KR100789368B1 - Apparatus and Method for coding and decoding residual signal - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a residual signal encoding and decoding apparatus and a method thereof.

2. The technical problem to be solved by the invention

The present invention improves the residual signal coding method using the conventional transform coding, and employs a linear predictive coding model and a track structure in the transform coding method to improve the sound quality and to reduce the memory and the calculation amount. And a decoding device and a method thereof.

3. Summary of Solution to Invention

According to an aspect of the present invention, there is provided a residual signal encoding apparatus comprising: a transform unit configured to convert a residual signal in a time domain into a frequency domain and output a transform coefficient; A linear predictive coefficient extracting unit extracting a linear predictive coefficient from the transform coefficient; A linear predictive coefficient quantizer configured to quantize the linear predictive coefficient and output a quantized linear predictive coefficient and an index; A linear predictive analysis filter unit having a filter implemented based on the quantized linear predictive coefficients and outputting a linear predictive residual transform coefficient by performing linear predictive analysis on the transform coefficients; A band dividing unit for dividing the linear prediction residual conversion coefficient into a predetermined number of bands and outputting a linear prediction residual conversion coefficient for each band; A pulse searching unit searching the linear prediction residual transformation coefficient for each band to select an optimal pulse, and outputting a pulse parameter for the optimal pulse; And a pulse quantizer for quantizing the pulse parameters of the optimum pulse.

4. Important uses of the invention

The present invention is used for voice coding in a broadband integrated network.

Residual Signal, Residual Parameter, Linear Prediction, Transform Coding

Description

Apparatus and Method for coding and decoding residual signal

1 is a block diagram of a speech encoding / decoding apparatus using a residual signal encoding method;

2 is a detailed block diagram of a conventional residual signal encoder and decoder;

3 is a block diagram of a residual signal encoding and decoding apparatus for encoding / decoding a residual signal using transform encoding according to an embodiment of the present invention;

4 is an open-loop pulse search flowchart that may be performed in a pulse searcher according to an embodiment of the present invention;

5 is a closed-loop pulse search flow chart that may be performed in a pulse searcher according to an embodiment of the present invention;

6 is a detailed block diagram of an embodiment of the pulse quantizer and the pulse de-quantizer of FIG. 3;

7 is a graph comparing a speech spectrum processed by a residual encoding method using a conventional transform encoding and a speech spectrum processed by a method of the present invention with an original sound.

* Explanation of symbols for the main parts of the drawings

301: transducer 303: linear predictive coefficient extractor

305: linear predictive coefficient quantizer 307: linear predictive analysis filter

309: band divider 311: pulse searcher

313: pulse quantizer 321: linear predictive coefficient inverse quantizer

323: pulse de-quantizer 325: linear predictive synthesis filter

327 band integrator 329 pulse generator

331: Inverse transformer

The present invention relates to a speech encoding and decoding technique, and more particularly, to a residual signal encoding apparatus and method for converting a residual signal of a speech signal into a frequency domain and outputting a residual parameter, and a residual from the residual parameter. The present invention relates to a residual signal decoding apparatus for recovering a signal, and a method thereof.

The technology of digitizing and transmitting voice is widely used in wired communication networks including existing telephone networks, mobile communication networks, and voice over IP (Internet Protocol) networks. In the case of simply sampling, digitizing and transmitting voice, a data rate of about 64 kbps (when sampling at 8 kHz and encoding each sample by 8 bits) is required. However, transmission of speech using speech analysis and appropriate coding methods can significantly reduce the data rate.

As such a voice compression technique, there is a transform coding method. According to the transform encoding method, a coefficient corresponding to each frequency component is encoded after a speech signal in a time domain is converted into a frequency domain, and a relatively low data rate and a calculation amount are required because each frequency component is encoded according to a human auditory characteristic. .

On the other hand, the recent speech coding technology is moving away from encoding narrowband speech corresponding to the existing telephone network band, and moving toward encoding wideband speech that can provide better naturalness and clarity. In addition, in order to accommodate various network environments, a multi-rate coder in which one voice encoding apparatus supports various data rates is widely used.

Reflecting this trend, embedded variable rate coders have been developed that provide bandwidth scalability and rate scalability. The embedded variable bit rate encoder is configured such that a high bitrate bitstream includes a low bitrate bitstream, and mostly uses a residual signal encoding method.

1 is a block diagram of a speech encoding / decoding apparatus using a residual signal encoding method.

As shown in FIG. 1, the speech encoding apparatus 100 includes a core encoder 101, a core decoder 103, a residual signal generator 105, a residual encoder 107, and a parameter packing unit 109. . The core encoder 101 encodes an input speech signal and outputs key parameters. The core decoder 103 outputs a core signal by decoding the core parameter output from the core encoder 101. The residual signal generator 105 generates a residual signal by subtracting the core signal output from the core decoder 103 from the input speech signal. The residual encoder 107 encodes the residual signal output from the residual signal generator 105 to output a residual parameter. The parameter packing unit 109 converts the core parameter output from the core encoder 101 and the residual parameter output from the residual encoder 107 into a predetermined bitstream and outputs the result.

The speech decoding apparatus 110 includes a core decoder 111, a speech signal reconstructor 113, a residual decoder 115, and a parameter unpacker 117. The parameter unpacker 117 converts the bitstream input from the speech encoding apparatus 100 into core parameters and residual parameters. The core decoder 111 outputs a core signal by decoding the core parameter. The residual decoder 115 decodes the residual parameter and outputs a residual signal. The voice signal reconstructor 113 adds the core signal output from the core decoder 111 and the residual signal output from the residual decoder 115 to output the reconstructed voice signal.

