KR100715014B1 - Transcoder and coder conversion method - Google Patents

Abstract

According to the present invention, a spectral parameter calculating circuit 100 for calculating spectral parameters with respect to the signal Ⅹ (n) obtained by decoding the first code, and a coefficient calculating circuit 130 for inputting spectral parameters and converting them into coefficients of a band-extended signal. The noise generating circuit 120 outputs the band-limited noise signal, the gain circuit 140 multiplying the gain by the output signal of the noise generating circuit, and the coefficients from the output signal and the coefficient calculating circuit 130 of the noise generating circuit 120. A synthesis filter circuit 170 for outputting the high-band signal y (n) for band extension and a sampling frequency conversion circuit for outputting a signal s (n) up-sampled the signal x (n) at a predetermined sampling frequency ( 180), the adder 190 which adds the high-band signal y (n) and the signal s (n) to form the band extension signal z (n), and the band extension signal z (n) by encoding the second coding scheme. A transconversion transcoder having a second encoding circuit 195 for outputting to provide.

Frequency band, amount of calculation, first code, second code

Description

Transcoder and coder conversion method

The present invention relates to a transcoder that mutually converts a code according to a first coding scheme and a code according to a second coding scheme, and when converting from a first code to a second code, the frequency band of the signal is expanded. A transcoder to convert.

It is known that a frequency band of a speech signal encoded and reproduced with a low bit rate is extended on the receiving side without transmitting auxiliary information for extending the bandwidth from the transmitting side (for example, P.Jax, P.Vary, " Wideband extension of telephone speech using hidden markov model, ”Proc. IEEE Speech Coding Workshop, pp. 133-135, 2000 (hereinafter referred to as“ Non-Patent Document 1 ”).

In the conventional method described in the document 1, the filter coefficient is searched after the band expansion by using the HMM (Hidden Markov Model) on the receiving side.

On the other hand, in a transcoder that converts a code according to a first encoding method and a code according to a second encoding method, the transcoder converts after extending the band of the signal when converting from the first code to the second code. There is no precedent.

The conventional method described in P.Jax and P.Vary (see Non-Patent Document 1) requires modeling by wideband spectral envelope and filter coefficients by HMM, and has the following problems.

In other words, it is necessary to determine the parameters of the HMM model from a large number of offline voice databases in advance, which requires enormous computation time and cost.

In addition, when performing the bandwidth extension processing on the receiving side in real time, a search by the HMM model was required, which required a large amount of computation.

Accordingly, a main object of the present invention is to expand a band of a signal when converting from a first code to a second code in a transcoder that mutually converts a code according to a first coding scheme and a code according to a second coding scheme. Then, there is provided a transcoder and a code conversion method capable of performing band-expanded conversion with good sound quality with a relatively small amount of calculation when converting.

According to one aspect of the present invention, a transcoder is a transcoder for converting a code according to a first encoding method and a code according to a second encoding method. A spectral parameter calculator for calculating a spectral parameter exhibiting spectral characteristics by decoding by a first encoding method, a noise generator for generating a noise signal, a coefficient calculator for shifting the frequency of the spectral parameter, and obtaining a filter coefficient; A gain section that provides an appropriate gain to the output of the noise generator, a synthesis filter section for reproducing a band extension signal by passing the output of the gain section through a synthesis filter constructed using the coefficients, and converting a sampling frequency of the input signal An adder for adding and outputting an output signal of the filter unit, and a second code for the output signal of the adder; The second code is output by encoding by the coding method.

According to a second aspect of the present invention, a transcoder according to the second aspect of the present invention is a transcoder for converting a code according to a first encoding scheme and a code according to a second encoding scheme to input a code encoded by the first encoding scheme. A spectral parameter calculator for decoding spectral parameters representing spectral characteristics by decoding by the first encoding scheme, and an adaptive code for calculating an pitch period from the input signal to generate an adaptive codebook component based on the pitch period and the sound source signal in the past. A noise generator for generating a noise signal in the north, a coefficient calculator for shifting the frequency of the spectral parameters, and obtaining a filter coefficient, and adding an appropriate gain to at least one of the output of the noise generator and the output of the adaptive codebook. A gain unit for outputting a sound source signal, and the sound source signal to a synthesis filter constructed using the coefficients A synthesizer for reproducing a band extension signal by reproducing a signal, an adder for converting a sampling frequency of the reproduced signal, and then adding and outputting an output signal of the synthesized filter, and encoding the output signal of the adder by a second encoding scheme. The second code is outputted.

According to the third aspect of the present invention, a transcoder according to the third aspect of the present invention is a transcoder for converting a code according to a first encoding method and a code according to a second encoding method. A spectral parameter calculator that inputs and decodes the spectral parameter exhibiting spectral characteristics by decoding using a first encoding scheme; an adaptation that calculates a pitch period from the input signal and generates an adaptive codebook component based on the pitch period and a sound source signal in the past After shifting the frequency of the codebook, the noise generator for generating the noise signal, the frequency of the spectral parameters, a coefficient calculator for obtaining a filter coefficient, and a gain suitable for at least one of the output of the noise generator and the output of the adaptive codebook. A gain unit for adding and outputting a sound source signal, and for the sound source signal using the pitch period. A synthesized filter passing a pitch prefilter and inputting the pitch prefilter output signal to a synthesis filter constructed using the coefficients to reproduce a band extension signal, and converting a sampling frequency of the reproduced signal and adding the output signal of the synthesis filter unit. And the output signal of the adder is encoded by a second encoding method to output a second code.

