Variable transfer rate control coding apparatus, reproducing apparatus and recording medium

Abstract

A variable transfer rate control coding apparatus which can distribute codes of an amount most suitable to the contents of a moving picture to be recorded and to a recording medium, on which information is recorded by this transfer rate coding apparatus, by obtaining an amount of codes to be temporarily generated in each unit period of time by a temporary or tentative coding, and then storing a temporary transfer rate (namely, a value of the temporary amount of codes to be generated in each unit period of time), and setting a target transfer rate (namely, a target value of an amount) of codes to be sent in each unit period of time from a total of the temporary transfer rates and the recordable capacity of the recording medium and next performing an actual or real coding according to the target transfer rates.

Description

This application is a continuation of application Ser. No. 08/142,280 filed Oct. 28, 1993, now abandoned.

BACKGROUND OF THE INVENTION

1. Field of The Invention

This invention generally relates to a highly-efficient encoding technique to be employed for efficiently performing a coding (or encoding) in digital-signal recording, transmission and display apparatuses to generate a smaller amount of codes (hereunder sometimes referred to simply as code amount). More particularly, this invention relates to a coding apparatus adapted to perform a coding of a moving picture signal by controlling a transfer rate and also relates to a recording medium on which a code generated by the coding apparatus is recorded. Further, this invention relates to a reproducing apparatus for reading moving picture information from the recording medium. More particularly, this invention relates to a variable transfer rate recording information reproducing apparatus for reproducing moving picture information recorded on a recording medium, which information represents a code generated by changing an amount of information corresponding to a predetermined period of time, and also relates to the recording medium on which the moving picture information is recorded.

2. Description of The Related Art

When a variable length code is used in performing a highly efficient coding of an image signal, a part of an image represented by the image signal, which part contains a small amount of image information, is coded or converted into a small amount of codes. Therefore, it is reasonable for increasing the efficiency of coding to employ a variable length coding. Especially, in case of an inter-image predictive coding of each frame or field of a moving picture, an amount of codes corresponding to a part having no motion is very little. Thus, the efficiency of transmission or recording of information or codes can be increased if the transmission or recording is effected by making the visual picture quality of a moving picture nearly constant and changing a transfer rate according to an aspect of the moving picture.

Such a way of transmitting information is called an asynchronous transmission mode (ATM) which is extensively studied as a packet transmission in the field of communication. In this case, basically, codes are generated at a predetermined transfer rate. Further, packets (or cells) are discarded on a transmission network if necessary. Thus, an amount of information or codes is controlled.

Meanwhile, in case of recording media termed package media (for example, a video tape recorder (VTR), a video disk or the like as presently used), information is recorded thereon at predetermined tape speed or a predetermined rotational speed. As the result, an amount of information recorded on the recording medium in a unit period of time (or a unit time slot) becomes constant. Therefore, the capacity of the recording medium can be indicated in terms of the length of available recording time. For instance, in case that a moving picture of 100 minutes is recorded on a recording medium whose maximum recording time is 120 minutes, the remaining capacity of the recording medium corresponding to the recording time of 20 minutes is space for recording another picture.

To make the most of the capacity of a recording medium, a transfer rate should be changed according to the contents of a picture to be recorded and thus the total amount of codes recorded thereon should be suited to the capacity thereof. However, in case of a conventional coding apparatus, the transfer rate is fixed to a constant value as will be described hereinbelow by referring to FIG. 1.

FIG. 1 is a schematic block diagram for illustrating the configuration of an example of the conventional coding apparatus. Incidentally, the coding apparatus of FIG. 1 is in conformity with CCITT (International Telegraph and Telephone Consultative Committee) specified standard system.

As shown in this figure, image signals are inputted to a predictive subtracter 2 and an activity detector 4 through an image input terminal 31. Incidentally, what is called activity indicates a degree of change in data, which is represented by an image signal, between adjacent blocks. In the predictive subtracter 2, an inter-frame prediction signal (hereunder sometimes referred to simply as a prediction signal) inputted from an inter-image predicting device 13 is subtracted from the image signal. Then, a prediction residual signal representing a result of the subtraction is outputted from the predictive subtractor 2 to a discrete cosine transform (DCT) device 3.