2 is a detailed configuration diagram of a conventional residual signal encoder and decoder, and illustrates a residual encoder and a residual decoder for encoding / decoding a residual signal using a transform encoding method.

As shown in FIG. 2, the residual encoder 107 includes a transformer 201, a transform coefficient normalizer 203, a scale factor quantizer 205, a scale factor calculator 207, and a normalized transform coefficient quantizer 209. It includes.

The converter 201 receives a residual signal in the time domain, converts the residual signal into a frequency domain, and outputs a transform coefficient. Modified Discrete Cosine Transform (MDCT) may be used as a method of converting to the frequency domain, but is not limited thereto. The scale factor calculator 207 receives the conversion coefficient from the converter 201 and calculates and outputs a scale factor. Here, the scale factor is a normalized energy obtained by dividing the total energy of the transform coefficients by the number of transform coefficients and averaging them. The scale factor quantizer 205 quantizes the scale factor output from the scale factor calculator 207. The quantized scale factor output from the scale factor quantizer 205 is input to the transform coefficient normalizer 203 and the residual decoder 115. The transform coefficient normalizer 203 divides the transform coefficient output from the transformer 201 by the quantized scale factor output from the scale factor quantizer 205 and outputs normalized transform coefficients. The normalized transform coefficient quantizer 209 quantizes the normalized transform coefficient output from the transform coefficient normalizer 203 and inputs it to the residual decoder 115. Thus, the residual encoder 107 outputs a residual parameter that is a quantized scale factor and a quantized normalized transform coefficient.

Residual decoder 115 includes a normalized transform coefficient inverse-quantizer 211, a transform coefficient inverse-normalizer 213, a scale factor inverse quantizer 215, and an inverse transformer 217.

The normalized transform coefficient inverse quantizer 211 inversely quantizes the quantized normalized transform coefficient output from the normalized transform coefficient quantizer 209 and outputs the restored normalized transform coefficient. The scale factor de-quantizer 215 de-quantizes the quantized scale factor output from the scale factor quantizer 205 and outputs the reconstructed scale factor. The transform coefficient inverse-normalizer 213 converts the restored normalized transform coefficients output from the normalized transform coefficient de-quantizer 211 by the restored scale factor output from the scale factor inverse quantizer 215. Output the coefficients. The inverse transformer 217 inversely transforms the restored transform coefficients output from the transform coefficient inverse-normalizer 213 and restores the residual signal in the time domain. Inverse MDCT (IMDCT) may be used in correspondence with the MDCT in an inverse-conversion method.

The residual signal coding method using the conventional transform coding has a problem in that the harmonic component of the speech signal reconstructed due to quantization noise is distorted, and thus the sound quality is deteriorated. There is a problem.

The present invention has been proposed to solve the above problems, by improving the residual signal coding method using the conventional transform coding, by improving the sound quality by adopting a linear predictive coding model and track structure in the transform coding method An object of the present invention is to provide a residual signal encoding and decoding apparatus and a method thereof for reducing a memory and a calculation amount.

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

According to another aspect of the present invention, there is provided a residual signal encoding apparatus comprising: a transform unit which converts a residual signal in a time domain into a frequency domain and outputs a transform coefficient; A linear predictive coefficient extracting unit extracting a linear predictive coefficient from the transform coefficient; A linear predictive coefficient quantizer configured to quantize the linear predictive coefficient and output a quantized linear predictive coefficient and a corresponding index; A linear predictive analysis filter unit having a filter implemented based on the quantized linear predictive coefficients and outputting a linear predictive residual transform coefficient by performing linear predictive analysis on the transform coefficients; A band dividing unit for dividing the linear prediction residual conversion coefficient into a predetermined number of bands and outputting a linear prediction residual conversion coefficient for each band; A pulse searching unit searching the linear prediction residual transformation coefficient for each band to select an optimal pulse, and outputting a pulse parameter for the optimal pulse; And a pulse quantizer for quantizing the pulse parameters of the optimum pulse.

The present invention also provides a method of encoding a residual signal, the method comprising: converting a residual signal in a time domain into a frequency domain and outputting a transform coefficient; Extracting a linear predictive coefficient from the transform coefficient; Quantizing the linear predictive coefficients to output quantized linear predictive coefficients and corresponding indices; Outputting a linear predictive residual transform coefficient having a filter implemented based on the quantized linear predictive coefficient and performing linear predictive analysis on the transform coefficient; Dividing the linear prediction residual conversion coefficient into a predetermined number of bands and outputting a linear prediction residual conversion coefficient for each band; Searching for the linear prediction residual transformation coefficient for each band to select an optimal pulse, and outputting a pulse parameter for the optimal pulse; And quantizing the pulse parameters of the optimal pulse.

In addition, the present invention provides a residual signal decoding apparatus, comprising: a linear predictive coefficient inverse-quantizer for outputting a linear predictive coefficient reconstructed by inversely quantizing an index of a quantized linear predictive coefficient; A pulse inverse-quantizer for outputting a reconstructed pulse parameter by inversely quantizing the quantized pulse parameter; A pulse generator for generating a pulse from the recovered pulse parameter and outputting a linear prediction residual transform coefficient for each band; A band integrating unit for outputting the restored linear prediction residual transform coefficients by adding the restored linear prediction residual transform coefficients for each band; A linear prediction synthesis filter having a filter implemented based on the reconstructed linear prediction coefficients and outputting a reconstructed transform coefficient by performing linear prediction synthesis on the reconstructed linear prediction residual transform coefficients; And an inverse-transformer which inverse-converts the restored transform coefficients in the frequency domain to the time domain to restore the residual signal.

