JPH0731514B2 - Speech waveform coding method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial application] The present invention extracts and encodes a parameter representing a resonance characteristic of a sound path and a driving sound source signal of a filter having the resonance characteristic from an original audio signal. The present invention relates to a speech waveform coding method. In particular, the present invention relates to a speech waveform coding method in which the impulse response calculation method in the process of searching the driving excitation signal is improved.

〔Overview〕

According to the present invention, a parameter representing a resonance characteristic of a sound path and an impulse response of a synthesis filter having the resonance characteristic are calculated from an input voice signal, and a cross-correlation operation between the impulse response and the input voice signal is performed and encoded. In the speech waveform encoding method, the power of the calculated impulse response is sequentially calculated,
The calculation amount is reduced by stopping the calculation of the impulse response when the value becomes equal to or less than the predetermined value.

[Conventional technology]

Conventionally, as an effective method for encoding a voice signal at a low bit rate, LPC (Linear Predictive Coding, Linea
r Predictive coding) A pulse which is a driving sound source signal of a synthesizer is analyzed by the encoder side at a short time, Ab-S (Analysis-by-Synthesi).
In the literature (1), a method of sequentially obtaining by the method (s) is proposed.

Further, as a method of realizing the method with a relatively small amount of calculation, a method of obtaining a pulse forming a driving sound source signal based on a correlation calculation has been proposed.

FIG. 3 is a block diagram showing an encoder in the conventional system described in Document (2). FIG. 4 is a block diagram showing the details of the impulse response calculation circuit in FIG.

In FIG. 3, reference numeral 300 denotes an input terminal of the encoder, to which a discrete input audio signal x (n) is input. Reference numeral 310 is a linear prediction coefficient calculation circuit, and the calculated output coefficient is output to the quantization encoder 320. 340 is an impulse response calculation circuit. The cross-correlation calculation circuit 330 receives the input audio signal x (n)
And the impulse response calculated by the impulse response calculation circuit 340 are obtained. Autocorrelation calculation circuit 35
0 determines the autocorrelation of the impulse response input from the impulse response calculation circuit 340. The output values of the cross-correlation calculation circuit 330 and the autocorrelation calculation circuit 350 are output to the excitation pulse search circuit 360, and the drive excitation signal calculated by this excitation pulse search circuit 360 is output to the quantization encoder 370. . 380 is a multiplexer and 390 is an output terminal of the encoder.

In FIG. 4, the impulse response calculation circuit 340 inputs the quantized linear prediction coefficient from the input terminal 341. 200
Is an impulse response calculation circuit. Further, if the time required for the impulse response calculation circuit 200 to calculate one sample of the impulse response is T ₀ , the counter (1) 210 is a counter that counts down by 1 at each time T ₀ .

Therefore, if the impulse response of 40 samples per frame is used to calculate the driving sound source signal, the counter (1) 21
39 is set to 0, the value is counted down by 1 at each time T ₀ , and the address for storing the impulse response output from the impulse response calculation circuit 200 in the memory 230 is designated. When the counter (1) 210 reaches 0, the calculation by the impulse response calculation circuit 200 is stopped,
Information on the impulse response in the memory 230 is output from the output terminal 342.

5 and 6 are characteristic diagrams showing examples of impulse responses experimentally obtained by the conventional method shown in FIG. Here, in FIGS. 5 and 6, the resonance characteristics of the synthetic filter that outputs the impulse response are different,
The horizontal axis represents discrete time and the vertical axis represents amplitude.
It is to be noted that a case is shown in which impulse responses of n samples per frame are obtained. That is, the impulse response used to calculate the drive sound source signal is the impulse response from time 0 to n indicated by the arrows in the figure.

In FIG. 5, the impulse response almost converges after the time m, whereas in FIG. 6, the amplitude of the impulse response becomes considerably large even after the time m.

References (1) B, S, Ataal et al. (BSAtal.etal) “A New Model of LPC Excitat, a new model of LPC excitement for generating natural speech at low bit rates.
ion For Producing natural-Sounding Speech At Low
Bit Rates ") Sound, Communication Signal Processing International Conference, (Proceedi
ngs of International Confrence on Acoustics, Speech
Signal Processing.) 1982, P614-617.