Further, according to the present invention, the output of the adaptive codebook portion may be passed through a low pass filter having a predetermined cutoff frequency.

In addition, according to the present invention, a post filter may be configured using a weighting factor that is weighted to the coefficient, and the output signal of the synthesis filter portion may be passed through the post filter to reproduce a band extension signal.

According to one aspect of the method according to the present invention, in a transcoder code conversion method for converting a code according to a first encoding scheme and a code according to a second encoding scheme to each other, Outputting a decoded signal by decoding in a decoding method, calculating and outputting a spectral parameter representing a spectral characteristic from the decoded signal, shifting the frequency of the spectral parameter, obtaining a filter coefficient, and outputting the filter coefficient, a noise generator Gaining an output signal of the signal, passing the gained output signal to a synthesis filter configured using the filter coefficients, and outputting a signal of a band required for band conversion; converting the decoded signal to a predetermined sampling frequency Adding the converted signal and the output signal of the synthesis filter, and adding the result of the addition; Encoding by the second encoding scheme to obtain and output the second code.

According to another aspect of the method according to the present invention, the method further comprises the steps of: decoding a code encoded by the first encoding scheme by a first decoding scheme and outputting a decoded signal; Calculating and outputting, calculating a pitch period from the decoded signal, generating an adaptive codebook component based on the pitch period and a sound source signal in the past, shifting the frequency of the spectral parameter, and obtaining and outputting a filter coefficient; Gaining at least one of an output of the noise generator and the adaptive codebook component, adding the output signal, and outputting a sound source signal; passing the sound source signal through a synthesis filter configured using the filter coefficients to obtain a signal of a band required for band conversion Outputting a signal obtained by converting the decoded signal into a predetermined sampling frequency And a step, and a step for encoding the output to obtain a second code by the second coding method to the result of the addition for adding an output signal of the synthesis filter.

According to another aspect of the method according to the present invention, the method further comprises the steps of: decoding a code encoded by the first encoding method by a first decoding method and outputting a decoded signal; Calculating and outputting, calculating a pitch period from the decoded signal, generating an adaptive codebook component based on the pitch period and a sound source signal in the past, shifting the frequency of the spectral parameter, and obtaining and outputting a filter coefficient; Gaining at least one of an output of the noise generator and the adaptive codebook component, adding the output signal, performing a pitch prefilter on the sound source signal using the pitch period, and using the filter coefficients Passing the pitch pre-filtered signal through a synthesis filter is necessary for band conversion. Outputting a signal of a band, adding a signal obtained by converting the decoded signal to a predetermined sampling frequency and an output signal of the synthesis filter, and encoding the addition result by the second encoding method to encode a second code. Obtaining and outputting.

According to another aspect of the method according to the present invention, the pitch period is used as a pitch prefilter, prefilter processing is performed on the sound source signal at the gain section, and an output signal from the pitch prefilter is input to a synthesis filter. It is good also as a structure which has a step to make.

According to another aspect of the method according to the present invention, the post-filter configured by using a weighting factor that is weighted to the filter coefficient in the coefficient calculating section may have a step of inputting an output signal of the synthesis filter section.

Further, according to another aspect of the method according to the present invention, instead of the output signal from the adaptive code book portion, the output of the periodic signal generator for generating the periodic signal using the pitch period may be supplied to the gain portion.

According to the present invention, when the code according to the first encoding method is inputted and converted into a code according to the second encoding method, the signal is converted into a signal according to the second encoding method, and then converted into a signal of a high frequency by a process having a relatively small amount of calculation. By generating the signal and adding the sampling frequency of the narrow band input signal to the converted signal, there is an effect that a band extension signal (for example, 7 kHz band) can be generated.

Further, according to the present invention, an adaptive codebook signal is generated using a delay calculated from a narrow band input signal based on a past sound source signal having a high frequency component, multiplied by an appropriate gain, and added to a noise signal, such as a vowel or the like. When periodicity is required for the high frequency part, there is an effect that can generate a good widening signal of sound quality.

Further, according to the present invention, by using a pitch pre-filter for the sound source signal using delay or weighting the coefficients from the coefficient calculating circuit to provide a post filter, a better sound quality band extension signal can be generated. It can be effective.

1 is a diagram showing the configuration of a first embodiment of the present invention.

2 is a diagram showing the configuration of a second embodiment of the present invention.

3 is a diagram showing the configuration of a third embodiment of the present invention.

4 is a diagram showing the configuration of the fourth embodiment of the present invention.

5 is a diagram showing the configuration of the fifth embodiment of the present invention.

6 is a diagram showing a configuration of a modification of the second embodiment of the present invention.

* Explanation of symbols for main parts of drawings *

100: spectrum parameter calculating circuit 105: first decoding circuit

120: noise generating circuit 130: coefficient calculation circuit

140: gain circuit 170: synthesis filter

180: sampling frequency conversion circuit 195: second encoding circuit

200: planetary and silent discrimination circuit 310: gain adjustment circuit

 In order to describe the present invention in more detail, it will be described with reference to the drawings for the embodiments. In the following description, the first code is coded for a narrow band input signal of 4 kHz, and in a transcoder, the band is extended to a signal of 5 kHz or 7 kHz, and then coded according to a second coding scheme to obtain a second code. Assume getting a sign.

