AU689134B2 - Low bit rate encoder, low bit rate encoding method, low bit rates decoder, low bit rate decoding method for digital audio signals, and recording media on which signals coded by such encoder or encoding method are recorded - Google Patents

Description

a Low Bit Rate Encoder, Low Bit Rate Encoding Method, Low Bit Rates Decoder, Low Bit Rate Decoding Method for Digital Audio Signals, and Recording Media On Which Signals Coded By Such Encoder or Encoding Method Are Recorded BACKGROUND OF THE INVENTION Field of the Invention This invention relates to a low bit rate encoder and a low bit rate encoding method for compression-encoding audio signals of multi-channel system, a low bit rate decoder and a low bit \o rate decoding method for decoding compression-coded signals, and recording media on which signals encoded by such encoder/encoding method are recorded, which are used cinema film projection systems or stereo or multi-sound acoustic systems such as video tape recorder or video disc player, etc.

:'T5 Description of the Related Art Various efficient encoding techniques and devices for audio or speech signals, etc. are known.

As an example of the efficient encoding technique, there is a blocking frequency band division system, which is so called transform coding, for blocking, an audio signal, euc. in the time region every time unit to transform signals on the time base every blocks into signals on the frequency base (orthogonal transform) thereafter to divide them into signal components in a plurality of frequency bands to encode those signal components every respective frequency bands.

Moreover, there can be enumerated sub-band coding (SBC) ~L ~sL-lll~b~eC -~81 ~slsPW-s~-- IIII~ II~Is~~ which is non-blocking frequency band division system in which an audio signal, etc. in the time region is divided into signal components in a plurality of frequency bands without blocking it every unit time thereafter to encode them.

Further, there have been proposed efficient coding techniques and devices in which the sub-band coding and the transform coding described above are combined. In this case, an input signal is divided into signal components in a plurality of frequency bands by the sub-band coding thereafter 1 to orthogonally transform signals every respective frequency bands into signals in the. frequency region to implement coding to these orthogonally transformed signal components in the frequency region.

Here, as a filter for frequency band division of the S.1. above-described sub-band coding, there is, a filter of QMF, etc. Such filter is described in, the literature "Digital coding of speech in subbands" R.E.Crochiere, Bell Syst. Tech. J., Vol. 55, No. 8, 1976. This filter of QMF serves to halve the frequency band into bands of equal bandwidth. This filter is characterized in that so called aliasing does not take place in synthesizing the above-mentioned divided frequency bands at later processing stage.

Moreover, in the literature "Polyphase Quadrature filters-A new subband coding technique", Joseph H. Rothweiler ICASSP 83, BOSTON, -filter division technique of equal bandwidth is described. This polyphase quadrature filter is characterized in that division can be made at a time in dividing-a signal into signal components in a plurality of frequency bands of equal bandwidth.

Further, as the above-described orthogonal transform processing, there is, such an orthogonal transform system to divide an input audio signal into blocks by a predetermined unit time (frame) to carry out Fast Fourier Transform (FFT), Discrete Cosine Transform (DCT), or Modified DCT Transform (MDCT), etc. every respective blocks to thereby transform signals on the time base into those on the frequency base.

SThis MDCT is described in the literature "Subband/Transform \o Coding Using Filter Bank Designs Based on Time Domain Aliasing Cancellation", J.P. Princen A.B. Bradley, Univ. of Surrey Royal Melbourne Inst. of Tech. ICASSP 1987.

Further, as frequency division width in the case of encoding (quantizing) respective frequency components divided into iS frequency bands, there is band division in which, hearing sense characteristic of the human being is taken into consideration. Namely, there are instances where an audio signal S is divided into signal components in plural 25) bands by a bandwidth such that the bandwidth becomes broader according as frequency shifts to higher frequency band side, which is 9* generally called critical band.

In addition, in encoding data every respective bands at this time, coding by a predetermined bit allocation every respective bands or adaptive bit allocation every respective bands is carried out.

For example, in encoding coefficient data obtained after undergone the MDCT processing by the above-mentioned bit allocation, coding is carried out by adaptive allocation bit W~1 i C~ P_ I _L1 III s number with respect to MDCT coefficient data every respective bands obtained by MDCT processing every respective blocks.

As the bit allocation technique and device therefore, the following two techniques and device are known.

SFor example, in the literature "Adaptive Transform Coding of Speech Signals", IEEE Transactions of Acounstics, Speech, and Signal Processing, vol. ASSP-25, No. 4, August 1977, bit allocation is carried out on the basis of magnitudes of signals every respective bands.

lo Moreover, for example, in the literature "The critical band coder digital encoding of the perceptual requirements of the auditory system", M.A. Kransner MIT, ICASSP 1980, there are described the technique and the device in which necessary signal-to-noise ratios are obtained every frequency bands by making used of the hearing sense masking to carry out fixed bit allocation.

Meanwhile, in the efficient compression encoding system for audio signals using subband coding, etc. as described above, such a system to compress audio data by making use of the characteristic of the hearing sense of the human being so that its data quantity becomes equal to about 1/5 has been already put to practice.

It should be noted that there is a system called ATRAC (Adaptive TRansform Acoustic Coding, Trade Name by SONY Corporation) used in, MD (Mini Disc, Trade Name by SONY Corporation) as the efficient encoding system of compressing audio data so that its data quantity becomes equal to about However, in the efficient coding system utilizing the I I-1C-11~-53~~ -CI- g I 3characteristic of the hearing sense of the human being, there are examples where sound of musical instrument or voice of human being, etc. obtained by compression-coding a speech signal thereafter to decode that coded signal might be changed from original sound although such a phenomenon takes place to a little degree. Particularly, in the case where this efficient coding system utilizing the characteristic of the hearing sense is used for recording format of recording media for which fidelity reproduction of original sound is required, realization of higher io sound quality is required.

On the contrary, format of such an efficient coding system (ATRAC system, etc.) to compress audio signal so that its signal (data) quantity becomes equal to about 1/5 has been already put into practice, and hardware employing such a format is being '5 popularized.

Accordingly, implementation of change or expansion having no compatibility of'the format is disadvantageous not only to manufactures (makers) which have used the format but also to general users.

For this reason, it is expected to attain high sound quality based on device in encoding or decoding without changing the format itself.