The present invention also provides a residual signal decoding method comprising: outputting a reconstructed linear predictive coefficient by inversely quantizing an index of a quantized linear predictive coefficient; De-quantizing the quantized pulse parameters to output the reconstructed pulse parameters; Generating a pulse from the reconstructed pulse parameter and outputting a reconstructed linear prediction residual transform coefficient for each band; Outputting the reconstructed linear prediction residual transform coefficient by adding the reconstructed linear prediction residual transform coefficient for each band; Outputting a reconstructed transform coefficient having a filter implemented based on the reconstructed linear predictive coefficient and performing linear predictive synthesis on the reconstructed linear predictive residual transform coefficient; And inversely transforming the reconstructed transform coefficient in the frequency domain into the time domain to recover a residual signal.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram of a residual signal encoding and decoding apparatus for encoding / decoding a residual signal using transform encoding according to an embodiment of the present invention.

The residual signal encoding apparatus and the decoding apparatus according to the present invention may be applied to a speech encoding / decoding apparatus using the residual signal encoding method of FIG. 1.

As shown in FIG. 3, the residual signal encoding apparatus 300 includes a transformer 301, a linear predictive coefficient extractor 303, a linear predictive coefficient quantizer 305, a linear predictive analysis filter 307, and a band divider 309. ), A pulse searcher 311 and a pulse quantizer 313.

The converter 301 converts the residual signal of the time domain output from the residual signal generator 105 into the frequency domain, for example, and outputs a conversion coefficient. In the present specification, the MDCT coefficient X (k) is calculated by performing MDCT transformation as shown in Equation 1 below using MDCT as an example. However, the present invention is not limited to the MDCT, and various frequency domain conversion methods can be applied without departing from the technical idea of the present invention to those skilled in the art (hereinafter, those skilled in the art). Self-explanatory

Where x (n) is the residual signal in the time domain, h (n) is the window function, n is the sample index in the time domain, k is the coefficient index in the frequency domain, and N is the size of the MDCT block.

The linear predictive coefficient extractor 303 extracts linear predictive coding coefficients from the transform coefficient X (k) output from the converter 301. The linear predictive coefficient is a function (E) representing the difference between the current transform coefficient and the transform coefficient predicted from the past p transform coefficients with respect to the total transform coefficients k, k = 0, 1, ..., N-1. P coefficients that minimize). That is, the coefficient ({a _i }, i = 1, 2, ..., p) which minimizes E of the following [Equation 2] is a linear prediction coefficient.

Where p is the linear predictive order. The linear predictive coefficient may be calculated using the Levinson-Durbin algorithm, which is an autocorrelation function (ACF), but the present invention is not limited thereto. Is apparent to those skilled in the art.

The linear predictive coefficient quantizer 305 quantizes the linear predictive coefficients output from the linear predictive coefficient extractor 303 and outputs a quantized linear predictive coefficient and its index. Quantization methods include vector quantization, split prediction vector quantization, and the like, and various quantization methods may be used. The index of the quantized linear prediction coefficient is input to the residual signal decoding apparatus 320. The quantized linear prediction coefficient is used to implement the linear prediction analysis filter 307.

The linear predictive analysis filter 307 is a filter implemented based on the quantized linear predictive coefficients output from the linear predictive coefficient quantizer 305 and performs linear predictive analysis on the transform coefficients output from the transformer 301. Output the predictive residual transform coefficient. That is, as shown in Equation 3 below, the linear prediction residual transformation coefficient R (k) is calculated.

Where {a ^` _i } is the quantized linear predictive coefficient.

In order to divide the entire residual signal band into several bands, the band divider 309 divides the linear prediction residual transform coefficients output from the linear prediction analysis filter 307 for each band and outputs the linear prediction residual transform coefficients for each band. The band dividing method includes a method of dividing at regular intervals, a method of dividing by using a critical band reflecting an auditory characteristic of a voice signal, and various band dividing methods.

The pulse searcher 311 selects an optimal coefficient by searching the linear prediction residual transform coefficient for each band output from the band divider 309. In this case, when each of the linear prediction residual transform coefficients is regarded as one pulse, each pulse may be represented by a sign, a position, and a magnitude. Therefore, when the optimal pulse is selected by searching the linear prediction residual transform coefficient (pulse), a pulse parameter composed of the sign, position, and magnitude information of the selected pulse is output.

In the process of selecting an optimal coefficient (pulse), searching the entire linear predictive residual transform coefficients of each band requires a large amount of memory and a large amount of computation since the search range is wide. However, according to an embodiment of the present invention, the pulse searcher 311 divides the linear prediction residual transform coefficient of each band output from the band divider 309 into a predetermined number of tracks and searches for an optimal pulse in each track. And the amount of calculation does not increase.

In the present specification, when a linear predictive residual transform coefficient is 40 in one predetermined band and the number of pulses to be searched is 5, a track structure as shown in Table 1 below will be described.