Next, in the DCT device 3, a DCT is performed on the prediction residual signal. Then, a signal representing a result of the DCT is outputted from the DCT device 3 to a quantizer 6 whereupon a quantization is effected according to a quantization step width (namely, a quantization step size) designated by information inputted from a quantization controller 5 thereon.

The quantized signal is next inputted to a variable length coder 7 and a local decoder 15. Further, in the device 7, information represented by the inputted signal is converted into a compressed code. Subsequently, a signal representing the compressed code is inputted to a buffer 32. Note that data (namely, the compressed code) inputted to the buffer 32 is converted by the device 7 into a variable length code. Thus, an amount of generated codes changes or fluctuates constantly. However, such change in amount of the generated codes is absorbed by the buffer 32. As the result, the generated code is outputted to a decoding apparatus (shown in FIG. 3) from a code output terminal 11 at a constant transfer rate.

On the other hand, in the local decoder 15, an inverse quantization and an inverse DCT are performed on the quantized signal inputted thereto. Thereby, the code is decoded and as a consequence, a reproduced prediction residual signal is produced. Then, the reproduced prediction residual signal is inputted to an adder 14 whereupon the inter-frame prediction signal inputted from the inter-image predicting device 13 is added to the reproduced prediction residual signal inputted from the local decoder 15. Subsequently, a reproduced image signal representing a result of this addition is supplied to an inter-image predicting device 13 whereupon the reproduced image signal is delayed by one frame and a motion compensation is effected to generate an inter-frame prediction signal. The generated inter-frame signal is supplied from the inter-image predicting device 13 to the prediction subtracter 2 and the adder 14.

Further, the quantization is controlled according to what is called an occupancy of the buffer and to the activity of an original image.

Thus, information representing the occupancy of the buffer 32 and the activity detected by the activity detecting device 4 is inputted to the quantization controller 5 whereupon a quantization step width is set according to the inputted information. Further, a signal indicating the quantization step width is inputted to the quantizer 6. Incidentally, the quantization step width is set in such a manner to be wide (namely, quantization is coarse) when many codes are stored in the buffer 32 and to be narrow (namely, quantization is fine) when the buffer 32 is almost empty. Such a characteristic of the quantization step width is shown in FIG. 2.

FIG. 2 is a diagram for illustrating the manner of the quantization control, which shows an example of the relation between the occupancy of the buffer and the quantization step width.

In case of controlling the quantization according to the activity, the quantization step width is wide (namely, the quantization is coarse) when the activity is large. Further, the quantization step width is narrow (namely, the quantization is fine).

This is due to the fact that in case of a block having large activity, change in image signal is large and that an error is not noticeable and that in contrast, in case of a block having small activity, even a small error is conspicuous.

Practically, the value of the quantization step width set according to the occupancy of the buffer is multiplied by a multiplier which ranges from (½) to 2 and is set according to the activity regarding each block.

At that time, if the average value of the activity is 1, the average value of the quantization step width does not change.

In case of this conventional coding apparatus, for instance, a variance of tone levels (or density levels) of pixels of a block is employed as an activity. Incidentally, when using DCT or the like, a quantization error is conspicuous in a block of an edge portion. Therefore, it is preferable that an edge portion is detected before the activity is determined, and subsequently, the activity of a block of the detected edge portion is regulated in such a way not to become large.

By using the activity of an input image as described above, subjective visual picture quality can be made to be uniform.

Next, a conventional decoding apparatus will be described hereinbelow by referring to FIG. 3.

FIG. 3 is a schematic block diagram for illustrating the configuration of an example of the conventional decoding apparatus.

As shown in this figure, codes inputted from a code input terminal 20 to a buffer 41 at a constant transfer rate are outputted to a variable length decoder 22 in synchronization with a processing to be effected therein.

In he variable length decoder 22, the variable length code is converted into a fixed length code. Then, in the dequantizer 23, the fixed length code is converted into a quantization representative value (hereunder sometimes referred to simply as a quantization representative). The quantization representative is inputted to an inverse DCT device 24 whereupon an inverse DCT is performed on the quantization representative to produce a reproduction predictive residual signal. Then, the reproduction predictive residual signal is applied to the adder 14.