Reference (2) Ozawa et al., "Study on Multi-Pulse Driven Speech Coding Method", IEICE, CAS 82-202, 1983, pp. 115-122.

[Problems to be solved by the invention]

In this way, the time until the impulse response converges is
In the conventional speech coding format, the impulse response is calculated until the constant number of impulse responses (here, n) is reached, and the driving sound source signal is calculated (cross-correlation and auto-correlation). Calculation).

In the case of the impulse response as shown in FIG. 5, since the amplitude at times m to n is almost 0, even if the processing of the next step, that is, the calculation of the cross correlation and the calculation of the autocorrelation is performed without using this portion. , A cross-correlation value and an auto-correlation value similar to those in the case of using the time m to n are obtained. Therefore, if the driving sound source signal is calculated without using the impulse response of the time m to n, it should be possible to calculate the driving sound source signal similar to the conventional one with a smaller calculation amount than the conventional one.

That is, in the conventional speech waveform coding method, since the number of impulse responses used for driving excitation signal calculation is a predetermined value, the driving excitation signal calculation may be performed using more than necessary impulse responses depending on the frame. Done,
There is a drawback that excessive calculation is performed.

It is an object of the present invention to provide a speech waveform coding method which eliminates the above-mentioned drawbacks and can search a driving excitation signal having an appropriate position and amplitude as in the conventional case with a smaller amount of calculation than the conventional case.

[Means for solving problems]

The present invention divides an input speech signal into fixed frame periods, extracts a parameter representing the resonance characteristic of a sound path, calculates an impulse response of a synthesis filter having the resonance characteristic, and calculates the impulse response and the input speech. It is possible to obtain a plurality of values obtained by executing an operation for calculating a pulse having an amplitude that can be minimized for each pulse at a timing at which a squared error with a signal is minimized and repeating this operation for continuous pulses. In a speech waveform encoding method that outputs a pulse as a driving excitation signal, the power of the calculated impulse response is sequentially calculated for each of the constant frame periods, and when the value reaches a predetermined value or less,
It is characterized in that the calculation of the impulse response is stopped.

[Action]

In calculating the impulse response, the present invention sequentially calculates the power of the calculated impulse response, compares the calculated power value with the total value of the power values calculated up to that time, and the value is 1 Alternatively, the impulse response calculation is stopped when it becomes smaller than a predetermined threshold value. Therefore, in the case of the characteristics shown in FIG. 5, unnecessary calculation is not performed, and the calculation amount can be reduced.

〔Example〕

FIG. 1 is a block diagram showing a main part of an encoder according to an embodiment of the present invention, which corresponds to the impulse response calculation circuit in FIG.

The impulse response calculation circuit 340a according to the present embodiment is a power calculation circuit 120 that calculates the power of the calculated impulse response output from the impulse response calculation circuit 200, and a counter that specifies the number of impulse responses used in this power calculation circuit 120. (1) 210a, a power ratio determination circuit 100 for determining whether or not the power value of the impulse response output from the power calculation circuit 120 is below a predetermined value, and a power ratio determination circuit according to an instruction from the counter (1) 210a. Counter (2) 11 that controls the number of impulse responses calculated by 100
Includes 0 and memory 230. Here, the power ratio determination circuit 100, the power calculation circuit 120, and the counter (2) 110 form an impulse response determination circuit 220.

The feature of the present invention resides in that in the embodiment shown in FIG. 1, the impulse response determination circuit 220 is provided to calculate and determine the power of the impulse response.

Next, the operation of this embodiment will be described. The parts other than the impulse response calculation circuit not shown in FIG.
This is similar to the conventional example shown in FIG.

The operation of this embodiment is performed in the following order.

(1) The minimum value a of the number of impulse responses is set in the counter (1) 210a, and the maximum value b of the number of impulse responses is set in the counter (2) 110.

(2) The impulse response calculation circuit 200 calculates the impulse response of one sample every time T ₀ . The counter (1) 210a and the counter (2) 110 are both counters that count down by 1 at each time T ₀ . The counter (1) 210a starts the countdown and at the same time specifies the start of the countdown to the counter (2) 110, and the memory 230 specifies the storage start address of the impulse response calculated by the impulse response calculation circuit 200. When the counter (1) 210a becomes “0”, the impulse response calculation circuit 200 stops calculating the impulse response, and the counter (2) 110 also stops counting down.