) 및 위치 정보([표1]에서, 첫 번째 트랙인 경우 0,5,10,15,20,25,30,35)가 나타나 있다. 각 트랙에서 각 펄스의 크기 정보를 나타내기 위해서는 별도의 코드북이 필요하다. 상기 [표1]에 나타난 실시예에서, 각 펄스의 부호 정보 및 위치 정보는 후술되는 펄스 양자화기(313)에서 부호에 대한 1비트 및 위치에 대한 3비트로 양자화되고, 크기 정보는 상기 별도의 코드북에 따른 소정의 비트로 양자화될 수 있다.As shown in Table 1, the number of tracks for dividing the linear predictive residual transform coefficient (pulse) of a specific band is 5, and the number of pulses per track is 8 (that is, having 8 positions). The number of pulses to search in a particular band is five, so one pulse is selected as the optimal pulse in each track. At this time, a pulse selected in each track is called a track selection pulse. The track structure includes sign information of each pulse in each track (

) And location information (Table 1) shows 0, 5, 10, 15, 20, 25, 30 and 35 for the first track. A separate codebook is needed to represent the magnitude information of each pulse in each track. In the embodiment shown in Table 1, the sign information and the position information of each pulse are quantized by 1 bit for the code and 3 bits for the position in the pulse quantizer 313 described later, and the size information is the separate codebook. Can be quantized to a predetermined bit according to

In this specification, a case in which a track structure as shown in Table 2 below is used as an example when the linear prediction residual transform coefficient is 40 and the number of pulses to be searched is 9 in another predetermined band will be described. .

As shown in Table 2, the number of tracks for dividing the linear predictive residual transform coefficient (pulse) of a specific band is five and the number of pulses per track is 16, 8, 8, 4, and four. In this example, the number of pulses to be searched in a specific band is 9 in total, and 3, 2, 2, 1, 1 pulses are selected as optimal pulses in each track. Each of the pulses selected in each track is called a track-specific selection pulse, and the set of track-specific selection pulses in each track is called a track-specific selection pulse combination. That is, in the embodiment of Table 2, if the pulse having the position of 0, 1, 2 in the first track is selected as the optimal pulse, the pulse having the position of 0, the pulse having the position of 1 or the position of 2 is selected. Each pulse having is a track-specific selection pulse, and a pulse having a position of 0, a pulse having a position of 1, and a pulse having a position of 2 in the first track are called track-specific pulse combinations. As described above, in the embodiment of Table 2, the sign information of each pulse may be quantized to 1 bit in the pulse quantizer 313 described later. In addition, the position information of each pulse selected in the first track may be quantized to 4 bits, the position information of each pulse of the second track and the third track may be quantized to 3 bits, and the position information of the fourth track and the fifth track may be quantized to 2 bits. . As described above, the size information of each pulse may be quantized into predetermined bits according to the separate codebook.

) 및 트랙당 검색할 펄스의 개수(g, g는 자연수,

)가 다양하게 결정될 수 있다.In addition to the above examples, various track structures may be used in consideration of the number D of linear prediction residual transform coefficients per band and the number G of pulses to be searched for each band. That is, the number of tracks (T) for searching and dividing the linear prediction residual conversion coefficient for each track by track, the number of pulses per track (2 ^m , m is a natural number,

) And the number of pulses to search per track (g, g is a natural number,

) Can be determined in various ways.

The pulse searcher 360 searches for a pulse using the track structure includes an open-loop method and a closed-loop method. The open-loop method searches the linear predictive residual transform coefficients in each track and selects the optimal pulses in order of pulses having a large magnitude (see FIG. 4). In the closed-loop scheme, linear prediction synthesis is performed in a local decoder inherent in the residual signal encoding apparatus 300 in consideration of all combinations of the original transform coefficients output from the transformer 301 and each pulse position of each track. This is a method of selecting a pulse that minimizes the difference (error value) from the converted conversion coefficient (see Fig. 5). It is apparent to those skilled in the art that the encoding apparatus includes an associative decoding apparatus. Therefore, the associated decoding apparatus is not shown. The closed-loop pulse retrieval method can obtain better sound quality than the open-loop pulse retrieval method because the associated decoding apparatus first synthesizes and selects an optimal pulse.

The pulse quantizer 313 quantizes the pulse parameter output from the pulse searcher 311 into predetermined bits and outputs the result to the residual signal decoding apparatus 320 (see FIG. 6).

In addition, as shown in FIG. 3, the residual signal decoding apparatus 320 includes a linear predictive coefficient inverse quantizer 321, a pulse inverse quantizer 323, a linear predictive synthesis filter 325, and a pulse generator 329. Band integrator 327 and inverse-converter 331.

The linear predictive coefficient inverse quantizer 321 outputs the reconstructed linear predictive coefficient by inverse-quantizing the indices of the quantized linear predictive coefficients output from the linear predictive coefficient quantizer 305.

The pulse de-quantizer 323 inversely quantizes the quantized pulse parameter output from the pulse quantizer 313 and outputs a reconstructed pulse parameter composed of the sign, position, and magnitude information of the selected optimal pulse.

The pulse generator 329 generates pulses using the sign, position, and magnitude information of the pulses output from the pulse de-quantizer 323. The pulse generated by the pulse generator 329 is a reconstructed band-specific linear prediction residual transform coefficient.

The band integrator 327 outputs the reconstructed linear prediction residual conversion coefficient by adding the pulses output from the pulse generator 450, that is, the band-specific linear prediction residual conversion coefficients in all bands.