"As the method of realization of higher sound quality except for the above, it is conceivable to mix linear PCM sound into ordinary compressed data. However, since compressed data of the efficient coding system and linear data are different in length of frame and time length per each frame, it is difficult to take synchronization at the time of reproduction. Accordingly, it is II II I-II I ~L9 very difficult to use. these data of two formats at the same time.

Further, not only in the case of ordinary audio equipments, but also in, W. cinema film projection system, high definition television, or stereo or multi-sound acoustic system such as video tape recorder or video disc player, etc., audio signals of plural channels of 4 8 channels are being handled. Also in this case, it is expected to carry out efficient coding to reduce bit rate.

Particularly, in the cinema film, there are instances where, io digital audio signals of 8 channels of left channel, left center channel, center channel, right center channel, right channel, surround left channel, surround right channel and sub-woofer channel are recorded. In this case, the above-mentioned efficient coding to reduce bit rate is required.

Namely, it is difficult to ensure, on the cinema film, the area capable of 8 channels of linearly quantized audio data of sampling frequency of 44.1 kHz and 16 bits as used in so called CD (Compact Disc), etc. Accordingly, compression of the audio data is required.

It should be noted that channels of 8 channel data recorded on the cinema film respectively correspond to left speaker, left center speaker, center speaker, right center speaker, right speaker, surround left speaker, surround right speaker, and sub-woofer speaker, which are disposed on the screen side where, pictures reproduced from the picture recording areas of cinema film are projected by projector.

The center speaker is disposed in the center on the screen side, and serves to output reproduced sound by audio data of .41911 I I center channel. This center speaker outputs the most important reproduced sound, speech of actor, etc.

The sub-woofer speaker serves to output reproduced sound by audio data of sub-woofer channel. This sub-woofer speaker effectively outputs sound which feels as vibration rather than sound in low frequency band, sound of explosion, and is frequently used effectively in scene of explosion.

The left speaker and the right speaker are dispcosed on left and right sides of the screen, and serve to output reproduced o0 sound by audio data of left channel and reproduced sound by audio data of right cnannel, respectively. These left and right speakers exhibit stereo sound effect.

The left center speaker is disposed between the left speaker and the center speaker, and the right center speaker is disposed between the center speaker and the right speaker. The left center speaker outputs reproduced sound by audio data of left channel, and the right center speaker outputs reproduced sound t by audio data of right center channel. These left and right center speakers perform auxiliary roles of the left and right o speakers, respectively.

4 54 Particularly, in movie-theater having large screen and large number of persons to be admitted, etc., there is the drawback •that localization of sound image becomes unstable in dependency upon seat positions. However, the above-mentioned left and right oo..

center speakers are added to thereby exhibit effect in creating more realistic localization of sound image.

Further, the surround left and right speakers are disposed so as to surround spectator's seats. These isurround left and CI dl~ d right speakers serve to respectively output reproduced sound by audio data of surround left channel and reproduced sound by audio data of surround right channel, and have the effect to provide reverberation or impression surrounded by hand clapping or shout of joy. Thus, it is possible to create sound image in more three-dimensional manner.

In addition, since defect, etc. is apt to take place on the surface of a medium of cinema film, if digital data is recorded as it is, data missing takes place to much degree. Such a lo recording system cannot be employed from a practical point of view. For this reason, ability of error correcting code is the very important.

Accordingly, with respect to the data compression, it is necessary to carry out compression processing to such a degree i5 that recording can be made in the recording area on the film by taking bits for correcting code into consideration.

From facts as described above, as the compression method of compressing digital audio data of 8 channels as described above, there is applied the efficient coding system the ATRAC 2 system) to attain sound quality comparable to CD by carrying out optimum bit allocation by taking into consideration the characteristic of the hearing sense of the human being as described above.

However, with this efficient coding system, sound of general musical instrument or voice of the human being, etc. is varied from original sound similarly to the above although such a phenomenon takes place to a little degree. For this reason, in the case where such a system is employed in recording format for I- dL -1 which reproduction having fidelity to original sound is required, any meap' for realizing higher sound quality is required.

This problem always exists as long as in the case where systems except for the above-mentioned efficient coding system is used as multi-channel recording format in the cinema film, irreversible compression system is employed from a viewpoint of ensuring of the recording area.

Moreover, in the system of implementing efficient coding to audio signals of multi-channel system as described above, data of respective channels are independently caused to undergo compression processing.

For this reason, even if, a certain one channel is in unvoiced sound state, fixed bit (byte) allocation amount is allocated to that channel.

Giving fixed bit allocation amount to the channel in unvoiced sound state as stated above is redundant.

o• Moreover, since bit allocation amounts are the same also with respect to 1 channel of a signal of low level and channel of signal of high level, if bit allocation "'•amounts are evaluated over respective channels, redundant bits exist.

SIt is considered that particularly in the case where bit allocation amounts are fixed every respective channels, redundancy as described above becomes more conspicuous.

S: 20 Object and Summary of the Invention It is an object of the present invention to overcome or at least amediorate one or more of the disadvantages of the prior art.

.o Accordingly, in a first aspect, there is provided a low bit encoder adapted for compression-encoding digital audio signals of a plurality of channels, the low bit rate encoder comprising: energy detecting means for detecting energies of the digital audio signals of each respective channel; bit allocation amount determining means for determining bit allocation amounts for the respective channels on the basis of the detected energies; compression-encoding means for compression-encoding the digital audio signals on the basis of the bit allocation amounts allocated to the respective channels; and multiplexing means for multiplexing the compression-encoded digital audio signals of the respective channels, the bit allocation amount determining means operative to determine bit allocation amounts so that the relationship between the energy and the bit allocation amount of the digital audio signals represents a non-linear characteristic based upon human hearing sense such that, as energy of the digital audio signals increases, the bit IN:\LIBE101475:SEC .r In a second aspect, there is provided a low bit rate encoder adapted for compression-encoding digital audio signals of a plurality of channels, the low bit rate encoder comprising: energy detecting means for detecting energies of the digital audio signals of each respective channel; bit allocation amount determining means for determining bit allocation amounts for the respective channels on the basis of the detected energies; compression-encoding means for compression-encoding the digital audio signals on the basis of the bit allocation amounts allocated to the respective channels; and multiplexing means for multiplexing the compression-encoded digital audio signals of the respective channels, the bit allocation amount determining means operative to determine bit allocation amounts so that the relationship between the energy and the bit allocation 15 amount of the digital audio signals represents a non-linear characteristic based upon human hearing sense such that, as energy of the digital audio signals increase, the bit allocation amounts, as a whole, increase, wherein the non-linear characteristic of the bit allocation amount determining means is such that, when energy of the digital audio signal is sufficiently large, the bit allocation amount decreases.