Next, in the adder 14, a prediction signal inputted from the inter-image predictor 13 is added to the reproduction predictive residual signal to generate a signal (hereunder referred to as a reproduced image signal) representing a reproduced image. This reproduced image signal is outputted from an image output terminal 25. Further, the reproduced image signal is also inputted to the inter-image predictor 13.

However, as described above, in case of the conventional coding apparatus, the transfer rate is controlled in such a manner to be constant. Thus, the conventional coding apparatus has a drawback in that although an amount of codes corresponding to a portion of an image is sufficient and a corresponding quantization step width is too narrow, an amount of codes corresponding to another portion of the image is insufficient and a corresponding quantization step width is large (namely, quantization is coarse) and thus the picture quality is degraded.

Further, in case of the conventional coding apparatus, a coding is performed at a constant transfer rate irrespective of the length (or duration) of a moving picture. Thus, the conventional coding apparatus has another drawback in that if the length of a moving picture is shorter than the maximum recordable time of a recording medium to be used to record the moving picture, a part of the recordable area of the recording medium remains unused.

Meanwhile, in case of an apparatus for reproducing information from a recording medium as above described, it is usual that information representing an image or an audio is continuously read and reproduced from the medium and thus there is no necessity of special control of reproduction of the information.

In case of a constant-line-velocity (CLV) disk medium is which a line velocity is constant, a rotational frequency should be changed according to the position on a disk. However the rotational frequency

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, preferred embodiments of the present invention will be described in detail by referring to the accompanying drawings.

FIG. 4 is a schematic block diagram for illustrating the configuration of a variable transfer rate control coding apparatus embodying the present invention.

In this figure, like reference characters designate like or corresponding parts of the conventional apparatus of FIG. 1.

Principal differences between the coding apparatuses of FIGS. 1 and 4 (namely, composing elements of FIG. 4 which are not contained in FIG. 1) are a VTR 1, selectors 8 and 9, a temporary code amount counter 16, a code amount controller 17, a target transfer rate setting device 18 and a temporary transfer rate memory 19.

Hereinafter, a coding performed in this variable transfer rate control coding apparatus will be described in detail by referring to FIG. 4.

A coding is performed on a same moving picture signal two times. At first time, a coding process is performed for effecting a temporary coding for setting a target transfer rate corresponding to each unit period of time. At second time, another coding process is performed for effecting an actual coding (or a real coding). Therefore, in case of a coding apparatus which performs a coding at the same speed as the running speed of a moving picture, the processing time required for performing the coding process twice is nearly two times the running time of the moving picture.

A method for fixing a total amount of codes to a constant value and distributing the amounts of codes by performing such a feed forward processing has been proposed by the inventor of the present invention. Basic ideas employed in this method are described in previous Japanese Patent Applications (see, for example, the Japanese Unexamined Patent Publication (Kokai Tokkyo Koho) Official Gazette Nos. S63-151225, H2-194734 and H3-263927).

An object to be processed by the apparatus of the present invention is a moving picture signal. Further, the activity is not used as an estimate of an amount of codes. Moreover, the apparatus of the present invention performs a coding, which is the same as a real coding, and uses an output coded by a variable length coding. In contrast, in cases of the apparatuses of the previous applications, a unit period (hereunder sometimes referred to as a target-transfer-rate setting unit period), to which a target transfer rate is set correspondingly, is equal to a unit period (hereunder sometimes referred to as a control-operation unit period), to which a control operation is effected correspondingly. However, in case of the apparatus of the present invention, a target-transfer-rate setting unit is equal to a predetermined unit period of time and a control operation unit period is less than the predetermined unit period of time. Further, a target transfer rate is set in such a manner to become less than a corresponding temporary transfer rate and to be less than a predetermined upper limit as will be described.

When performing a temporary coding, quantization control is not performed according to the occupancy of a buffer. Instead, a transfer rate corresponding to each unit period of time is fixed to a predetermined value and then a temporary amount of codes corresponding to each unit period of time (namely, a temporary transfer rate) is obtained. Upon completion of this processing, the conversion characteristics between the temporary transfer rate and the corresponding target transfer rate are determined from the total amount of codes and the capacity of the recording medium correspondingly to each unit period of time.