1 is a block diagram showing the configuration of a first embodiment of a transcoder according to the present invention. Referring to FIG. 1, the transcoder includes a first decoding circuit 105, a spectral parameter calculating circuit 100, a noise generating circuit 120, a coefficient calculating circuit 130, a synthesis filter circuit 170, and a sampling frequency conversion. A circuit 180, an adder 190, a second encoding circuit 195, a voiced / unvoiced discrimination circuit 200, a gain adjusting circuit 310, and a gain circuit 140 are provided.

The first decoding circuit 105 inputs a code according to the first encoding scheme, decodes it by the first decoding scheme, and outputs a decoded signal X (n).

The spectral parameter calculating circuit 100 divides the decoded signal X (n) into a frame (for example, 10 ms) and calculates a spectral parameter of a predetermined order P for each frame. Here, the spectral parameter is a parameter that means the spectral reformation of the audio signal for each frame, and known LPC (linear predictive encoding) analysis or the like can be used for this calculation. In addition, the spectral parameter calculator 100 converts the linear predictive coefficient α i (i = 1, ... P) calculated by the LPC analysis into an LSP (Line Spectrum Pair) parameter suitable for quantization or interpolation. Output Here, the conversion from the linear predictive coefficient to the LSP is described in, for example, the following paper, Kwanchon, Panchang "Voice Information Compression by Line Spectrum Pair (LSP) Speech Analysis Synthesis Method," Journal of the Institute of Electronics and Telecommunications, J64-A pp. 599-606, 1981 (hereinafter referred to as "non-patent document 2").

The coefficient calculating circuit 130 inputs the spectral parameters output from the spectral parameter calculating circuit 100 and converts them into coefficients of the band-extended signal. For this conversion, for example, known methods such as a method of simply shifting the frequency of the LSP to a high frequency, a nonlinear conversion method, and a linear conversion method can be used. Here, all or part of the LSP parameters are used, the existing frequency band of the LSP is shifted to a high frequency range, and then converted into a linear predictive coefficient of order P and output to the synthesis filter circuit 170.

The noise generator 120 generates a band-limited noise signal whose average amplitude is normalized to a predetermined level by the same length as the frame length, and outputs the same to the gain circuit 140. In this embodiment, white noise is used as an example of the noise signal, but other noise signals may be used.

The voiced / unvoiced discrimination circuit 200 inputs a narrow band input signal Ⅹ (n) to determine whether the signal for each frame is voiced or unvoiced. As the voiced / unvoiced determination, for example, a normalized autocorrelation function D (T) up to a predetermined delay time m for a narrow band input signal) (n) is calculated according to equation (1), and D (T) If the maximum value of D (T) is larger than a predetermined threshold value, the maximum value is determined.

(1)

(One)

The voiced / unvoiced discrimination circuit 200 outputs the voiced / unvoiced discrimination information to the gain adjustment circuit 210. In formula (1), N is the number of samples for calculating the normalized autocorrelation.

The gain adjustment circuit 310 inputs the voiced / unvoiced discrimination information from the voiced / unvoiced discrimination circuit 200, adjusts the gain given to the noise signal according to the voiced / unvoiced, and outputs it to the gain circuit 140.

The gain circuit 140 inputs the gain from the gain adjusting circuit 310 and multiplies the gain by the output signal of the noise generating circuit 120 and outputs the gain to the synthesis filter circuit 170.

The synthesis filter circuit 170 inputs an output signal from the gain circuit 140 and inputs coefficients of a predetermined order from the coefficient calculating unit 130 to form a filter, and a high frequency band signal y necessary for band expansion. outputs (n)

The sampling frequency conversion circuit 180 upsamples the narrow band input signal Ⅹ (n) to a predetermined sampling frequency and outputs the signal s (n) after upsampling.

The adder 190 adds the output signal y (n) of the synthesis filter circuit 170 and the output signal S (n) of the sampling frequency conversion circuit 180 to form a finally extended signal z (n). And print it out.

The second encoding circuit 195 inputs the output signal z (n) of the adder 190, encodes by the second encoding scheme, obtains the second code, and outputs it.

This concludes the description of the first embodiment.

Fig. 2 is a block diagram showing the construction of the second embodiment of the present invention. 2, the transcoder of the second embodiment of the present invention includes a first decoding circuit 105, a spectral parameter calculating circuit 100, an adaptive codebook circuit 110, a noise generating circuit 120, and a coefficient calculating circuit. 130, gain circuit 340, synthesis filter circuit 170, sampling frequency conversion circuit 180, the adder 160, the adder 190, the second coding circuit 195, the planetary / unvoiced discrimination circuit 200 ) And a gain adjusting circuit 210. In FIG. 2, the same reference numeral is attached to the same element as FIG. In the following, differences from the first embodiment will be mainly described, and description of the same elements as in FIG. 1 will be appropriately omitted. Referring to FIG. 2, the second embodiment of the present invention includes an adaptation codebook circuit 110 and an adder 160 in addition to the configuration of FIG.

The voiced / unvoiced discrimination circuit 200 inputs a narrow band input signal Ⅹ (n) and determines whether the signal for each frame is voiced or unvoiced. As a voiced / unvoiced determination, for example, a normalized autocorrelation function D (T) up to a predetermined delay time m for a narrow band input signal Ⅹ (n) is calculated according to Equation (1) above, and D (T) If the maximum value of D (T) is greater than the predetermined threshold value, it is determined to be planetary, otherwise unvoiced, and the determination result is output to the gain adjustment circuit 210.