20 In a third aspect, there is provided a low bit rate encoding method of compression-encoding digital audio signals of a plurality of channels, the method comprising the steps of: .detecting energies of the digital audio signals of each respective channel; determining bit allocation amounts for the respective channels on the basis of the detected energies; compression-encoding the digital audio signals on the basis of the bit allocation amounts allocated to the respective channels; and multiplexing the compression-encoded digital audio signals of the respective channels, wherein, the step of determining bit allocation amounts, the relationship between energy and bit allocation amount of the digital audio signals represents a non- I Sj^* IN;\LIBE101475SEC r I pllb C s rCd~- I linear characteristic based upon human hearing sense such that, as energy of the digital audio signals increases, the bit allocation amounts, as a whole, increase, wherein the non-linear characteristic is approximated by a substantially S-shaped curve, beginning at a low bit allocation amount for a first energy level, increasing to a higher bit allocation amount for a second energy level higher than the first energy level, and decreasing to a bit allocation lower than the higher bit allocation amount for a third energy level higher than the second energy level.

In a fourth aspect, there is provided a low bit rate encoding method of compression-encoding digital audio signals of a plurality of channels, the method 1 o comprising the steps of: detecting energies of the digital audio signals of each respective channel; the, determining bit allocation amounts for the respective channels on the basis of the detected energies: compression-encoding the digital audio signals on the basis of the bit allocation 15 amounts allocated to the respective channels, and multiplexing the compression-encoded digital audio signals of the respective channels, wherein, in the step of determining bit allocation amounts, the relationship between energy and bit allocation amount of the digital audio signals represents a non- 20 linear characteristic based upon human hearing sense such that, as energy of the digital audio signals increases, the bit allocation amounts, as a whole, increase, wherein the non-linear charactertcic is such that, when energy of the digital audio signal is sufficiently large, the bit allocation amount decreases.

IN :IBE1O01475SEC according to this invention, the energy detecting means is amplitude information detecting means for detecting amplitude information of digital audio signals of respective channels before undergone compression-coding. Further, the bit allocation amount determining means determines bit allocation amounts to respective channels on the basis of change in point of time of the amplitude information.

In this case, the bit allocation amount determining means calculates (determines), by a predetermined conversion formula, io bit allocation amounts with respect to peak values of amplitule information of respective channels on the basis of the hearing sense characteristic, thus to determine amounts of bits to be allocated to respective channels on the basis of the conversion result.

.Y Moreover, the bit allocation amount determining means respectively determines estimated amounts of bit amounts to be allocated to respective channels from the predetermined conversion formula to allocate bit allocation amounts of respective channels in proportion to the respective estimated a6 amounts to thereby allow the total bit allocation quantity of all channels to be fixed.

"On the other hand, low bit rate decoder of the first embodiment according to this invention includes decoding means for decoding signals of respective channels encoded by the low bit rate encoder of the first embodiment.

Further, in low bit rate encoder of the second embodiment according to this invention, the energy detecting means is means for detecting change in point of time of a predetermined scale I I L~ LC~ "CCl factor (normalized value of the two-dimensional areas of time and frequency (block floating units)) with respect to signals of the respective channels, and the bit allocation amount determining means serves to carry out variable bit allocation between channels in dependency upon change of scale factors.

Also in low bit rate encoder of the second embodiment, the bit allocation amount determining means calculates (determines), by a predetermined conversion formula, bit allocation amount with respect to change in point of time of sum total of scale factors \o of respective channels on the basis of the characteristic of the hearing sense of the human being to determine bit amounts to be allocated to the respective channels on the basis of the conversion result.

Further, the bit allocation amount determining means respectively calculates (determines) estimated amounts of bit amounts to be allocated to respective channels from the predetermined conversion formula to allocate bit allocation

S.

amounts of respective channels in proportion to respective estimated amounts to thereby allow total bit allocation amount of all channels to be fixed.

In addition, low bit rate decoder of the second embodiment according to this invention includes decoding means for decoding signals of respective channels encoded by the low bit rate encoder of the second embodiment.

,i 2 In accordance with this invention, in compression-coding audio data of a plurality of channels, since there is employed an approach to determine bit allocation amounts to respective channels on the basis of changes in point of time of energies of "4~11pllC CPql I -r respective channels thus to carry out compression-coding, bit allocation in correspondence with information amounts can be carried out with respect to respective channels.

In addition, in accordance with this invention, in compression-coding audio data of a plurality of channels, the relationships between energies and bit allocation amounts at respective channels are caused to be non-linear to carry out compression-coding on the basis of the bit allocation amounts.

For this reason, it is possible to carry out bit allocation in correspondence with information amounts with respect to respective channels.

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BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a circuit diagram showing, in a block form, outline of the configuration of a low bit rate encoder of a first 4 \5 embodiment according to this invention.

FIG. 2 is a circuit diagram showing, in a block form, outline of the configuration of a low bit rate decoder of first and second embodiments according to this invention.

FIG. 3 is a circuit diagram illustrated in a block form for explaining bit allocation in low bit rate encoder of the ATRAC system and low bit rate encoder of the embodiment according to this invention.

FIG. 4 is a view for explaining the state of recording of data within sound frame.

1 5 FIG. 5 is a ,raph for explaining bit allocation amount in the first embodiment.

FIG. 6 is a flowchart for explaining the operation of a *e S 0* 0

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I _I r eP qll determination of bit allocation amount in the first embodiment.

FIG. 7 is a circuit diagram showing, in a block form, outline of the configuration of a low bit rate encoder of a second embodiment according to this invention.

FIG. 8 is a graph for explaining bit allocation amount in the second embodiment.

FIG. 9 is a flowchart for explaining the operation of determination of bit allocation amount in the second embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS K\ Preferred embodiments of this invention will r.a be described with reference to the attached drawings.

The fundamental configuration of a first embodiment according to this invention is shown in FIGS. 1 and 2. The configuration of a low bit rate encoder of the first embodiment @o 5' is shown in FIG. 1, and the configuration of a low bit rate a@9 decoder of the first embodiment is shown in FIG. 2.