When performing an actual coding (namely, a real coding), the target transfer rate is established from the corresponding temporary transfer rate and the conversion characteristics every unit period of time. Moreover, the real coding is controlled according to the occupancy of the buffer and the target rates. Incidentally, the target transfer rate is set in such a fashion that moving picture signals to be recorded are just stored in the recordable area of the recording medium. Thus, so long as the buffer does not overflow, the total amount of codes obtained as the result becomes adapted to the recording medium.

At least, during each unit period of time, the transfer rate is not changed and is kept constant. Usually, a buffer 10 has capacity corresponding to an amount of codes generated in a period of 0.2 to 0.3 second. Further, instantaneous change in amount of codes is absorbed by the buffer 10. Thus, the unit period of time is set to be a little longer than the length of a short period in which the change in amount of codes occurs. Namely, it is preferable that the unit period of time is set as adapted to change of a long period. For example, the unit period of time is set to be 0.5 to 0.1 second.

Incidentally, in cases of the apparatus of the previous applications, simple activity is used when estimating an amount of codes. In contrast, in case of this embodiment, a nearly same coding is performed two times. Thus, there is no necessity of simplifying a coding process. Therefore, similarly as in case of the real coding, a variable length coding is performed as the temporary coding. Consequently, an exact amount of generated codes can be obtained from an output signal representing a result of the coding.

Conversely, there has been proposed a method of using a plurality of quantizers and variable length coders and estimating an amount of codes by effecting different types of quantization. In case of this method, what is called cyclic prediction is employed for performing a coding. Thus, differences in quantization influence a result of the prediction. Consequently, a precise amount of codes can not be obtained if a plurality of quantizers and a plurality of variable length coders are not provided for the inter-image prediction or the like.

Next, a temporary coding means 30 of this embodiment will be described in detail hereinbelow. The temporary coding means 30 is used to obtain the temporary transfer rate for transferring the moving picture signal.

As showing in FIG. 4, an image signal outputted from the VTR 1 is inputted to the prediction subtracter 2 and the activity detector 4. In case of this embodiment, the same image signal is supplied to a coding portion two times. Therefore, all image signals before coded are recorded on a mass image recording medium such as VTR. For instance, a memory element as optical disk and a hard disk drive (HDD) which have sufficient capacity may be employed as the mass image recording medium.

In case of the apparatus of FIG. 4, a basic coding process is similarly to that of the conventional apparatus. First, a prediction signal supplied from the inter-image predictor 13 is subtracted by the prediction subtracter 2 from the image signal outputted from the VTR 1. Then, a signal representing a result of this subtraction (namely, a predictive residual) is inputted to the DCT device 3. Thereafter, a DCT operation and a quantization operation are effected by the DCT device 3 and the quantizer 6, respectively. Subsequently, this quantized signal is inputted to the variable length coder 7 and the local decoder 15. Information represented by the quantized signal is converted by the variable length coder 7 into a compressed code. This compressed code is then inputted to the selector 9.

At the time, an input to the selector 8 is switched to a terminal A through which a predetermined fixed value is inputted to the quantization controller 5 as the occupancy of the buffer. Thus the quantization is changed only by the activity corresponding to each block, which is inputted from the activity detector 4 to the quantization controller 5. Incidentally, the fixed value is set in such a way that the image coded by using this fixed value has sufficient picture quality.

On the other hand, in the local decoder 15, the code is decoded to produce a reproduced prediction residual signal. This reproduced prediction residual signal is then inputted to the adder 14 whereupon the prediction signal inputted from the inter-image predictor 13 is added to the reproduced prediction residual signal. Then, a reproduced image signal represented a result of this addition is inputted to the inter-image predictor 13 whereupon an inter-frame prediction signal is generated from the reproduced image signal. Subsequently, the inter-frame prediction signal is supplied to the prediction subtracter 2 and the adder 14.

In case of the apparatus of FIG. 4, at time of the first coding, an output of the variable length coder 7 is inputted to the temporary code amount container 16 through the selector 9. Further, an amount of codes generated in each unit period of time is counted by the temporary code amount counter 16 and a signal representing the count (namely, the amount of codes generated in each unit period of time) is then outputted therefrom.

Next, a target transfer rate setting means 40 will be described in detail hereinbelow. This target transfer rate setting means 40 is used to set a target transfer rate from the temporary amount of codes each unit period of time in such a manner that a total of amounts of codes generated from the moving picture signals becomes a predetermined value.