In addition, the voiced / unvoiced discrimination circuit 200 supplies a value of T that maximizes the normalized autocorrelation function D (T) to the adaptive codebook circuit 110 in a pitch period T in the frame of the voiced part.

The adaptive codebook circuit 110 inputs the delay T of the adaptive codebook from the voiced / unvoiced discrimination circuit 200 and adapts the adaptive code vector p (n) based on the following sound source signal V (n) according to the following equation (2). Generate and print

(2)

(2)

The gain adjustment circuit 210 inputs the voiced / unvoiced discrimination information from the voiced / unvoiced discrimination circuit 200, adjusts the gain of the adaptive codebook signal and the gain of the noise signal according to whether the voiced or unvoiced discrimination circuit 200 is used. ).

The gain circuit 340 inputs the gain from the gain adjustment circuit 210, multiplies the gain by at least one output signal of the adaptive codebook circuit 110 and the noise generating circuit 120, and outputs the gain to the adder 160.

The adder 160 adds two kinds of signals output from the gain circuit 340 (two signals obtained by multiplying the gains by at least one output signal of the adaptive codebook circuit 110 and the noise generating circuit 120) and combining the signals. Output to filter circuit 170 and adaptive codebook circuit 110.

The synthesis filter circuit 170 inputs an output signal of the adder 160 and inputs coefficients (filter coefficients) of a predetermined order from the coefficient calculating unit 130 to form a filter, and a signal of a high frequency band required for band extension. output y (n)

According to the second embodiment of the present invention, by multiplying a gain suitable for generating an adaptive codebook signal by using a delay calculated from a narrow band input signal based on a past sound source signal of a high frequency portion and adding it with a noise signal, such as a vowel or the like. When periodicity is required for high frequency signals, a good spreading signal of sound quality can be generated. This concludes the description of the second embodiment.

Further, as a modification of the second embodiment of the present invention, instead of the adaptive codebook circuit 110 of FIG. 2, a configuration including a periodic signal generating circuit 115 may be provided as shown in FIG. The periodic signal generation circuit 115 inputs a pitch period from the voiced / unvoiced discrimination circuit 200, generates a periodic signal for this pitch period, and outputs it to the gain circuit 340. The configuration other than the periodic signal generation circuit 115 is the same as in the second embodiment.

3 is a block diagram showing a configuration of a third embodiment of the present invention. Referring to FIG. 3, the transcoder of the third embodiment of the present invention includes a first decoding circuit 105, a spectral parameter calculating circuit 100, an adaptive codebook circuit 110, a noise generating circuit 120, and a coefficient calculating circuit. 130, gain circuit 300, synthesis filter circuit 170, sampling frequency conversion circuit 180, adder 190, second coding circuit 195, planetary / silent discriminating circuit 200, gain adjustment circuit And a pitch prefilter circuit 400. In Fig. 3, the same reference numerals are attached to the same or equivalent elements as Figs. Hereinafter, differences from the second embodiment will be mainly described, and descriptions of the same elements as those in FIGS. 1 and 2 will be omitted. In this embodiment, the pitch prefilter circuit 400 is provided.

The gain circuit 300 inputs a gain from the gain adjusting circuit 210, multiplies the gain by the output signal of the adaptive codebook circuit 110 and the noise generating circuit 120, adds two kinds of signals, and pitch-adds the addition result. Output to the filter circuit 400.

The pitch prefilter circuit 400 inputs a delay T (pitch period) from the voiced / unvoiced discrimination circuit 200 and pitch-presets the sound source signal V (n) from the gain circuit 300 according to the following equation (3). After filtering, the filter is output to the synthesis filter circuit 170.

(3)

(3)

According to this embodiment, by using the pitch prefilter circuit 400 for the sound source signal using the delay, it is possible to generate a band extension signal of good sound quality. This concludes the description of the third embodiment.

Also in the present embodiment, a periodic signal generation circuit may be used in place of the adaptive codebook circuit 110 as in the modification of the second embodiment. In this case, the periodic signal generation circuit inputs a signal from the planetary / silent discrimination circuit 200 to calculate the pitch period, generates a periodic signal based on the pitch period, and outputs it to the gain circuit 300.

4 is a block diagram showing a configuration of a fourth embodiment of the present invention. 4, the transcoder of the fourth embodiment of the present invention includes a first decoding circuit 105, a spectral parameter calculating circuit 100, an adaptive codebook circuit 110, a noise generating circuit 120, and a coefficient calculating circuit. 130, gain circuit 340, adder 160, synthesis filter circuit 170, sampling frequency conversion circuit 180, adder 190, second coding circuit 195, voiced / unvoiced discrimination circuit 200 ), A gain adjustment circuit 210, and a low pass filter circuit 500. In FIG. 4, the same reference numerals are attached to the same or equivalent elements as in FIG. In the following, differences from the second embodiment will be mainly described, and description of the same elements as in FIG. 2 will be omitted. 4, a low pass filter circuit 500 having an output of the adaptive codebook circuit 110 as an input is provided.

The low pass filter (LPF) circuit 500 passes the low pass signal by the equation (4) to the output signal of the adaptive codebook circuit 110 and then outputs it to the gain circuit 340.