The configuration of the encoder shown in FIG. 1 will be first described.

Audio signals of a plurality of channels (chl, ch2, jo chn) are sent to sampling and quantizing elements 1001 l00n corresponding to respective channels via input terminals 20) 20 and transmission paths 1i 1, similarly corresponding to respective channels. At these sampling and quantizing elements 1001 100,, audio signals of respective channels are converted into quancized signals. Quantized signals from these sampling and quantizing elements 1001 100, are sent to amplitude information detecting circuit 200 and delay lines 3001 300, via ~LI-l LL ~L1 IDII- al- respective transmission lines 21 2 n The amplitude information detecting circuit 200 detects amplitude information from quantized signals of respective channels. Namely, this amplitude information detecting circuit 5 200 detects peak values of amplitude information every periods corresponding to the number of samples (hereinafter referred to as time blocks) of audio data processed at a time by encoding elements 4001 400, which will be described later to send (transfer) these peak values to bit allocation determining \O circuit 500 via transmission lines 4 1 4, corresponding to respective channels. It should be noted that this amplitude information detecting circuit 200 may be of a structure to detect amplitude information by signals from transmission lines 11 l,.

The bit allocation determining circuit 500 determines, by conversion, bit allocation amounts every respective channels from peak values every respective channels in a manner described later to send (transfer) these bit allocation amounts to respective encoding elements 4001 400 n via transmission lines 51 5 n s ee Moreover, the delay lines 3001 300, delay signals which :1o have been received through transmission lines 21 2 n by the time blocks to send (transfer) these delayed signals to respective encoding elements 400i 400- through respective transmission lines 31 3,.

Respective encoding elements 4001 400n carry out compressing operation every time blocks. Bit allocation amounts received through transmission lines 51 5, at this time reflect peak information of signals received through the transmission lines 31 to Respective encoding elements 4001 to 400, i L~ I sl~ _I compress signals which has been received through the transmission lines 31 3, so that their bit allocation amounts are equal to bit allocation amounts which have been received through the transmission lines 51 5, to send (transfer) these compressed signals to formater 600 via respective transmission lines 61 6n.

The formater 600 implements error correcting processing to the compressed signals every channels which have been received via the transmission lines 61 6, in accordance with a to predetermined format to compose them into bit stream for transmission or recording onto recording medium. This bit stream is outputted from output terminal 21 via transmission line 7.

Further, this bit stream is written into predetermined areas 28 on cinema film 27 by laser recording unit 26, for example.

In the figure, reference numeral 29 denotes perforations adapted so that sprockets of projector (not shown) for film feeding are Sengaged therewith. The recording areas 28 are provided, e.g., between the perforations 29.

The configuration of low bit rate decoder of this embodiment 2o will now be described with reference to FIG. 2.

9 Bit stream composed by the encoder (low bit rate encoder) of FIG. 1 is transmitted or is recorded onto a recording medium.

This recorded bit stream is delivered to input terminal 22 via a predetermined reproducing unit (not shown), and is then sent kS from this input terminal 22 via transmission line 8 to deformater 700.

This deformater 700 decomposes the bit stream which has been sent through the transmission line 8 into compressed signals I IL II every respective channels in accordance with a predetermined format. The compressed signals decomposed every respective channels are sent to decoding elements 8001 800, provided correspondingly every respective channels via transmission lines -91 9 n corresponding to respective channels.

Respective decoding elements 8001 800, expand the compressed signals which have been sent via the respective transmission lines 91 9 n to send them to D/A (digital/analog) converters 9001 900, via corresponding respective transmission I0 lines 101 Respective D/A converters 9001 900, convert the expanded signals (digital signals) which have been sent via the respective transmission lines 101 10, into analog signals. These signals caused to be in analog form are outputted as decoded signals of 9.

respective channels chi chn through corresponding transmission lines 111 11, and output terminals 231 23 n respectively.

The compression-encoding technique utilized in the low bit rate encoder of this embodiment as described above can be applied -to all encoders capable of varying bit rate. Here, the .o compression-encoding technique for compressing audio signal of Sstereo 2 channels at a fixed bit rate by making use of the 9 hearing sense characteristic of the human being previously 99 described so that its signal quantity is equal to about ATRAC system used in so called MD (Mini Disc)) is taken as ar example, and a compression-encoding method of this embodiment for allowing the compression at a fixed bit rate to be compression at a variable bit rate will now be described.

The configuration of encoder to which so called ATRAC system ~--~93SI _I 1 I is applied is shown in FIG. 3. It should be noted that the components from frequency band division filter 401 to re-quantizer 406, formater 407 of FIG. 3 correspond to encoding elements 4001 400, of respective channels of FIG. 1.

In FIG. 3, sampled and quantized audio data which has been delivered through input terminal 24 is first divided into signals (signal components) in three frequency bands of signal component in lower frequency band 6f 0 5.5 kHz, signal component in medium frequency band of 5.5 kHz 11 kHz, and signal component to in higher frequency band more than 11 kHz (11 kHz 22 kHz).

Among signals in three frequency bands, signal in the lower frequency band from the band division filter 401 is sent to MDCT circuit 402L for performing MDCT (Modified Discrete Cosine Transform) operation, signal in the medium frequency band is sent 9.ee to MDCT circuit 402M for similarly performing MDCT operation, and signal in higher frequency band is sent to MDCT circuit 402H for similarly performing MDCT operation. Those signals are respectively decomposed into frequency components at these MDCT circuits 402L 402H.

o At this time, time block length at the time of implementing oe e the MDCT processing is variable every respective frequency bands.

9 At the portion where signal suddenly changes, time block length t" a is shortened, thus to increase the time resolution. On the other hand, at the portion where signal is in stationary state, time block length is prolonged to control effective transmission of signal components and quantization noise.

This time block length is determined in advance at block size evaluation element 403. Namely, signals in three frequency I I bands from the band division filter 401 are sent also to block size evaluation element 403. This block size evaluation element 403 determines time block lengths of the MDCT to send information indicating the determined time block lengths to the MDCT circuits 402L 402H.