The temporary transfer rate outputted from the temporary code amount counter 16 is inputted to the code amount controller 17 and the temporary transfer rate memory 19. In the temporary transfer rate memory 19, all of the transfer rates respectively corresponding to unit periods of time, which are used again in the actual coding (real coding), are stored.

For instance, in case where a moving picture, the running time of which is 1 hour, is represented by a set of data corresponding to 1 second, the amount or number of data to be stored is 3600. The code amount controller 17, whose configuration is shown in FIG. 5, is used to determine the conversion characteristics between the temporary transfer rates and the target transfer rates.

FIG. 5 is a schematic block diagram for illustrating the configuration of the code amount controller 17 of this embodiment.

As shown in this figure, the temporary transfer rate inputted from the temporary transfer rate input terminal 51 is converted by n transfer rate converting devices (hereunder sometimes referred to simply as converters) 52, 53, 54, . . . whose conversion characteristics are different from one another. Thereafter, the transfer rates respectively corresponding to the conversion characteristics are accumulated by the accumulation adders 55, 56, . . . 57 over the entire running time of the moving picture. Thus the total amount of codes, which are generated from the entire picture and correspond to each of the converters, is obtained.

Upon completion of the temporary coding, the total amounts of codes corresponding to the transfer rate converting devices (or converters) are inputted to comparators 58, 59, . . . 60, respectively, whereupon the inputted total amounts of codes are target total amounts of codes set from the recordable capacity of the recording medium. Then, outputs of the comparators are inputted to a judgment device 61 for making comparisons between each pair of the output of the comparators. The judgement device 61 determines and selects the conversion characteristic corresponding to the total amount of codes which is less than the target total amount of codes but is greater than any of the total amounts of codes corresponding to the other conversion characteristics. Then, information representing the selected conversion characteristic is inputted from the conversion characteristic information output terminal 62 to the target buffer rate setting device 18 of FIG. 4. FIG. 6 shows the conversion characteristics corresponding to the converters 1 to n.

Namely, FIG. 6 is a graph for showing the conversion characteristics between the temporary transfer rates and the target transfer rates corresponding to each unit period of time. As shown in this figure, the upper limit (Rmax) to the outputs of the transfer rate converting devices is first determined. This is due to the facts that there is an upper limit to the processing ability (or throughputs) of the recording medium and the decoder and that the maximum transfer rate is determined according to this upper limit to the throughputs. Therefore, although the variable transfer rates are employed, the maximum target transfer rate is a fixed value.

As shown in this figure, for example, logarithmic characteristics are employed as the conversion characteristics, by which change in each target transfer rate is compressed or suppressed throughout in comparison with change in each temporary transfer rate, corresponding to the transfer rate converting devices. Namely, each target transfer rate is controlled as gently increases. In case of a portion of the picture, which portion corresponds to a small temporary amount of codes corresponding to each unit period of time, degradation in visual picture quality is conspicuous. Therefore, the amount of codes is somewhat increased.

The conversion characteristics between the temporary transfer rate X and the target transfer rate R are given by, for instance, the following equations:

R=K*LOG(Y*X);

or

R=K*X^Z

wherein K and Y are positive numbers and Z is a positive number less than 1. The conversion characteristics can be changed by changing the values of Y and Z.

Namely, when the target transfer rate corresponding to each unit period of time is obtained by converting the temporary transfer rate corresponding to each unit period of time, the conversion is effected by making a ratio of increase in the target transfer rate to corresponding increase in the temporary transfer rate less than 1 and limiting the maximum value of the target transfer rate to a constant value.

The larger the number n of kinds of the conversion characteristics becomes, the more precise the selected conversion characteristics become. Thus, waste in capacity of the recording medium becomes smaller.

Incidentally, in case of the code amount controller 17 of FIG. 5, the transfer rate converting devices, the accumulation adders and the comparators are placed in parallel with one another as illustrated in this figure and operate in parallel with the temporary coding. However, the apparatus may employ a serial processing instead of such a parallel processing.

