JPH01177225A - System and device for encoding/decoding sound signal - Google Patents

Abstract

PURPOSE:To obtain excellent sound signals which are not deteriorated in tone quality even when the sound signals are applied to a highly erroneous usage of a transmission line by performing error controlling encoding to codes having important transmitting information in accordance with the importance. CONSTITUTION:A multi-pulse sound source calculating circuit 300 finds the amplitude and position of a prefixed number of multi-pulse trains by using sound signals and LPC coefficients and a pulse quantizer 350 quantizes the maximum value of the pulses as normalizing information with a prefixed bit number and, after normalizing the amplitude of each pulse by using the normalizing information, quantizes each pulse with the prefixed bit number and encodes the position of each pulse. An error controlling encoding circuit 400 inputs the LPC coefficients, normalized information of sound source pulses, and codes of the amplitude and position of sound source pulses and performs one kind or plural kinds of error controlling encoding in accordance with the importance of the code of each transmitting information and the sensitiveness to transmission line errors. Then the circuit 400 adds redundancy bits to the information to be protected in accordance with the kind of error controlling encoding. Therefore, deterioration of tone quantity can be eliminated even if a transmission line error is high and, as a result, excellent sounds can be reproduced.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an audio signal encoding/decoding method and apparatus for efficiently encoding and decoding audio signals at a low bit rate. In particular, the present invention relates to an audio signal encoding/decoding method and apparatus for reproducing good audio with almost no deterioration in audio quality even when the error rate of a transmission path is high when used in mobile communications.

(Prior art) Multi-pulse encoding is a method for encoding audio signals at approximately 16-8 kbps in a good manner, in which the characteristics of the vocal tract are represented by a digital filter, and the sound source is represented by a combination of multiple pulse trains. The law is known. In this method, the filter coefficients and the information (pulse amplitude, position) for the sound source pulse are set to 20
It is transmitted every frame of about m5. For details of this method, see, for example, Araseki
), “Multi-pulse Excited Speech Coder Paste on Maximum Cross-Correlation Search Algorithm (Multi-pulse Excited 5)” by Ozawa et al.
peach Coder Ba5ed on Maxi
mumCrosscorrelation 5earc
h Algorithm) J (GLOBECOM
83, Lecture No. 23.3.1983) (Reference 1), so the explanation will be omitted here.

This method can reproduce good audio in locations where there are very few transmission path errors, such as wired transmission paths.

(Problems to be Solved by the Invention) However, when the above-mentioned conventional method is applied to mobile communications such as car telephones, for which the demand has been rapidly increasing recently, the error rate of the wireless transmission path is about 10-2. Furthermore, not only random errors but also burst errors occur frequently due to causes such as multipath fading, so the reproduction quality of the conventional method has been extremely degraded. In particular, if a transmission path error occurs in important information such as the low-order part of the filter coefficients or the normalized amplitude information of the sound source, the sound quality will deteriorate significantly, and in extreme cases, calls will be interrupted. There was a major problem that made it difficult.

SUMMARY OF THE INVENTION An object of the present invention is to provide an audio encoding/decoding system and an apparatus thereof that can reproduce good audio with almost no deterioration in audio quality even if the transmission path error is about 10<-2 >.

(Means for Solving the Problems) The audio signal encoding/decoding method according to the present invention inputs a discrete audio signal, represents the audio signal as a combination of a spectral parameter and a plurality of pulse trains, and transmits the audio signal. In the multipulse audio coding method that reproduces signals well,
The present invention is characterized by comprising means for performing one or more types of error control on a portion of the code representing the transmission information.

The audio signal encoding device according to the present invention includes a spectral parameter calculation circuit that inputs a discrete audio signal, obtains and encodes spectral parameters representing the spectral characteristics of the audio signal, and a plurality of spectral parameter calculation circuits that represent the spectral characteristics of the audio signal. a multi-pulse excitation calculation circuit that determines and encodes a combination of pulse trains, and an error that performs one or more types of error control encoding on a portion of the output code of the spectral parameter calculation circuit and the multi-pulse excitation calculation circuit. It is characterized by having a control encoding circuit.

An audio signal decoding apparatus according to the present invention includes a demultiplexer circuit that inputs and separates a code representing an error-controlled spectral parameter of an audio signal and a code representing a multipulse sound source, and one type for a portion of the code. Alternatively, the feature includes an error control decoding circuit that performs multiple types of error control decoding, and a synthesis filter circuit that reproduces an audio signal using the decoded spectral parameter and the decoded multipulse sound source. shall be.