Among two kinds of time block lengths at the MDCT processing, mode using long time block length is called long mode, which has block length of time of 11.6 ms. On the other hand, mode using shorter time block length is called short mode, which has block length of time of 1.45 ms in the higher frequency band (more than 11 kHz), and has block length of time of 2.9 ms in the lower frequency band (less than 5.5 kHz) and in the medium frequency band (5.5 kHz to 11 kHz), thus to increase time resolution.

,15 Audio signals decomposed in this way into signal components in the two dimensional regions (which will be called Block Floating Units) of time and frequency are divided into 52 block floating units in total in lower, medium and higher frequency bands, and are normalized every units (determination of scale .o factors is made).

The bit allocation element 405 analyzes components constituting corresponding audio signal by making use of the characteristic of the hearing sense of the human being. This analyzed result is sent to re-quantizer 406 supplied with signals AS every respective units from the normalization c.rcuits 404L 404H.

The re-quantizer 406 determines acnracies in coding respective units on the basis of the a,~alyzed result, i.e., I carries out determination of word lengths to obtain parameters, and to carry out re-quantization.

Finally, formater 407 multiplexes respective parameter information and re-quantized spectrum signal every respective units in accordance with a predetermined format to thereby provide bit stream. An output of this formater 407 is outputted from output terminal Operation of encoding as described above is carried out every unit of sound frame.

\o The state of recording of data within the sound frame 40 is shown in FIG. 4.

In FIG. 4, one sound frame consists of 212 bits. At this sound frame, audio reproduction data of 512 samples and corresponding to one channel is compression-encoded at sampling \5 rate of 44.1 kHz.

The sound frame data of 212 bits consists of block size mode i 4L, sub-information amount 42, word length data 43, scale factor data 44, spectrum data 45, redundancy scale factor data 46, redundancy word length data 47, lower portion sub-information X6 amount 48, and lower portion block size mode 49.

9* 99* In data of 212 bits, double write portion for error correction is included. Namely, this portion consists of t o t redundancy scale factor data 46, redundancy word length data 47, lower portion sub-information amount 48, and lower portion block size mode 49.

In this example, 186 bits of the 212 bits correspond to the portion except for the double write portion, and become equal to 128 kbps in terms of substantial bit rate.

1- ~-~11111 1 f 4.

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4 4 4,r 444 6*4 4.

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4' '4 '.4 The block size mode is data for recording evaluation result of block size evaluation element 403 of FIG. 3, and its content is as shown in Table 1.

Table 1 FREQUENCY CODE MODE NO. OF BAND FREQUENCY

COMPONENTS

.HIHG 00 SHORT 32 01 LONG 256 MEDIUM 00 SHORT 32 01 LONG 128 LOW 00 SHORT 32 01 LONG 128 As seen from this Table 1, when the block length use mode is long mode, a signal subject to transform processing is decomposed into 128 frequency components by MDCT operation respectively in lower and medium frequency bands, and is Sdecomposed into 256 frequency components in higher frequency band.

M On the other, when the block length use mode is short mode, a signal subject to transform processing is decomposed into 32' frequency components respectively in lower, medium and higher frequency bands.

Further, three information of amount 1, amount 2 and amount as 3 are recorded into sub-information amount 42. Amount 1 ~I I II CI lp indicates the numbers of word lengths and scale factors recorded, amount.2 indicates the number of word lengths doubly written, and amount 3 indicates the number of scale factors doubly written.

The content thereof is shown in Table 2.

Table 2 AMOUNT 1 AMOUNT 2 AMOUNT 3 '0 *r

S.

S."5 *5*b CODE NO. CODE NO. CODE NO.

000 20 00 0 000 0 001 28 01 28 001 8 010 32 10 44 010 12 011 36 11 52 011 16 100 40 100 24 101. 44 101 36 110 48 110 44 111 52 111 52 Word lengths indicate word lengths when .respective units are re-quantized. The content in Table 3.

(signals every) thereof is shown 0* *e S

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*5 9* I I ~P-,l Table 3 j CODE WORD LENGTH CODE WORD LENGTH (NO. OF BITS) (NO. OF BITS) 0000 0 1000 9 0001 2 1001 0010 3 1010 11 0011 4 1011 12 0100 5 1100 13 0101 6 1101 14 0110 7 1110 0111 8 1111 16

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*r Scale factors indicate the values when (signals every) respective units are normalized. The content thereof is shown in Table 4.

5O 0 S. S S SS S Table 4A CODE VALUE CODE VALUE SF~n] BIT SCALE FACTOR SFI~n) BIT SCALE FACTOR PATTERN VALUE PATTERN VALUE 000000 0. 99999999x2- 5 100000 0.79370052x2 6 000001 0. 62996052x2- 4 312:,f, 01 0.99999999x2 6 000010 0. 79370052x2- 4 100010 0.6r2996052,:2 000011 0. 99999999x2- 4 100011 0.793"10052x2 7 000100 0,62996052x2- 3 100100 0.99999999x2 7 000101 O.'79370052x2- 3 100101 0.62996052x2 8 000110 0. 99999999x2- 3 100110 0.79370052x2 8 000111 0. 62996052x2- 2 100111 0.99999999x2 8 001000 0. 79370052x2- 2 101000 0.62996052x2 9 001001 0. 99999999x2- 2 101001 0.79370052x2 9 001010 0.62996052x2- 1 101010 0.99999999x2 9 9* 9 9 0* .9 9 9 9., 999* 9*99 99 I*3~ 999* 99 9 **99 9.9.

.9 99 9 9 9 9.