(4)

(4)

The cutoff frequency of the low pass filter circuit 500 is determined in advance and can be, for example, 6 Hz. In formula (4), h (n) indicates the impulse response of the low pass filter, and the symbol "*" indicates the folding operation.

This concludes the description of the fourth embodiment of the present invention. Also in the fourth embodiment of the present invention, a periodic signal generation circuit may be used instead of the adaptive codebook circuit 110 as in the modification of the second embodiment. In this case, a pitch period is calculated by inputting a signal from the voiced / unvoiced discrimination circuit 200, a periodic signal based on the pitch period is generated, and output to the gain circuit 340.

Fig. 5 is a block diagram showing the construction of the fifth embodiment of the present invention. Referring to FIG. 5, the transcoder of the fifth embodiment of the present invention includes a first decoding circuit 105, a spectral parameter calculating circuit 100, an adaptive codebook circuit 110, a noise generating circuit 120, and a coefficient calculating circuit. 130, gain circuit 300, synthesis filter circuit 170, sampling frequency conversion circuit 180, adder 190, second coding circuit 195, planetary / silent discriminating circuit 200, gain adjustment circuit (210), pitch prefilter (400), and post filter (600). In FIG. 5, the same reference numerals are attached to the same or equivalent elements as in FIG. In the following, differences from the third embodiment are mainly described, and description of the same elements as in FIG. 3 is omitted. In this embodiment, in addition to the configuration of the third embodiment, a post filter 600 is also provided.

The post filter 600 inputs a coefficient (filter coefficient) from the coefficient calculating circuit 130, weights the coefficient, performs post filtering according to equation (5), and outputs the output to the adder 190. do.

(5)

(5)

According to this embodiment, by using the post filter 600, it is possible to generate a band extension signal of good sound quality. This concludes the description of the fifth embodiment.

Also in the fifth embodiment of the present invention, a periodic signal generation circuit may be used instead of the adaptive codebook circuit 110 as in the modification of the second embodiment. In this case, a pitch is calculated by inputting a signal from the voiced / unvoiced discrimination circuit 200, and a periodic signal based on the pitch period is generated and output to the gain circuit 300.

The post filter described in the fifth embodiment may be used for the first embodiment, and the configuration of each embodiment may be combined. As mentioned above, although this invention was demonstrated based on said each Example, this invention is not limited only to the structure of the said Example, and includes the various deformation | transformation and correction which a person skilled in the art can make within the scope of the invention of each claim of a claim. Of course.

As described above, according to the present invention, when converting the code of the first encoding method from the code of the second encoding method, it is possible to generate a good band extension signal of sound quality and is suitable for application to a code conversion device such as a transcoder. Do.

Claims (31)