(Function) The present invention provides the above-mentioned multipulse speech encoding method.
The present invention is characterized in that one or more types of error control are applied to the code of a portion of the transmission information, depending on the importance of the bits of the transmission information or the sensitivity to transmission path errors.

Next, the operation of the present invention will be explained using FIG. 2.

A discrete audio signal sequence is input through the input terminal 100. The audio signal consists of frames of a certain length (for example, 2 frames).
0m5). Next, the LPC analysis section 200
The audio signal of the frame is subjected to LPC analysis using a well-known method to obtain LPC coefficients of a predetermined order. LPG quantizer 220 quantizes the LPC coefficients. This method is described, for example, in Tokuko No. 59-272435 (Reference 2).
can be referred to. LPC quantizer 220 is LP
A code obtained by quantizing the G coefficient is output to the error control encoding circuit 400. The LPC coefficient dequantizer 240 decodes the encoded LPC coefficients and outputs them to the multipulse excitation calculation circuit 3.
Output to 00. For this method, reference can be made to the above-mentioned document 2.

The multi-pulse sound source calculation circuit 300 calculates the sound signal and L
The amplitude and position of a predetermined number of multi-pulse trains are determined using the PG coefficient. Here, for how to obtain this sound source pulse train, reference can be made to the aforementioned Document 1 or Document 2.

The pulse quantizer 350 quantizes the maximum value of the pulse as normalization information with a predetermined number of bits, uses this to normalize the amplitude of each pulse, and then quantizes it with a predetermined number of bits. Encode the position. For these specific methods, reference can be made to the above-mentioned document 2. The normalization information, the pulse amplitude, and the code representing the position are output to an error control encoding circuit 400.

The error control encoding circuit 400 inputs the LPC coefficient, the normalization information of the excitation pulse, the amplitude of the excitation pulse, and the code of the position, and selects one type depending on the importance of the code of each transmission information and the sensitivity to transmission path errors. Alternatively, multiple types of error control encoding are performed, and redundant bits are added to the information to be protected depending on the type of error control encoding. In the following, a case will be described in which an error correction code is used as error control, and a plurality of types of error correction codes are used. Here, the well-known Reed-Solomon (R3) code, BCH code, MLD code, etc. can be used as the error correction code. I here? S code, B
The structure of CH codes is explained in detail in "Iwa Lectures, Information Science 4, Theory of Information and Codes" by Mr. Imai et al. (Chapter 6, Iwanami Shoten, Reference 3), and regarding MLD codes, , and is explained in Reference 4, which will be mentioned later, so the explanation is omitted here.In the case of multi-pulse coding, LPC coefficients carry the phonological information of the audio signal as the transmission information to be error-protected. The bits near the MSB of the low-order coefficients are important because the low-order coefficients represent information on the lowest formants.Next, the normalized information of the pulse amplitude that determines the amplitude of the sound source is added to the MSH. The bits closest to each other are important.In addition to these, the bits from the MSB of the pulse amplitude and the bits from the MSB of the pulse position are important.Therefore, which bits are more important in these transmitted information? An error correction code having a strong error correction ability is used.However, for less important bits, a less strong error correction code with a small number of redundant bits may be used, or a configuration may be adopted in which they are not protected at all.

The multiplexer circuit 500 inputs a code sequence subjected to error correction encoding, interleaves error-protected information so as to be strong against burst errors, and outputs the interleaved and arranged information to a transmission path.

(Embodiment) In FIG. 1 showing an embodiment of the present invention, an input terminal 60
Input a discrete audio signal from 0. The audio signal is divided into fixed time frames (for example, 20 m5), and the LPG
Analysis circuit 650 performs LPC analysis using a well-known method, and outputs LPC coefficients to LPC quantizer 670. LPC quantizer 670 quantizes the LPC coefficients according to a predetermined number of bits. For a specific method, reference can be made to the above-mentioned document 2, for example. L
The PC decoder 680 decodes and outputs the quantized LPG coefficients. The impulse response calculation circuit 700 uses the decoded LPC coefficients to calculate the impulse response of the weighted synthesis filter. For the specific method, reference can be made to the above-mentioned document 2.

The autocorrelation function calculation circuit 720 calculates the autocorrelation function of the impulse response. As a specific method, see the above-mentioned document 2.
9 weighting circuit 690 applies listening weighting to the audio signal.

For the specific method, reference can be made to the above-mentioned document 2. A cross-correlation function calculation circuit 710 calculates a cross-correlation function between the weighted signal and the impulse response. For a specific method, see the above document 2.
can be referred to. Multipulse sound source calculation circuit 7
30 uses a cross-correlation function and an auto-correlation function to obtain the amplitude and position of a predetermined number of multi-pulses.