9 9 9 9. 9 *9 9 99 stoo see* Table 4B CODE VALUE CODE VALUE SFI~n] BIT SCALE FACTOR SFnl BIT SCALE FACTOR PATTERN VALUE PATTERN VALUE 001011 0.79370052x2-1 101011 0. 62996052x2 10 001100 O.99999999x2 1 l 101100 0.79370052x2l 0 001101 O.620996052x2 0 101101 0. 99999999x21 0 001110 0.79370052x2O 101110 O.62996052x2li 001111 0.99999999x2 0 101111 0.79370052x2ll 010000 O.62996052x2 1 110000 O.99999999x2l 1 010001 O.79370052x2 1 110001 0. 62996052x2 12 010010 O.99999999x2 1 110010 0. 79370052x21 2 010011 0.62996052x2 2 110011 0.99999999x2 12 010100 0.79370052x2 2 110100 0. 62996052x21 3 01 0101 0.99999999x2 2 110101 0.79370052x2 3 00 0 0 0* 0 0* 00 Table 4C CODE VALUE CODE [VALUE SEn] BIT SCALE FACTOR SF[n] BIT SCALE FACTOR PATTERN VALUE PATTERN VALUE 010110 0.62996052x2 3 110110 0. 99999999x2 13 010111 0.79370052x2 3 110111 0. 62996052x2 14 011000 0.99999999x2 3 111000 0. 79370052x2 14 011001 0.62996052x2'1 111001 0. 99999999x2 1 4 011010 0.79370052x2 4 111010 0.62996052x2' 011011 0.99999999x2 4 111011 0.79370052x2 1 011100 0.62996052x2 5 111100 0.99999999x2 011101 0.79370052x2 5 111101 0 .62996052x21 6 011110 0.99999999x2 5 111110 0. 79370052x21 6 011111 0.62996052x2 6 1 11111 0. 99999999x2 16 Meanwhile, bit allocation element 405 in FIG. 3 mentioned above determines values of word lengths by taking into consideration the hearing sense characteristic of the human being so that hit amount of one sound frame becomes equal to 212 bits in re-quantization. By al1o~ing the value of 212 bits to be variable, it is possible to constitute an encoder of variable length.

0 0 0* 00 0 0 0000 0 *0009 00 04.

Namely, if there is employed a configuration in which output of bit allocation determining circuit 500 of FIG. 1 constituting low bit rate encoder of the embodiment according to this AS- invention is connected to bit allocation element 405 of FIG. 3, it becomes possible to constitute encoder of variable length.

The operation of bit allocation determining circuit 500 of FIG. 1 connected to bit allocation element 405 of FIG. 3 in this way will now be described with reference to the graph of FIG. and the flowchart of FIG. 6.

Initially, when processing operation is started at step S61 -of FIG. 6, bit allocation determining circuit 500 detects peak values every respective channels at step S62. Generally, peak values correspond to energies of audio signal in respective channels.

o Then, at step S63, bit allocation amounts corresponding to the determined peak values are calculated. For this calculation, correspondence graph of peak value/bit allocation afount constructed as table is used.

^The graph of FIG. 5 is a graph for converting bit allocation amount with respect to the peak value. It should be noted that graph of conversion of bit allocation amount shown in FIG. 5 is a graph in the case where so called ATRAC system is employed as the encoding system.

0* In FIG. 5, the abscissa represents peak value of an input signal and maximum value which can take is normalized into 1.

go* Moreover, the ordinate represents bit allocation amount, and maximum allocation amount is set to 186 bytes. This value is equal to information amount of one sound frame of the ATRAC system in so called MD (Mini Disc) device.

The graph of conversion shown in FIG. 5 is determined by conducting experiment by using various audio signals.

In FIG. 5, the entire tendency of bit allocation amount is such that bit allocation amount increases with increase in peak value, but changes in a decrease direction when the peak value is above the minus third power of 2.

This is based on the experimental result that since when the signal level is sufficiently large (remarkably large), quantizing 5 noise by re-quantization is masked by signal level, sound is difficult to be heard even if amount of injection of re-quantizing noise is increased.

On the other hand, in FIG. 5, in the case where signal level is sufficiently small (remarkably small), for example, the peak value is less than the minus 12th power of 2, the bit allocation amount is caused to be fixed (flat bit allocation). This is because since bit amount necessary for respective parameter information (word length data or scale factor data, etc. shown in FIG. 4) of the ATRAC system is substantially fixed, it is necessary to ensure bit amount to some degree.

Moreover, since when the level is lowered, random noise (white noise) can be heard and such a signal has a tendency such that the frequency components are uniformly distributed over the entire frequency band, a large amount of bits are required 0 although the level is small.

As stated above, the relationship between. bit allocation amount and peak value is caused to be non-linear (substantially

C

S-shaped curve). Namely, unless the hearing sense characteristic is taken into consideration, the relationship between bit allocation amount and peak value is proportional relationship.

However, in this invention, there is employed a scheme in which while maintaining the minimum bit allocation amounts every respective channels, bit allocation amount is decreased in the 28 case where the level is above a predetermined level.

At step S64, judgment as to whether or not the entire bit amount is fixed is made. When it is judged at this step S64 that it is necessary to allow total bit allocation amount of all channels to be fixed, the processing operation proceeds to step After the above-mentioned conversion is completed, calculation of the formula which will be later is carried out to calculate the ultimate bit allocation amounts every respective channels.

Namely, when it is assumed that total bit allocation amount per one sound frame of a system of n channels is G and bit allocation amount by conversion is Ci 2, the ultimate bit allocation amount Si allocated to each channel is expressed as follows: Si Cn) (1) After processing at the step S65, or after it is judged at the step S64 that the entire bit amount is not fixed, the processing operation proceeds to step S66 to complete the processing.

a O Formater of FIG. 1 and deformater 700 of FIG. 2 are caused to be in correspondence with ATRAC system as described above, whereby they operate as described below.

S: Formater 600 of FIG. 1 places, in order of channels, data sent in a format as shown in FIG. 4 from encoding elements 4001 a5 400 n of respective channels every one sound frame to transmit it as bit stream. Namely, this formater 600 serves as multiplexer.

Further, deformater 700 of FIG. 2 serves as demultiplexer to .decompose data multiplexed at the formater 600 every respective channels to send (transfer) them to respective decoding elements 4 001 400,.

As described above, in accordance with the device (encoder/decoder) of the first embodiment according to this invention, in compression of audio data having a plurality of channels, bit allocation amounts to respective channels are determined by changes in point of time of amplitude information of respective channels to encode audio data. For this reason, to bit allocation in correspondence with information amounts can be made with respect to respective channels. Thus, more efficient coding can be made.

Namely, realization of higher sound quality or realization of low bit rate in total of all channels can be made. It should be noted that since there are instances where fixed length is desired in dependency upon medium recorded, coding may be carried out in the device of the first embodiment in a manner to allow total bit allocation amount of all channels to be approximately fixed.

.0 A second embodiment of this invention will now be described.

The configuration of a low bit rate encoder of the second embodiment is shown in FIG. 7.