In a transcoder for converting a code according to a first encoding method and a code according to a second encoding method, A first decoding unit which inputs the code encoded by the first encoding method, decodes by the first decoding method, and outputs a decoded signal; A spectral parameter calculator for inputting the decoded signal to calculate and output spectral parameters representing spectral characteristics; A noise generator for generating a noise signal, A coefficient calculator for shifting the frequency of the spectral parameters to obtain and output a filter coefficient; A gain unit for giving a gain to the output signal from the noise generator and outputting the gain; A synthesis filter comprising a synthesis filter configured using the filter coefficients in the coefficient calculating unit, inputting an output signal from the gain unit and passing through the synthesis filter to output a signal of a band required for band conversion; A sampling frequency conversion circuit for outputting a signal obtained by converting the decoded signal into a predetermined sampling frequency; An adder for adding and outputting the output signal of the sampling frequency conversion circuit and the output signal of the synthesis filter unit, and And a second encoding unit which inputs an output signal of the adder, performs encoding by the second encoding method, obtains a second code, and outputs the second code. A transcoder for converting a code according to a first encoding scheme and a code according to a second encoding scheme, A first decoding unit which inputs the code encoded by the first encoding method, decodes by the first decoding method, and outputs a decoded signal; A spectral parameter calculator for inputting the decoded signal and calculating a spectral parameter indicative of spectral characteristics; An adaptive code book unit for calculating a pitch period from the decoded signal and generating an adaptive code book component based on the pitch period and a sound source signal in the past; A noise generator for generating a noise signal, A coefficient calculating unit for obtaining a filter coefficient after shifting the frequency of the spectral parameter, A gain unit for gaining at least one of an output signal of the noise generator and an output signal of the adaptive codebook, and adding the gain to output a sound source signal; A synthesis filter comprising a synthesis filter configured using the filter coefficients in the coefficient calculating unit, inputting a sound source signal from the gain unit and passing through the synthesis filter to output a signal of a band required for band conversion; A sampling frequency conversion circuit for outputting a signal obtained by converting the decoded signal into a predetermined sampling frequency; An adder for adding and outputting the output signal of the sampling frequency conversion circuit and the output signal of the synthesis filter unit; And a second encoding unit which inputs an output signal of the adder, performs encoding by the second encoding method, obtains a second code, and outputs the second code. A transcoder for converting a code according to a first encoding scheme and a code according to a second encoding scheme, A first decoding unit which inputs the code encoded by the first encoding method, decodes by the first decoding method, and outputs a decoded signal; A spectral parameter calculator for inputting the decoded signal and calculating a spectral parameter indicative of spectral characteristics; An adaptive code book unit for calculating a pitch period from the decoded signal and generating an adaptive code book component based on the pitch period and a previous sound source signal; A noise generator for generating a noise signal, A coefficient calculator for shifting the frequency of the spectral parameters to obtain a filter coefficient; A gain unit for gaining at least one of an output signal of the noise generator and an output signal of the adaptive codebook, and adding the gain to output a sound source signal; A pitch prefilter for prefiltering the sound source signal in the gain section using the pitch period; A synthesis filter comprising a synthesis filter configured using the filter coefficients in the coefficient calculator, and outputting a signal of a band required for band conversion by passing an output signal of the pitch prefilter to the synthesis filter; A sampling frequency conversion circuit for outputting a signal obtained by converting the decoded signal into a predetermined sampling frequency; An adder for adding and outputting the output signal of the sampling frequency conversion circuit and the output signal of the synthesis filter unit, and And a second encoding unit which inputs an output signal of the adder, performs encoding by the second encoding method, obtains a second code, and outputs the second code. A transcoder for converting a code according to a first encoding scheme and a code according to a second encoding scheme, A first decoding unit which inputs the code encoded by the first encoding scheme, decodes by the first decoding scheme, and outputs a decoded signal; A spectral parameter calculator for inputting the decoded signal to calculate a spectral parameter indicative of spectral characteristics; A periodic signal generator for calculating a pitch period from the decoded signal and generating a periodic signal using the pitch period; A noise generator for generating a noise signal, A coefficient calculator for shifting the frequency of the spectral parameters to obtain a filter coefficient; A gain unit for gaining at least one of an output signal of the noise generator and an output signal of the periodic signal generator, and adding the gain to output a sound source signal; A synthesis filter comprising a synthesis filter configured using the filter coefficients in the coefficient calculating unit, inputting a sound source signal from the gain unit and passing through the synthesis filter to output a signal of a band required for band conversion; A sampling frequency conversion circuit for outputting a signal obtained by converting the decoded signal into a predetermined sampling frequency; An adder for adding and outputting the output signal of the sampling frequency conversion circuit and the output signal of the synthesis filter unit, and And a second encoding unit which inputs an output signal of the adder, performs encoding by the second encoding method, obtains a second code, and outputs the second code. In a transcoder for converting a code according to a first encoding method and a code according to a second encoding method, A first decoding unit which inputs the code encoded by the first encoding method, decodes by the first decoding method, and outputs a decoded signal; A spectral parameter calculator for inputting the decoded signal to calculate a spectral parameter indicative of spectral characteristics; A periodic signal generator for calculating a pitch period from the decoded signal and generating a periodic signal using the pitch period; A noise generator for generating a noise signal, A coefficient calculator for shifting the frequency of the spectral parameters to obtain a filter coefficient; A gain unit for gaining at least one of an output signal of the noise generator and an output signal of the periodic signal generator, and adding the gain to output a sound source signal; A pitch prefilter for performing prefiltering on the sound source signal in the gain section using the pitch period; A synthesis filter comprising a synthesis filter configured using the filter coefficients in the coefficient calculator, and outputting a band signal for band conversion through the output signal of the pitch prefilter to the synthesis filter; A sampling frequency conversion circuit for outputting a signal obtained by converting the decoded signal into a predetermined sampling frequency; An adder for adding and outputting the output signal of the sampling frequency conversion circuit and the output signal of the synthesis filter unit; And a second encoding unit which inputs an output signal of the adder, performs encoding by the second encoding method, obtains a second code, and outputs the second code. 4. The transcoder according to claim 2 or 3, further comprising a low pass filter for inputting an output signal