59 elements. c / a, when the driver 6 is not checked for the detected initial word boundary, the control unit 4 at regular intervals sends a signal to the third input of the driver 6, which updates the information in registers 8-10 and counters 16-20. This signal, having passed through the OR element 34 and lingering on the element 60 for the response time of the block 2 of the characteristics memory, arrives at the synchronous input of the registers 8-10, writing information supplied to the information inputs into them. In addition, by lingering on element 61 for the duration of the operation of registers 3-10, it similarly records information in counters 16-20.

The word storage unit 7, its operation algorithm, a set of elements and connections completely correspond to the prototype (Fig. 5) except that the driver of 6 temporal ratio pulses is made with four additional inputs and one additional output and together with the driver 5 of the characteristic signals are described and is depicted in FIG. 3 and 7.

Feature memory block 2 {FIG. 3) consists of three memory blocks with combined address inputs. The cells of each memory block store the values of the corresponding temporal characteristics TL-T3. The address for these memory blocks is a binary representation of the noise level over the period of analysis of the input audio signal. The values of the time parameters Tr - Ts are located in memory locations in one-to-one correspondence with the possible level of the input signal.

The Converter 3 input signal (Fig. 6) works as follows.

Signal Initial installation resets to zero the contents of counter 73, register 79, through the elements OR 83 and 88, the contents of trigger 74 and integrator 77, and also generates 72 sync pulses. The pulses of the synchronous generator 72 are fed to the counting input of the counter 73. The capacity of which is calculated for the length of the interval for analyzing the ambient noise of the TA. Audio input after amplification in amplifier 75 and detection by detector

76 enters the input of the integrator 77 level. The signal from the output of the integrator 77 level is converted into binary form using an analog-digital converter 78 and is fed to the information inputs of the register 79. At the end of the TA analysis interval, a single impulse control unit arrives at the third input of the converter 3. Simultaneously, the same pulse appears at the output of the counter 73, in the resulgate of which this pulse appears at the output of the AND 80 element, It passes through the OR 86 element to the synchronous input of the register 79 and records the contents of the integrator 77 in the binary in it code. This same pulse from the output of the element 80 is delayed by the element 89 at the time of the end of the process of recording information in the register 79, passes the element OR 84, enters the first inputs of the block of elements AND, unlocks it and connects the outputs of the register 79 to the address inputs of the characteristics memory block 2 . In addition, this pulse from the output of the element And 80 passes through the element OR 85, is delayed by the element 90 for the duration of the transient processes when writing information to the register 79 and thereafter through the element OR 88 resets the contents of the level 77 integrator to zero, thus preparing it to the measurement of the noise level during the next time interval of the TA analysis. In the event that the shaper 6 detects a probable initial word boundary, it will, before verifying its truth, forbid the control unit 4 to generate a control pulse for adjusting the values of the time parameters. Then the signal from the output of the counter 73 through the unlocked element AND 81 sets the trigger 74 to one, and also through the element OR 86 records the information in the register 79, and through the element OR 85, the delay element 90 and the element OR 88 flushes the integrator

77v zero. The integrator 77 will begin a new cycle of measuring the input signal level, and its data for the previous analysis interval is recorded in register 79. If the detected initial word boundary is false, the former will remove its prohibition from the control unit 4, which is not 5 waiting for the end of the current TA analysis interval, generates a pulse signal allowing device adaptation. The specified signal is fed to the third input of the Converter 3, passes through

0 unlocked by trigger 74 element AND 82, sbsasyv-ag through the element OR 83 this trigger to zero, and also the element OR 84 unlocks the block of elements AND 91, which leads to reading from memory block 2

5 characteristics of their new values stored at the address recorded in register 79. Next, the cycle of analysis and adjustment is repeated by fire. Pts / Algorithm, In case the detected at the beginning of the boundary of the boundary was true, the Former 5 Geger Roux; The initial blocking which goes to the inputs of PreobazovEtep 3 and Block 4 of the control and prohibits not only the correction,

5 but also change the input level. This signal comes from the second input of the converter 3, passes through the OR element 87 .1 keeps the counting rate 73 and the register 79 in the zero state during the whole time of its existence, similarly through the element OR 8 and 88 are set in the note of trggo 74 i 77-level integrator. By ius. i signal detected again from the recorder 1 signal

5 The initial blocking stops its prohibitive effect on the elements of the converter 3 after which it resumes its operation.