In FIG. 7, audio signals of a plurality of channels (chl, ch2, chn) are sent to sampling and quantizing elements 1201 120, corresponding to respective channels via input terminals 301 30 n and transmission lines 1011 101, corresponding to respective channels. At these sampling and quantizing elements 1201 120,, audio signals of respective channels are converted into quantized signals. These quantized signals from the respective sampling and quantizing elements 1201 120, are sent to respective coding elements 2101 210, via transmission lines 1021 102,.

5 At respective coding elements 2101 2101, audio signals of respective channels are divided into signals in two-dimensional regions of time and frequency (block floating units) to normalize signal components belonging to block floating units by using scale factors every block floating units. Scale factors of respective block floating units thus determined are sent to bit allocation determining circuit 310 through transmission lines 1031 103,.

This bit allocation determining circuit 310 determines sum total every respective channels of scale factors which have been received through transmission lines 1031 103, to calculate (determine) bit allocation amounts of respective channels from the sum total by conversion formula (graph of conversion) which will be described later to send (transfer) the bit allocation .amounts from transmission lines 1041 104, to coding elements O 2101 210R.

Accordingly, respective coding elements 2101 210, re-quantize signals from the transmission lines 1021 102, in dependency upon the bit allocation amounts to send (transfer) the re-quantized, compressed signals to formater 410 through transmission lines 1051 105,.

The formater 410 composes the compressed signals received via the transmission lines 1051 105, of a plurality of channels into bit stream for transmission or recording onto recording medium in accordance with a predetermined format. This bit stream is outputted from output terminal 31 through transmission line 106.

Further, this bit stream is written into predetermined -6 recording areas 28 on cinema film 27 by, laser recording unit 26.

It should be noted that since the fundamental configuration of low bit rate decoder in the second embodiment is similar to that of FIG. 2, the detailed explanation is omitted.

to This decoder will now be briefly described with reference to FIG. 2. Deformater 700 of low bit rate decoder of the second embodiment also decomposes bit stream from low bit rate encoder of the second embo1ilment into compressed signals every respective channels in accordance with a predetermined format.

5 The compressed signals decomposed every respective channels are expanded at decoding elements 8001 800o provided correspondingly every respective channels, and are then converted into analog signals at D/A (digital/analog) converters 900 i 900 n These analog signals are outputted as decoded signals of o respective channels chl chn.

The compression-encoding technique utilized in the low bit rate encoder of the second embodiment can be applied to all systems in which compression-encoding is carried out by using scale factors.

Namely, when there is employed, also in the second embodiment, the configuration in which output of bit allocation determining circuit 310 of FIG. 7 is connected to bit allocation element 405 of FIG 3, variable length encoder can be constituted.

0 s The detailed operation of bit allocation determining circuit 310 of FIG. 7 connected to bit allocation element 405 of FIG. 3 will now be described with reference to the graph of FIG. 8 and the flowchart of FIG. 9.

Initially, when processing operation is started at step S91 of FIG. 9, bit allocation determining circuit 310 calculates sum total of scale factors every respective channels from scale factors from encoding elements 210i 210, at step S92.

At the subsequent step S93, bit allocation amounts every o respective cannels are calculated from the determined sum total of scaling factors of respective channels.

Here, scale factors are values which have normalized frequency components included in 52 block floating units as previously described. Ordinarily, an approach is employed to determine absolute values of frequency components within corresponding block floating unit to select, from values shown in the Table 4, minimum one of values more than the maximum value of those absolute values.

Namely, it is considered that scale factor indicates representative character of data within block floating unit, i.e.

0" energy. Accordingly, it is considered that if sum of scale factors is determined, it is possible to estimate the entire information amount.

Bit allocation amount with respect to sum of scale factors at bit allocation determining circuit 310 of FIG. 7 is shown in FIG, 8.

Also in FIG. 8, ATRAC system is used as the encoding system similarly to the first embodiment. In FIG. 8, the ordinate *4 .4e *4* 64 ill I _1 I represents bit allocation amount (maximum allocation amount is 186 bytes) similarly to FIG. 5, and the abscissa represents sum of scale factors.

Graph of conversion shown in FIG. 8 is determined while conducting experiments by using various audio signals similarly to the FIG. 5 of the first embodiment.

As the entire tendency, according as value of sum of scale factors increases, bit allocation amount also increases.

However, in FIG. 8, when value of sum of scaling factors is o1 above about 7000, bit allocation amount changes in a decrease direction. This is based on the experimental result that since signal level is relatively large at bit allocation amount where value of sum of scale factors is remarkably large (signal level S" is sufficiently large), and quantization noise by requantization is masked by signal level, signal is difficult to be heard even if amount of injection of re-quantization noise is increased.

On the other hand, the reason why when value of sum of scale factors is less than 1.5 (in the case where signal level is too* S: sufficiently small), bit allocation amount is fixed is that since o0 bit amount necessary for respective parameter information of the ATRAC system (word length data or scale factor data, etc. shown in the FIG. 4) is substantially fixed, it is necessary to ensure 4 S this bit amount.

Also in this example, the relationship between bit aT allocation amount and sum total of scale factors represents non-linear characteristic of substantially S-shaped curve.

Also in the second embodiment, at step S94, judgment as to whether or not the entire bit amount is fixed is carried out.

pi I I- When it is Judged at this step S94 that it is necessary to allow total bit allocation amount of all channels to be fixed, the processing operation proceeds to step S95. After the above-mentioned conversion is completed, calculation of the 17 formula is carried out to calculate the ultimate bit allocation amounts every respective channels.

After processing at the step S95, or after it is Judged at the step S94 that the entire bit amount is not fixed, the processing operation proceeds to step S96.

Also in the second embodiment, formater 410 of FIG. 7 places, in order of channels, data sent in a form as shown in FIG. 4 from encoding elements 21.01 210, of respective channels every one sound frame to transmit it as bit stream. Namely, this formater 410 serves as a multiplexer.

Further, deformater in low bit rate decoder of the second embodiment also serves as a demultiplexer to decompose data multiplexed at the formater 410 every respective channels to send (transfer) them to respective decoding elements.

As described above, in accordance with the device (encode r/decode r) of the second embodiment, in compression of audio data having a plurality of channels, an approach is employed to determine bit allocation amounts of respective a: channels by change in point of time of sum total of scale factors of respective channels to encode audio data. For this reason, 5 bit allocation corresponding to information amounts can be implemented to respective channels. Thus, more efficient encoding can be made.