The linear predictive synthesis filter 325 is a filter implemented based on the restored linear predictive coefficients output from the linear predictive coefficient inverse quantizer 321. The linear predictive synthesis filter 325 is applied to the linear predictive residual transform coefficients output from the band integrator 327. Perform linear predictive synthesis to output the reconstructed transform coefficients. That is, the transform coefficient (X ^` (k)) restored as shown in Equation 4 below is calculated.

Where R ^` (k) is the reconstructed linear prediction residual transform coefficient and {a ^' _i } is the quantized linear predictive coefficient.

)를 산출한다. 그러나, 본 발명이 IMDCT에 한정되는 것은 아니며, 다양한 주파수 영역 역-변환 방법이 본 발명의 기술적 사상을 벗어나지 않으며 적용될 수 있다는 점은 당업자에게 자명하다.Inverse-transformer 331 converts the reconstructed transform coefficients in the frequency domain into residual signals in the time domain. In response to an exemplary MDCT transform of the converter 301 herein, the inverse-transformer 331 performs an IMDCT transform as shown in Equation 5 below to restore the residual signal (

) Is calculated. However, it is apparent to those skilled in the art that the present invention is not limited to the IMDCT, and that various frequency domain inverse transform methods can be applied without departing from the technical spirit of the present invention.

* y (n) is the inverse transformed sample of the current block, y ^` (n) is the inverse transformed sample of the previous block.

The output signal of the inverse transformer 331, i.e., the residual signal, is input to the speech signal reconstructor 113, for example.

4 is an open-loop pulse search flow diagram that may be performed in a pulse searcher in accordance with one embodiment of the present invention.

) 및 대역별 검색할 펄스의 개수(G,

)를 고려하여 결정된다.As described above, the number of tracks per band (T), the number of pulses of each track (2 ^m ), and the number of pulses (g) to be searched in each track are the number of linear prediction residual transform coefficients (D,

) And number of pulses to search by band (G,

) Is taken into consideration.

First, the first track is selected (s401).

Next, the absolute value of each of the 2 ^m pulses existing in the selected track is taken to obtain pulse size information (S402).

The pulse absolute values are sorted in descending order (s403), and the pulses are selected in order of increasing absolute value of the pulses sorted in descending order according to the number of pulses g to be searched per track (s404). When one pulse per track is searched as shown in [Table 1], the largest pulse for each track is selected as an optimal pulse. In addition, when three pulses are searched in the first track as shown in [Table 2], the three pulses are selected as the optimal pulses in the order of the largest absolute pulse value, and similarly in the order of the largest absolute pulse values in the second to fifth tracks. Pulses are selected by the number of pulses (2, 2, 1, 1) to be searched.

Next, it is checked whether the selected track is the last track (s405), and if it is not the last track, the next track is selected (s407). Steps s402 to s405 are repeated for the next track. On the other hand, if the selected track is the last track, the pulse search ends.

Finally, by selecting the pulse having the largest pulse size in each track as the optimal pulse, a track-specific selection pulse combination (including a case in which one pulse is selected for each track) is calculated, and the track selection pulse combination is applied to all tracks. In addition, a band-specific selection pulse combination is calculated. The pulse searcher 311 outputs a pulse parameter for each of the optimum pulses included in the track-specific selection pulse combinations constituting the band-specific selection pulse combination to the pulse quantizer 313.

5 is a closed-loop pulse search flow chart that may be performed in a pulse searcher according to an embodiment of the present invention.

) 및 대역별 검색할 펄스의 개수(G,

)를 고려하여 결정된다.As described above, the number of tracks per band (T), the number of pulses of each track (2 ^m ), and the number of pulses (g) to be searched in each track are the number of linear prediction residual conversion coefficients (D,

) And number of pulses to search by band (G,

) Is taken into consideration.

As an example of the present specification, a case in which the number of tracks for each band is 5 will be described as shown in Tables 1 and 2, but it is not limited thereto.

First, a predetermined minimum error value is initialized (s501).

Next, the first pulse combination of the first track is selected (s502). When one of the eight pulses is searched in each track as in the embodiment of Table 1 above, the pulse combination may be ₈ C ₁ (= 8). One of the eight pulse combinations is selected to be the first pulse combination of the first track. In addition, when three pulses are searched in 16 pulses of the first track as in the embodiment of Table 2, there are ₁₆ C ₃ (= 560) possible pulse combinations in the first track. One predetermined pulse combination of the 560 pulse combinations is selected to be the first pulse combination of the first track.

Next, the first pulse combination of the second track is selected (s503). When one of the eight pulses is retrieved in each track as in the embodiment of Table 1 above, the first pulse combination of the second track is selected in the same manner as in step s502. When two pulses are searched in eight pulses of the second track as in the embodiment of Table 2, there are ₈ C ₂ (= 28) possible pulse combinations in the second track. One predetermined pulse combination of the 28 pulse combinations is selected to be the first pulse combination of the second track.

In the same manner, the first pulse combination of the third track, the first pulse combination of the fourth track, and the first pulse combination of the fifth track are respectively selected (s504, s505, and s506). In step S502 to S506, a track-specific pulse combination is selected.

Next, the correlation inherent in the residual signal encoding apparatus 300 for a band-specific pulse combination obtained by adding a pulse having a value of only five track-specific pulse combinations in each track and having a value of zero in the remaining positions to all tracks. The decoding apparatus performs linear prediction synthesis to generate a transform coefficient for each band (s507). The difference (error value) between the band-dependent conversion coefficient output from the associated decoding apparatus and the original conversion coefficient output from the converter 301 is calculated (s508), and the calculated error value is compared with the currently stored minimum error value (s509). If the calculated error value is smaller than the minimum error value, the minimum error value is updated (s510).