of the adaptive codebook section and passing a signal having a frequency below a predetermined cutoff frequency. The post filter according to any one of claims 1 to 5, further comprising a post filter configured by using a weighting factor that is weighted to the filter coefficient in the coefficient calculating unit. Reproducing the band-converted signal by passing the output signal of the synthesis filter unit through the post filter, And the adder adds the output signal of the post filter to the output signal of the sampling frequency conversion circuit instead of the output signal of the synthesis filter unit. 4. The adaptive codebook of claim 2 or 3, wherein the adaptive codebook comprises: a pitch period from a voiced / unvoiced discrimination circuit for inputting the decoded signal from the first decoder to output voiced / unvoiced discrimination information and pitch period information; And an adaptive codebook circuit for inputting a sound source signal input to the synthesis filter unit. 7. The pitch period according to claim 4 or 5, wherein the period signal generation unit inputs the decoding signal from the first decoding unit and outputs the pitch period from the voiced / unvoiced discrimination circuit for outputting voiced / unvoiced discrimination information and pitch period information. And a periodic signal generating circuit serving as an input. 6. The pitch prefilter according to claim 3 or 5, wherein the pitch prefilter inputs a pitch period from a voiced / unvoiced discrimination circuit which inputs the decoded signal from the first decoder to output voiced / unvoiced discrimination information and pitch period information. And performing pitch pre-filtering on the sound source signal from the gain section and outputting the pitch to the synthesis filter section. 2. The apparatus of claim 1, wherein the first decoding unit inputs the decoded signal to output voiced and unvoiced discrimination information, and A gain adjustment circuit for inputting the voiced / unvoiced discrimination information from the voiced / unvoiced discrimination unit and adjusting the gain of the output signal from the noise signal generation unit according to whether it is voiced or unvoiced, And the gain section includes a gain circuit that receives a gain signal from the gain adjustment circuit and provides a gain to an output signal from the noise generator. The voice and voice discrimination circuit of claim 2 or 3, wherein the first decoding unit inputs the decoded signal to output voice and voice discrimination information and pitch period information. A gain adjustment circuit for inputting voiced / unvoiced discrimination information from the voiced / unvoiced discrimination unit and adjusting gains of the adaptive codebook signal and the output signal from the noise generator according to voiced or unvoiced application, A gain circuit for inputting a gain signal from the gain adjusting circuit, multiplying a gain of at least one output signal of the adaptive codebook and the noise generating section, and outputting the gain signal; And a second adder for adding and outputting two kinds of signals respectively corresponding to the output signals of the adaptive code book section and the noise generating section, output from the gain circuit, And the output signal of the second adder is supplied to the synthesis filter unit and the adaptation code book unit. The voice and voice discrimination circuit of claim 4 or 5, wherein the first decoder inputs the decoded signal to output voice and voice discrimination information and pitch period information. A gain adjustment circuit for inputting voiced / unvoiced discrimination information from the voiced / unvoiced discrimination unit and adjusting gains of the output signal from the periodic signal generator and the noise generator according to whether it is voiced or unvoiced, The gain unit inputs a gain signal from the gain adjustment circuit, multiplies a gain by at least one output signal of the periodic signal generator and the noise generator, and outputs the gain; A second adder for adding and outputting two kinds of signals respectively corresponding to the output signal of the periodic signal generator and the noise generator, output from the gain circuit; And the output signal of the second adder is supplied to the synthesis filter unit. The method according to any one of claims 1 to 5, wherein the coefficient calculating unit obtains a filter coefficient after shifting the frequency of the spectral parameter to a high frequency, The synthesis filter unit reproduces a signal having an extended band, And the sampling frequency conversion circuit inputs the decoded signal from the first decoding unit, upsamples it to a predetermined sampling frequency, and outputs the decoded signal. The transcoder according to any one of claims 1 to 5, wherein the noise generator generates a noise signal whose average amplitude is normalized to a predetermined level, and the band-limited noise signal is equal to a frame length. 12. The apparatus of claim 11, wherein the voiced / unvoiced discrimination circuit calculates a normalized autocorrelation function up to a predetermined delay time with respect to the decoded signal, obtains a maximum value of the normalized autocorrelation function, and sets the maximum value to a predetermined threshold. And if the value is larger than the value, it is discriminated as voiced, or unvoiced, and outputs the discrimination result to the gain adjusting circuit as the voiced / unvoiced discrimination information. The apparatus of claim 12, wherein the voiced / unvoiced discrimination circuit calculates a normalized autocorrelation function up to a predetermined delay time for the decoded signal, obtains the maximum value of the normalized autocorrelation function, and the maximum value is predetermined. If it is larger than the threshold, it is discriminated as voiced, otherwise unvoiced, and the result of determination is output to the gain adjusting circuit as the voiced / unvoiced discrimination information, and in the frame of the voiced part, the delay value for maximizing the normalized autocorrelation function is pitch period. A transcoder, characterized in that for supplying to the adaptation code book. 15. The apparatus of claim 13, wherein the voiced / unvoiced discrimination circuit calculates a normalized autocorrelation function up to a predetermined delay time with respect to the decoded signal, obtains a maximum value of the normalized autocorrelation function, and sets the maximum value to a predetermined threshold. If it is larger than the value, it is discriminated as voiced, or unvoiced, and the result of the discrimination is output to the gain adjusting circuit as the voiced / unvoiced discrimination information. And a supply to the periodic signal generator. In the code conversion method of a transcoder for converting a code according to a first encoding method and a code according to a second encoding method, Decoding a code encoded by the first encoding scheme by a first decoding scheme and outputting a decoded signal; Calculating and outputting spectral parameters representing spectral characteristics from the decoded signal; Shifting the frequency of the spectral parameters and calculating and outputting a filter coefficient; Gaining an output signal from the noise generator, Outputting a signal of a band required for band conversion by passing an output signal giving the gain to a synthesis filter configured using the filter coefficients; Adding the signal obtained by converting the decoded signal to a predetermined sampling frequency and the output signal of the synthesis filter; and And encoding the addition result by the second encoding method to obtain and output a second code. In the code conversion method of a transcoder for converting a code according to a first encoding method and a code according to a second encoding method, Decoding a code encoded by the first encoding scheme by a first decoding scheme and outputting a decoded signal; Calculating and outputting spectral parameters representing spectral characteristics from the decoded signal; Calculating a pitch period from the decoded signal, and generating an adaptive codebook component based on the pitch period and a previous sound source signal; Shifting the frequency of the spectral