By such Improvement In coding, higher sound quality or lower bit-rate can be realized. Namely, also in the second device of this embodiment, realization of lower bit rate or higher sound quality in total over the entire channel can be made.

Further, also in the case of the second embodiment, there are instances where data has fixed length in dependency upon medium recorded. In that case, encoding can be made so that total bit allocation amount of all channels is approximately fixed.

In the above-described first and second embodiments of this i invention, cinema film was exemplified as a recording medium.

However, as recording medium, not only cinema film, but also various media can be used within the range which does not depart from the gist of this invention. For example, optical disc and magnetic tape, etc. may be used.

In. this invention, since bit allocation amounts to respective channels are determined by energies, amplitude information or change in point of time of sum total of scale factors of respective channels, bit allocation corresponding to information amount can be implemented to respective channels.

0O As a result, more efficient coding can be made. Thus, higher oo sound quality of lower bit rate can be realized.

In addition, audio signals of multi-channel system in this invention refer to at least 2 channels, and the effect of this invention is conspicuous desirably in the case where the number Z of channels is 5 channels or more like sound track of cinema.

Claims (3)

1. A low bit-rate encoder adapted for compression-encoding digital audio signals of a plurality of channels, the low bit-rate encoder comprising: energy detecting means for detecting energies of the digital audio signals of each respective channel; bit allocation amount determining means for determining bit allocation amounts for the respective channels on the basis of the detected energies; compression-encoding means for compression-encoding the digital audio signals on the basis of the bit allocation amounts allocated to the respective channels; 1o and multiplexing means for multiplexing the compression-encoded digital audio signals of the respective channels, .the bit allocation amount determining means being operative to determine bit allocation amounts so that the relationship between the energy and the bit allocation e~o amount of the digital audio signals represents a non-linear characteristic based upon human hearing sense such that, as energy of the digital audio signals increases, the bit allocation amounts, as a whole increase, wherein the non-linear characteristic of the bit allocation amount determining means is approximated by a substantially S-shaped curve, beginning at a low bit allocation amount for a first energy level, increasing to a 20 higher bit allocation amount for a second energy level higher than the first energy level, and decreasing to a bit allocation lower than the higher bit allocation amount for a third energy level higher than the second energy level.

2. A low bit-rate encoder adapted for compression-encoding digital audio signals of a plurality of channels, the low bit-rate encoder comprising: energy detecting means for detecting energies of the digital audio signals of each respective channel; bit allocation amount determining means for determining bit allocation amounts for the respective channels on the basis of the detected energies; compression-encoding means for compression-encoding the digital audio signals on the basis of the bit allocation amounts allocated to the respective channels; and multiplexing means for multiplexing the compression-encoded digital audio signals of the respective channels, the bit allocation amount determining means being operative to determine bit allocation amounts so that the relationship between the energy and the bit allocation amount of the digital audio signals represents a non-linear characteristic based upon human hearing sense such that, as energy of the digital audio signals increases, the bit allocation amounts, as a whole, increase, wherein the non-linear characteristic of the bit IN:\LIBEOt10475SEC

38- allocation amount determining means is such that, when energy of the digital audio signal is sufficiently large, the bit allocation amount decreases. 3. A low bit-rate encoding method of compression-encoding digital audio signals of a plurality of channels, the method comprising the steps of; detecting energies of the digital audio signals of each respective channel; determining bit allocation amounts for the respective channels onl the basis of the detected energies; compression-encoding the digital audio signals on the basis of the bit allocation amounts allocated to the respective channels; and multiplexing the compress ion-c-ncoded digital audio signals of tile respective chann,!ls, wherein, in the step of determining bit allocation amounts, thle relationship **:between energy and bit allocation amount of the digital audio signals represents a non- linear characteristic based upon human hearing sense such that, as energy of thle digital audio signals increases, the bit allocation amounts, as a whole, increase, wherein the non-linear characteristic is approximated by a substantially S-shaped curve, beginning at a low bit allocation amount ft, a first energy level, increasing to a higher bit allocation amount for a second energy level higher than the first energy level, and decreasing to a bit allocation lower than the higher bit allocation amount for a third 20 energy level higher than the second energy level. 4. A low-!,At rate encoding method of compression-encoding digital audio signals of a plurality of channels, thle method comprising the steps of: detecting energies oi'the digital audio signals of each respective channel; :9 determining bit allocation amounts for the respective channels on the basis of thle detected energies: compression-encoding the digital audio signals onl the basis of the bit allocation amounts allocated to the respective channels, and multiplexing the compress ion-encoded digital audio signals of thle respective channels, wherein, in the step of determining bit allocation amounts, the relationship between energy and bit allocation amount of the digital audio signals represents a non- linear characteristic based upon human hearing sense such that, as energy of the digital audio signals increases, the bit allocation amounts, as a whole, increase, wherein tile non-linear chlaracteristic is such that, when energy of the digital audio signal is sufficiently large, the bit allocation amount decreases. DATED this Thirtieth Day of December 1997 Sony Corporation Patent Attorneys for the Applicant SPRUSON FERGUSON IN ILIGE101476 SEC Low Bit Rate Encoder, Low Bit Rate Encoding Method, Low Bit Rates Decoder, Low Bit Rate Decoding Method for Digital Audio Signals, and Recording Media on which Signals Coded by such Encoder or Encoding Method are Recorded ABSTRACT A low bit rate encoder adapted for compression-encoding digital audio signals of a plurality of channels by making use of both the property of the audio signal and the hearing sense of the human being is disclosed. The encoder comprises an energy detecting section (200) for detecting energies of the digital audio signals of the respective channel a bit allocation amount determining section (500) for determining bit allocation amounts for the respective channels on the basis of the detected result; a compression-encoding section (400) for compression-encoding the digital audio signals on the basic of the bit allocation amounts allocated to every respective channp 1 li; accordance with determined bit allocation amounts; and a multiplexing section (600) for multiplexing the compression-encoded signals every respective channels. The bit allocation amount determining means (500) is operative to determine bit allocation amounts so that the relationship between the energy and the bit allocation amount of the digital audio signal represents a non-linear characteristic, such that according as energy of the digital audio signal increases, the bit allocation amount increases as a whole. Thus, redundancy of bit allocation amount in compression-encoding of the multi-channel system is eliminated, and high 25 quality compression encoding/decoding can be realized. o Figure 1 4595F/CMS