Next, it is checked whether the pulse combination selected in the fifth track is the last pulse combination in the fifth track (s511). If it is not the last pulse combination of the fifth track, the next pulse combination of the fifth track is selected (s512) and steps s507 to s511 are repeated for the next pulse combination of the fifth track.

If the pulse combination selected in the fifth track is the last pulse combination, it is checked whether the pulse combination selected in the fourth track is the last pulse combination in the fourth track (s513). If it is not the last pulse combination of the fourth track, the next pulse combination of the fourth track is selected (s514) and steps s506 to s513 are repeated for the next pulse combination of the fourth track.

In the same way, if the pulse combination selected in the fourth track is the last pulse combination, check whether the pulse combination selected in the third track is the last pulse combination (s515) and if it is not the last pulse combination in the third track, the next pulse combination in the third track Select (s516) and repeat steps s505 to s515.

If the pulse combination selected in the third track is the last pulse combination, check whether the pulse combination selected in the second track is the last pulse combination (s517) .If it is not the last pulse combination of the second track, select the next pulse combination of the second track ( s518) Repeat steps s504 to s517.

If the pulse combination selected in the second track is the last pulse combination, it is checked whether the pulse combination selected in the first track is the last pulse combination (s519). If it is not the last pulse combination of the first track, the next pulse combination of the first track is selected (s520). ) Steps s503 to s519 are repeated. On the other hand, if it is the last pulse combination of the first track, the pulse search ends.

Finally, the band-specific selection pulse combination is calculated by selecting the band-specific pulse combination that minimizes the error value. A track-specific pulse combination constituting the band-specific selection pulse combination is a track-specific selection pulse combination. The pulse searcher 311 outputs a pulse parameter for each of the optimum pulses included in the track-specific selection pulse combinations constituting the band-specific selection pulse combination to the pulse quantizer 313.

FIG. 6 is a detailed block diagram of an embodiment of the pulse quantizer and the pulse de-quantizer of FIG. 3.

As shown in FIG. 6, the pulse quantizer 313 includes a magnitude quantizer 601, a sign quantizer 603, and a position quantizer 605.

The magnitude quantizer 601 quantizes the magnitude information of the pulse selected in each track into predetermined bits. At this time, since the size information of each pulse does not appear in the track structure, a separate codebook is required. Therefore, the separate codebook should be inherent in the residual signal encoding / decoding apparatus. The sign quantizer 603 may quantize the sign information of the pulse into 1 bit depending on whether the sign of the selected pulse in each track is (+1) or (-1). The position quantizer 605 quantizes the position information of the pulse selected in each track into bits determined according to the number of positions per track. That is, when the number of positions per track is eight as in the embodiment of Table 1, the position information of the pulse may be quantized to 3 bits. In addition, as shown in the embodiment of Table 2, when the number of positions in the first track is 16, the pulse position information of the first track is quantized into 4 bits, and when the number of positions in the second track and the third track is 8, the second track and The position information of the pulse selected in the third track is quantized in 3 bits. When the number of positions in the fourth track and the fifth track is four, the position information of the pulse selected in the fourth track and the fifth track may be quantized in 2 bits.

Here, as described above, since the track structure according to an embodiment of the present invention provides bit information necessary for pulse code and pulse position quantization, only a codebook for providing bit information necessary for pulse size quantization is needed. The memory required for codebook storage in the residual signal encoding / decoding device is reduced and the amount of computation required for codebook retrieval is reduced.

6, pulse inverse quantizer 323 includes magnitude inverse quantizer 607, sign inverse quantizer 609, and position inverse quantizer 611.

The magnitude inverse quantizer 607 recovers the pulse size by inverse quantization of magnitude information of a predetermined bit output from the magnitude quantizer 601. The code de-quantizer 609 dequantizes code information of a predetermined bit output from the code quantizer 603 to restore a pulse code. The position inverse quantizer 611 restores the pulse position by inverse quantization of position information of a predetermined bit output from the position quantizer 605.

FIG. 7 is a graph comparing a speech spectrum processed by a residual encoding method using a conventional transform encoding method and a speech spectrum processed by a method of the present invention with original sound. After decoding a speech signal in the 2.7 kHz to 3.7 kHz band with 40 bits, decoding is performed. One result is shown. For convenience of comparison, the remaining bands all used conventional methods.

The uppermost signal in the circled portion is the spectrum of the original speech, the middle signal is the spectrum of speech processed by the method of the present invention, and the lowermost signal is the spectrum of speech processed by the conventional method. As can be seen from the graph, the spectrum of speech processed by the method of the present invention is more similar to the spectrum of the original sound than the conventional method.

As described above, the method of the present invention may be implemented as a program and stored in a recording medium (CD-ROM, RAM, ROM, floppy disk, hard disk, magneto-optical disk, etc.) in a computer-readable form. Since this process can be easily implemented by those skilled in the art will not be described in more detail.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

As described above, the present invention can improve the sound quality and reduce the memory and the calculation amount by adopting a linear predictive coding model and a track structure in the transform coding method by improving the residual signal coding method using the conventional transform coding. .