The control unit 4 operates as follows.

0 way (Fig 4)

The signal Initial installation starts up the generator 94 and through the element OR 96 sets in the zero state of the counter 92 The capacity of the counter 92

5 is equal to the capacitance of an identical counter 73 of a pre-discharge signal 3 of a similar signal n calculated to calculate the time interval TA, the time for analyzing the level of the ambient noise signal 1 at the end of this interval at the output of counter 92 appears a single 1 mp that passes through the unlocked element AND 99 element OR 98 at the input of block 4 This single impulse is used by the converter 3 of the input signal and recorder 1 to organize the process of adjusting the device to the changing ambient noise environment. If formioi-ence 6 detects probable slgvz c tnuyu boundaries | j prohibiting unit delivers a signal to the second input of the control unit 4. This signal blocks the element AND 99 and unlocks the element AND 100. If, before you understand the truth or falsity of the detected initial boundary of the word, counter 92 will overflow, i.e. If the analysis interval Td expires, then the overflow pulse of counter 92 through the OR element 100 sets the trigger 93 to one state. At the same time, the measured input signal level will be written to the output register in converter 3. If the truth of the detected boundary is not confirmed, the shaper 6 removes a single inhibit signal from the second input of the control unit 4. The pulse decay detector 95, which forms a single pulse at its output, will respond to this process. This pulse passes through the unlocked element AND 101 and the element OR 98 at the output of the device. Thus, without waiting for the end of the current interval for analyzing the ambient noise level, block 4 immediately after concluding that the detected initial word boundary is false, organizes the formation of a signal allowing the device to adapt to external conditions. The output signal from AND 101 passes through the OR 97 and sets trigger 93 to initial zero state. In the event that shaper 6 confirms the truth of the detected initial word boundary, it sends the initial block to the first input of block 4, which, for the time of its existence through the OR 96 and 97 elements, sets the counter 92 and the trigger 93 to zero, and also blocks element 101. After reading the detected word from the memory block, the initial blocking signal removes its blocking action from the elements of block 4, after which the counter 92 and the whole block 4 are resumed according to the algorithm described above.

Evaluate the technical and economic efficiency of the proposed method and device in relation to the prototype.

The probability of a word being detected by the prototype is determined by the expressions:

Pn Pin Pan; (8)

Pn - Pan. (9)

where Pin is the probability that the pulse width of the first characteristic signal will be longer than PT;

P2p is the probability that the duration of the pause of the first characteristic signal will be less than the time Ta, provided that the previous pulse of this signal had a duration longer than

Ti;

The probability that the time from the appearance of the second characteristic signal to the disappearance of the first characteristic signal is

exceed the duration Tz.

Claims (1)

1. Method of detecting the boundaries of words on the author. St. Ms 1040512, characterized in that that, in order to improve noise immunity when defining word boundaries, the level of ambient noise is additionally measured during a fixed time interval of the analysis of the ambient noise situation and the results of the analysis correct the values of the time characteristics used. 2, A device for detecting word boundaries according to ed. St. No. 1040512, characterized in that, in order to improve noise immunity, a time storage unit, an input signal converter, a control unit, two inputs of which are connected to the corresponding two additional outputs of the time ratio generator, the first of which is connected to the second input, are introduced into it. input converter, the first input of which is connected to the input bus of the analog audio signal and the auxiliary input of the characteristic signal generator, the output of the control unit is connected to the first DOP01 - a separate input of the temporal ratio driver and the third input of the input signal converter, the output of which is connected to the input of the temporary characteristics memory block. three group outputs are connected 0 with the second, third and fourth additional group inputs of the pulse shaper of time ratios. HCH 35u gpf 09S1C9L tea with : h at