(3) The impulse response calculated by the impulse response calculation circuit 200 is stored in the memory 230 and the power calculation circuit 120.
Is input to. The power calculation circuit 120 calculates the power of the impulse response of the input portion, and the counter (1) 210a
Is output to the power ratio determination circuit 100.

(4) In the power ratio determination circuit 100, If P ₀ is 1 or larger than the threshold value Pt (P ₀ ≧ Pt), it is necessary to output the content of the memory 230 from the output terminal 342 and further calculate it in the counter (1) 210a. The number of impulse responses x is set, and calculation of the impulse response is restarted (the process returns to (2) above).

However, in the power ratio determination device 100, even if P ₀ ≧ Pt, if the counter (2) 110 becomes “0”, the power ratio determination circuit 100 performs data setting to the counter (1) 210a. Therefore, the impulse response is not calculated. Further, the contents of the memory 230 are output from the output terminal 342.

When P ₀ is smaller than the threshold value Pt (P ₀ <Pt), it is assumed that the impulse response calculation is completed.

FIG. 2 is a characteristic diagram showing an impulse response calculated experimentally according to this embodiment.

First, after calculating the impulse response of the portion of time 0 to a in FIG. 2, in the power ratio determination circuit 100, To get Therefore, the impulse response from time 0 to a is output from the output terminal 342, and the impulse response from time a to a + x is calculated. Again, in the power ratio determination circuit 100, Ask for. Here, if P ₂ ≧ Pt, the impulse response from time a to a + x is output from the output terminal 342, and the impulse response from time a + x to a + 2x is calculated to obtain P ₃ in the following equation.

At this time, if P ₃ <Pt, the impulse response calculation is stopped.

As described above, in the example of FIG. 2, the impulse response from time 0 to a + 2x is calculated. Further, the impulse response used for calculating the driving sound source signal is the portion from time 0 to a + x (the portion indicated by the arrow in the figure).

Although the above embodiments have been described with respect to the case where known circuits are combined, the present system can be implemented by combining a general-purpose computer (or microcomputer) and known circuits.

〔The invention's effect〕

As described above, the present invention determines the necessary and sufficient number of impulse responses to be used for driving sound source signal calculation by determining the power for each frame, with a smaller amount of calculation than the conventional method, and at an appropriate position as in the conventional method, There is an effect that a driving sound source signal having an amplitude can be searched.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an essential part of an embodiment of the present invention. FIG. 2 is a characteristic diagram showing an example of the characteristic. FIG. 3 is a block diagram showing a conventional example. FIG. 4 is a block diagram showing the impulse response calculation circuit of FIG. FIG. 5 and FIG. 6 are characteristic diagrams showing the characteristics of the conventional example. 100: Power ratio judgment circuit, 110: Counter (2), 12
0 ... Power calculation circuit, 200 ... Impulse response calculation circuit, 210, 210a ... Counter (1), 220 ... Impulse response determination circuit, 230 ... Memory, 300 ... Input terminal, 310
...... Linear prediction coefficient calculation circuit, 320,370 …… Quantization encoder, 330 …… Cross-correlation calculation circuit, 340,340a …… Impulse response calculation circuit, 341 …… Input terminal, 342 …… Output terminal,
350: Autocorrelation calculation circuit, 360: Sound source pulse search circuit, 380: Multiplexer, 390: Output terminal.

Claims (1)

[Claims] 1. An input audio signal is divided at a constant frame period, and a parameter representing a resonance characteristic of a sound path is extracted.
The impulse response of the synthesis filter having the resonance characteristic is calculated, and the impulse response and the input voice signal are calculated as 2
A plurality of pulses obtained by executing a calculation for each pulse for calculating a pulse having an amplitude that can be minimized at the timing at which the multiplication error is minimized and repeatedly executing this calculation for continuous pulses In the speech waveform encoding method for outputting as a signal, the power of the calculated impulse response is sequentially calculated for each of the constant frame periods, and when the value reaches a predetermined value or less, the calculation of the impulse response is stopped. A speech waveform coding method characterized by the following.