Claims (26)

In the residual signal encoding apparatus, A transformer for converting the residual signal in the time domain into the frequency domain and outputting a transform coefficient; A linear predictive coefficient extracting unit extracting a linear predictive coefficient from the transform coefficient; A linear predictive coefficient quantizer configured to quantize the linear predictive coefficient and output a quantized linear predictive coefficient and a corresponding index; A linear predictive analysis filter unit having a filter implemented based on the quantized linear predictive coefficients and outputting a linear predictive residual transform coefficient by performing linear predictive analysis on the transform coefficients; A band dividing unit for dividing the linear prediction residual conversion coefficient into a predetermined number of bands and outputting a linear prediction residual conversion coefficient for each band; A pulse searching unit searching the linear prediction residual transformation coefficient for each band to select an optimal pulse, and outputting a pulse parameter for the optimal pulse; And A pulse quantizer for quantizing a pulse parameter of the optimum pulse Residual signal encoding apparatus comprising a. The method of claim 1, The conversion unit, Outputting transform coefficients by performing an MDCT transformation Residual signal encoding apparatus. The method of claim 2, The conversion unit, Outputting MDCT coefficients by performing MDCT transformation according to Equation 1 below. Residual signal encoding apparatus. [Equation 1]

Where X (k) is the MDCT coefficient, x (n) is the residual signal in the time domain, h (n) is the window function, n is the sample index in the time domain, k is the coefficient index in the frequency domain, and N is the MDCT block. Is the size of. The method of claim 1, The linear predictive coefficient extraction unit, Outputs a linear predictive coefficient that minimizes the function value of Equation 2 below Residual signal encoding apparatus. [Equation 2]

Where E is a function representing the difference between the current transform coefficient and the transform coefficient predicted from the past p transform coefficients, a _i Is the linear predictive coefficient, p is the linear predictive order. The method of claim 4, wherein The linear predictive coefficient extraction unit, Computing the linear predictive coefficient using Levinson-Durbin algorithm Residual signal encoding apparatus. The method of claim 1, The linear predictive coefficient quantization unit, Quantized linear predictive coefficients and corresponding indices using vector quantization or partitioned prediction vector quantization Residual signal encoding apparatus. The method of claim 1, The linear prediction analysis filter unit, Output the linear prediction residual transformation coefficient according to Equation 3 below. Residual signal encoding apparatus. [Equation 3]

Where R (k) is the linear predictive residual transform coefficient and ^a` _i is the quantized linear predictive coefficient. The method of claim 1, The pulse search unit, Dividing the linear predictive residual transform coefficient for each band into a predetermined number of tracks, and searching the linear predictive residual transform coefficient for each track to select a predetermined number of optimal pulses. Residual signal encoding apparatus. The method of claim 8, The pulse search unit, A first step of selecting one track from the predetermined number of tracks; A second step of acquiring magnitude information on all pulses of the track selected in the first step; A third step of selecting optimal pulses in ascending order of magnitude information obtained in the second step according to a predetermined number of pulses to be searched per track in the track selected in the first step; And Fourth step performing steps 1 to 3 for each of the remaining tracks Residual signal encoding apparatus for performing the. The method of claim 8, The pulse search unit, A first step of initializing a predetermined minimum error value; A second step of selecting any one of track-specific pulse combinations which are pulse combinations selectable according to a predetermined number of pulses to be searched per track; A third step of generating a band-specific pulse combination by having a value only in the track-specific pulse combination selected in the second step and a pulse value of the remaining positions as 0; A fourth step of outputting the band-specific conversion coefficients, which are linearly predicted and synthesized based on the band-specific pulse combinations generated in the third step; A fifth step of calculating an error value that is a difference between the conversion coefficient for each band output from the fourth step and the original conversion coefficient output from the conversion unit; The error value calculated in the fifth step is compared with the minimum error value stored in the first step, and when the error value calculated in the fifth step is smaller, the pulse combination for each track constituting the band-specific pulse combination is included. A sixth step of selecting an included pulse as an optimum pulse and updating a minimum error value to the error value calculated in the fifth step; And Seventh step of performing steps 2 to 6 for the remaining track-specific pulse combinations Residual signal encoding apparatus for performing the. The method according to claim 9 or 10, The predetermined number of pulses to be searched per track is 1 Residual signal encoding apparatus. The method of claim 1, The pulse quantization unit, A magnitude quantizer for quantizing pulse size information among pulse parameters of an optimal pulse output from the pulse searcher into predetermined bits using a predetermined codebook; A code quantizer for quantizing the code information of pulses among the pulse parameters of the optimum pulse output from the pulse search unit into predetermined bits using a track structure of the pulse search unit; And Position quantizer for quantizing the position information of the pulse among the pulse parameters of the optimum pulse output from the pulse searcher to a predetermined bit using the track structure of the pulse searcher Residual signal encoding apparatus comprising a. In the residual signal encoding method, Outputting a transform coefficient by converting the residual signal in the time domain into the frequency domain; Extracting a linear predictive coefficient from the transform coefficient; Quantizing the linear predictive coefficients to output quantized linear predictive coefficients and corresponding indices; Outputting a linear predictive residual transform coefficient having a filter implemented based on the quantized linear predictive coefficient and performing linear predictive analysis on the transform coefficient; Dividing the linear prediction residual conversion coefficient into a predetermined number of bands and outputting a linear prediction residual conversion coefficient for each band; Searching for the linear prediction residual transformation coefficient for each band to select an optimal pulse, and outputting a pulse parameter for the optimal pulse; And Quantizing the pulse parameters of the optimal pulse Residual signal encoding method comprising a. The method of claim 13, The step of outputting the conversion coefficient, MDCT transformation to output the conversion coefficient Residual signal coding method. The method of claim 14, The step of outputting the conversion coefficient, Outputting MDCT coefficients by performing MDCT transformation according to Equation 1 below. Residual signal coding method. [Equation 1]