parameters and calculating and outputting a filter coefficient; Gaining at least one of a noise output from the noise generator and the adaptive codebook component, adding the gain, and outputting a sound source signal; Outputting a signal of a band required for band conversion by passing the sound source signal to a synthesis filter configured using the filter coefficients; Adding the signal obtained by converting the decoded signal to a predetermined sampling frequency and the output signal of the synthesis filter; and And encoding the addition result by the second encoding method to obtain and output a second code. In the code conversion method of a transcoder for converting a code according to a first encoding method and a code according to a second encoding method, Decoding a code encoded by the first encoding scheme by a first decoding scheme and outputting a decoded signal; Calculating and outputting spectral parameters representing spectral characteristics from the decoded signal; Calculating a pitch period from the decoded signal, and generating an adaptive codebook component based on the pitch period and past sound source signals; Shifting the frequency of the spectral parameters and calculating and outputting a filter coefficient; Gaining at least one of a noise output from the noise generator and the adaptive codebook component, adding the gain, and outputting a sound source signal; Performing a pitch prefilter process on the sound source signal using the pitch period; Outputting a signal of a band required for band conversion through the pitch prefiltered signal to a synthesis filter configured using the filter coefficients; Adding the signal obtained by converting the decoded signal to a predetermined sampling frequency and the output signal of the synthesis filter; and And encoding the addition result by the second encoding method to obtain and output a second code. In the code conversion method of a transcoder for converting a code according to a first encoding method and a code according to a second encoding method, Decoding a code encoded by the first encoding scheme by a first decoding scheme and outputting a decoded signal; Calculating and outputting spectral parameters representing spectral characteristics from the decoded signal; Calculating a pitch period from the decoded signal to generate a periodic signal using the pitch period, Shifting the frequency of the spectral parameters and calculating and outputting a filter coefficient; Gaining a noise output from the noise generator and at least one of the periodic signal and adding the same to output a sound source signal; Outputting a signal of a band required for band conversion by passing the sound source signal to a synthesis filter configured using the filter coefficients; Adding the signal obtained by converting the decoded signal to a predetermined sampling frequency and the output signal of the synthesis filter; And encoding the addition result by the second encoding method to obtain and output a second code. In the code conversion method of a transcoder for converting a code according to a first encoding method and a code according to a second encoding method, Decoding a code encoded by the first encoding scheme by a first decoding scheme and outputting a decoded signal; Calculating and outputting spectral parameters representing spectral characteristics from the decoded signal; Calculating a pitch period from the decoded signal to generate a periodic signal using the pitch period, Shifting the frequency of the spectral parameters and calculating and outputting a filter coefficient; Gaining a noise output from the noise generator and at least one of the periodic signal and adding the same to output a sound source signal; Performing a pitch prefilter process on the sound source signal using the pitch period; Outputting a signal of a band required for band conversion through the pitch prefiltered signal to a synthesis filter configured using the filter coefficients; Adding the signal obtained by converting the decoded signal to a predetermined sampling frequency and the output signal of the synthesis filter; and And encoding the addition result by the second encoding method to obtain and output a second code. 24. The method according to any one of claims 19 to 23, further comprising the steps of: reproducing a band-converted signal through an output signal of the synthesis filter unit, in a post filter configured using a weighting factor that is weighted to the filter coefficient; And adding the output signal of the post filter to the signal obtained by converting the decoded signal to a predetermined sampling frequency instead of the output signal of the synthesis filter. 22. The code conversion method according to claim 20 or 21, comprising performing a low pass filter process on the adaptive codebook component. 24. The method according to any one of claims 19 to 23, wherein the noise generator comprises generating and outputting a band-limited noise signal whose average amplitude is normalized to a predetermined level by a time length equal to the frame length. Code conversion method. 20. The method as claimed in claim 19, further comprising the steps of: discriminating the meteor / voice by the voiced / voiceless discrimination unit for inputting the decoding signal and outputting the voiced / voiceless discrimination information, Adjusting the gain of the output signal from the noise generator according to whether the voiced / unvoiced discrimination information is voiced or unvoiced, and And giving the adjusted gain to the output signal from the noise generator. 22. The method of claim 20 or 21, further comprising: discriminating the meteor / voice by the planetary / unvoice discrimination unit for inputting the decoded signal and outputting the meteor / unvoice discrimination information and the pitch period information; Adjusting at least one gain of the adaptive codebook signal and the output signal from the noise generating unit according to whether the voiced / unvoiced discrimination information in the voiced / unvoiced discrimination unit is voiced or unvoiced, Multiplying and outputting the adjusted gain signal by at least one of the adaptive codebook signal and the output signal of the noise generator; And outputting a signal obtained by adding at least one of the adaptive codebook signal multiplied by a gain and an output signal of the noise generator as a sound source signal. 24. The method as claimed in claim 22 or 23, further comprising: discriminating the meteor / voice by the voiced / unvoiced discriminator inputting the decoded signal and outputting voiced / unvoiced discrimination information and pitch period information; Adjusting at least one gain of the periodic signal and the output signal from the noise generator according to whether the voiced / unvoiced discrimination information in the voiced / unvoiced discriminator is voiced or unvoiced, Multiplying and outputting the adjusted gain to at least one of the periodic signal and the output signal of the noise generator, and And outputting a signal obtained by adding at least one of the periodic signal multiplied by the gain and the output signal of the noise generator as a sound source signal. 28. The apparatus of claim 27, wherein the voiced / unvoiced discriminator calculates a normalized autocorrelation function up to a predetermined delay time with respect to the decoded signal, obtains a maximum value of the normalized autocorrelation function, and the maximum value is a predetermined threshold. If greater than or equal to unvoiced, and outputting the discrimination result as the voiced / unvoiced discrimination information. 29. The apparatus of claim 28, wherein the voiced / unvoiced discriminator calculates a normalized autocorrelation function up to a predetermined delay time with respect to the decoded signal, obtains a maximum value of the normalized autocorrelation function, and the maximum value is a predetermined threshold. If larger than voiced, otherwise determined to be unvoiced, outputting the discrimination result as the voiced / unvoiced discriminant information, and outputting a delay value for maximizing the normalized autocorrelation function as a pitch period in a frame of the voiced part; Code conversion method, characterized in that.

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