For a specific method, reference can be made to the above-mentioned document 2. The pulse quantizer 740 operates in the same manner as the pulse quantizer 350 described in the operation section, and outputs amplitude normalization information, the position of each pulse, and a code representing the amplitude to the error control encoding circuit 750. .

The error control encoding circuit 750 operates in the same manner as the error control encoding circuit 400 described in the operation section, and determines which bits of the LPC coefficient are close to the low-order MSH and the normalization information of the pulse amplitude. Bits close to the MSB can be subjected to strong error correction encoding, and other bits can be subjected to different error correction encoding or no error correction at all. These codes are output to multiplexer 760.

The multiplexer 760 performs interleaving on these error-corrected code sequences to make them resistant to burst errors, and then outputs the code sequences.

On the receiving side, the demultiplexer 765 deinterleaves the received code sequence and then separates the LPG coefficient, the amplitude normalization information of the excitation pulse, the amplitude, and the position information and outputs them to the error control decoding circuit 770.

The error control decoding circuit 770 performs error correction decoding on information that has been error corrected on the transmitting side and outputs the information.

Pulse decoding circuit 780 decodes the sound source pulse train using pulse normalization information, amplitude, and position and outputs it to pulse generation circuit 800. The pulse generation circuit 800 generates and outputs a sound source pulse train.

LPC decoding circuit 790 decodes the LPC coefficients and outputs them to synthesis filter circuit 810. Synthesis filter circuit 81
0 uses the decoded LPC coefficients and the sound source signal to obtain a synthesized speech signal for one frame and outputs it through the terminal 820.

The embodiment described above is merely one embodiment of the present invention, and various modifications thereof are possible.

Regarding error control coding, well-known and good error correction codes can be used in addition to the error correction codes described in the above-mentioned functions and embodiments. Regarding these, in addition to the above-mentioned document 3, there are "car telephones" by Mr. Kuwabara et al.
Reference can be made to "Coding Theory" (Shokodo, Reference 5). It is also possible to use a code that detects or corrects burst errors. For details, refer to Reference 3.

Further, as a method for calculating the sound source pulse, a well-known method may be used in addition to the above-mentioned embodiment. Regarding this, please refer to Ozawa's ``A 5 study of Pu
1se 5earch AIgorithms for
Multi-Pulse 5peech Codec
Realization'' (J, 5 select
ed Area of Cowsunicati
ons, pp., 1987) (Reference 6).

(Effects of the Invention) As described above, according to the present invention, in the multi-pulse audio encoding method that can obtain good reproduced audio when there are almost no errors in the transmission path, important codes of transmission information can be Error control coding is performed according to the importance of the error, so even when applied to applications with high transmission path errors such as mobile communications,
This has the great effect of making it possible to obtain good reproduced audio with almost no deterioration in sound quality.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing the structure of an embodiment of a speech encoding/decoding system and apparatus according to the present invention, and FIG. 2 is a block diagram showing the operation of the present invention.

200.650LPC calculation circuit, 220.670LPC
Quantization circuit, 240.680 LPC decoding circuit, 3
50.740 Pulse quantization circuit, 400.750
Error control encoding circuit 300.710 Multipulse excitation calculation circuit, 690 Weighting circuit, 700 Impulse response calculation circuit, 710 Cross-correlation function calculation circuit, 72
0 autocorrelation function calculation circuit, 750 multiplexer,
765 demultiplexer, 770 error control decoding circuit, 800 pulse generation circuit, 810 synthesis filter.

Claims (3)

[Claims] (1) In a multi-pulse audio encoding method in which a discrete audio signal is input, the audio signal is expressed as a combination of a spectral parameter and a plurality of pulse trains, and the audio signal is transmitted to reproduce the audio signal satisfactorily. An audio signal encoding/decoding system characterized by having means for performing one or more types of error control on a portion of a code represented. (2) A spectral parameter calculation circuit that inputs a discrete audio signal, determines and encodes a spectral parameter representing the spectral characteristics of the audio signal, and determines a combination of a plurality of pulse trains representing the sound source of the audio signal. A multipulse excitation calculation circuit for encoding, and an error control encoding circuit for performing one or more types of error control encoding on a portion of the output code of the spectral parameter calculation circuit and the multipulse excitation calculation circuit. An audio signal encoding device characterized by: (3) a demultiplexer circuit that inputs and separates a code representing an error-controlled spectral parameter of an audio signal and a code representing a multipulse sound source; and one or more types of error control decoding for a portion of the code. An audio signal decoding device characterized by comprising an error control decoding circuit that performs a process of decoding, and a synthesis filter circuit that reproduces an audio signal using the decoded spectral parameter and the decoded multipulse sound source. .