Where X (k) is the MDCT coefficient, x (n) is the residual signal in the time domain, h (n) is the window function, n is the sample index in the time domain, k is the coefficient index in the frequency domain, and N is the MDCT block. Is the size of. The method of claim 13, The linear predictive coefficient extraction step, Outputs a linear predictive coefficient that minimizes the function value of Equation 2 below Residual signal coding method. [Equation 2]

Where E is a function representing the difference between the current transform coefficient and the transform coefficient predicted from the past p transform coefficients, a _i Is the linear predictive coefficient, p is the linear predictive order. The method of claim 16, The linear predictive coefficient extraction step, Computing the linear predictive coefficient using Levinson-Durbin algorithm Residual signal coding method. The method of claim 13, The linear predictive coefficient quantization step, Quantized linear predictive coefficients and corresponding indices using vector quantization or partitioned prediction vector quantization Residual signal coding method. The method of claim 13, The linear prediction analysis step, Output the linear prediction residual transformation coefficient according to Equation 3 below. Residual signal coding method. [Equation 3]

Where R (k) is the linear predictive residual transform coefficient and ^a` _i is the quantized linear predictive coefficient. The method of claim 13, The pulse search step, Dividing the linear predictive residual transform coefficient for each band into a predetermined number of tracks, and searching the linear predictive residual transform coefficient in each track to select a predetermined number of optimal pulses. Residual signal coding method. The method of claim 20, The pulse search step, A first step of selecting one track from the predetermined number of tracks; A second step of acquiring magnitude information on all pulses of the track selected in the first step; A third step of selecting optimal pulses in ascending order of magnitude information obtained in the second step according to a predetermined number of pulses to be searched per track in the track selected in the first step; And Fourth step performing steps 1 to 3 for each of the remaining tracks Residual signal encoding method comprising a. The method of claim 20, The pulse search step, A first step of initializing a predetermined minimum error value; A second step of selecting any one of track-specific pulse combinations which are pulse combinations selectable according to a predetermined number of pulses to be searched per track; A third step of generating a band-specific pulse combination by having a value only in the track-specific pulse combination selected in the second step and a pulse value of the remaining positions as 0; A fourth step of outputting the band-specific conversion coefficients, which are linearly predicted and synthesized based on the band-specific pulse combinations generated in the third step; A fifth step of calculating an error value that is a difference between the conversion coefficient for each band output from the fourth step and the original conversion coefficient output from the conversion unit; The error value calculated in the fifth step is compared with the minimum error value stored in the first step, and when the error value calculated in the fifth step is smaller, the pulse combination for each track constituting the band-specific pulse combination is included. A sixth step of selecting an included pulse as an optimum pulse and updating a minimum error value to the error value calculated in the fifth step; And Seventh step of performing steps 2 to 6 for the remaining track-specific pulse combinations Residual signal encoding method comprising a. The method of claim 21 or 22, The predetermined number of pulses to be searched per track is 1 Residual signal encoding apparatus. In the residual signal decoding apparatus, A linear predictive coefficient inverse quantizer for outputting a reconstructed linear predictive coefficient by inversely quantizing an index of the quantized linear predictive coefficient; A pulse inverse-quantizer for outputting a reconstructed pulse parameter by inversely quantizing the quantized pulse parameter; A pulse generator for generating a pulse from the recovered pulse parameter and outputting a linear prediction residual transform coefficient for each band; A band integrating unit for outputting the restored linear prediction residual transform coefficients by adding the restored linear prediction residual transform coefficients for each band; A linear prediction synthesis filter having a filter implemented based on the reconstructed linear prediction coefficients and outputting a reconstructed transform coefficient by performing linear prediction synthesis on the reconstructed linear prediction residual transform coefficients; And An inverse-transformer that inverse-converts the restored transform coefficients in the frequency domain to the time domain to recover a residual signal Residual signal decoding apparatus comprising a. The method of claim 24, The pulse de-quantization unit, A magnitude de-quantizer for restoring the pulse size by inversely quantizing size information of a predetermined bit among quantized pulse parameters; A sign de-quantizer for restoring a pulse code by dequantizing sign information of a predetermined bit among quantized pulse parameters; And Position de-quantizer for restoring pulse position by inverse quantization of position information of a predetermined bit among quantized pulse parameters Residual signal decoding apparatus comprising a. In the residual signal decoding method, Inversely quantizing the indices of the quantized linear predictive coefficients and outputting the reconstructed linear predictive coefficients; De-quantizing the quantized pulse parameters to output the reconstructed pulse parameters; Generating a pulse from the reconstructed pulse parameter and outputting a reconstructed linear prediction residual transform coefficient for each band; Outputting the reconstructed linear prediction residual transform coefficient by adding the reconstructed linear prediction residual transform coefficient for each band; Outputting a reconstructed transform coefficient having a filter implemented based on the reconstructed linear predictive coefficient and performing linear predictive synthesis on the reconstructed linear predictive residual transform coefficient; And Restoring the residual signal by inversely transforming the restored transform coefficients in the frequency domain into the time domain Residual signal decoding method comprising a.

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