In case of employing a serial processing, the code amount controller has only one transfer rate converting device, one accumulation adder and one comparator, which are as illustrated in FIG. 5. In this case, after the temporary coding is finished and before the real coding is performed, the total amounts of codes corresponding to various conversion characteristics are calculated from the data stored in the temporary transfer rate memory 19. As a consequence, a conversion characteristic most suitable for calculating the target transfer rate is selected. Further, information representing the selected conversion characteristic is outputted. Such a serial processing is described in, for example, the Japanese Unexamined Patent Publication (Tokkyo Kokai Koho) Official Gazette No. H2-417572.

Next, the coding means for performing an actual coding (namely, a real coding) will be described in detail hereinbelow. This coding means is used to perform a coding by controlling an amount of codes in accordance with the target transfer rate corresponding to a unit period of time.

In case of the apparatus of FIG. 4, the same image signal as used in the temporary coding is outputted from the VTR 1. Then, a coding similar to the temporary coding is performed. Basically, manners of operation is of the prediction subtracter 2, the DCT device 3, the activity 4, the quantization controller 5, the quantizer 6, the variable length coder 7, the inter-image predictor 13, the adder 14 and the local decoder 15 are similar to those of the operation of the corresponding elements in case of performing the temporary coding. However, the contents of the operation of these elements in case of performing the real coding are different from those of the operations of these elements in case of performing the temporary coding.

When performing the real coding, an output of the variable length coder 7 is applied to the buffer 10 through the selector 9. Further, variation in amount of generated codes, which variation is of a short period, is absorbed by the buffer 10. Codes are outputted from the buffer 10 through the code output terminal 11 to the decoder.

Furthermore, a reading rate for reading a code from the buffer 10 is controlled by a value supplied from the target transfer rate setting device 18 every unit period time. Thus, the amount of codes outputted from the buffer 10 changes each unit period of time. In the target transfer rate setting device 18, the temporary transfer rate inputted from the temporary transfer rate memory 19 every unit period of time is converted according to the conversion characteristics inputted from the code amount controller 17 and thus the target transfer rate is established.

On the other hand, information representing the occupancy of the buffer 10 is inputted to the quantization controller 5 through the selector 8.

Further, the quantization step width is controlled by the quantization controller 5 according to the activity and the filling rate of the buffer. In case of such control, differently from the conventional apparatus, variation in amount of generated codes, which variation is of a long period, is absorbed by utilizing a variable transfer rate every unit period of time. Thus only local variation thereof is absorbed. Consequently, the possibility of an occurrence of an overflow becomes low.

Incidentally, in case where there is no need of utilizing a fixed transfer rate for an output of the buffer, the buffer is treated as a virtual one and thus an output of the variable length coder 7 is directly outputted.

Next, it will be described hereinbelow by referring to FIGS. 7(A) and 7(B) how data streams coding by the coding apparatus are recorded by the apparatus of the present invention and the conventional apparatus.

FIGS. 7(A) and 7(B) are diagrams for illustrating the data streams (or code sequences) recorded on the recording medium.

In these figures, numerals designate numbers of unit periods of time. Practically, there are unit periods, the number of which is far larger than the number of unit periods illustrated in these figures. In case of the conventional apparatus, when the data stream is recorded on the recording medium, the amount of data of a portion of the data stream corresponding to a unit period is constant as illustrated in FIG. 7(A). As the result, an open space is generated in the recording medium. In contrast, in case of the embodiment of the present invention, the amount of codes of the data stream changes every unit period of time as illustrated in FIG. 7(B). Moreover, no space occurs in the recording medium because the total amount of codes is controlled.

Next, a variable transfer rate decoding apparatus of the present invention will be described hereinbelow by referring to FIG. 8.

FIG. 8 is a schematic block diagram for illustrating the configuration of the variable transfer rate decoding apparatus of the present invention for decoding codes generated by the variable transfer rate control coding apparatus of FIG. 4.

In this figure, like reference characters designate like or corresponding elements (namely, elements having the same functions) of the conventional apparatus of FIG. 3. The decoding apparatus of FIG. 8 is different from the conventional decoding apparatus of FIG. 3 in that the transfer rate is inputted to the buffer 21.

The codes inputted from the code input terminal 20 are outputted from the buffer 21 to the variable length decoder 22 in synchronization with the operation performed in the device 22. Further, a speed of writing the transfer ratio to the buffer 21 is controlled according to rate information inputted from the transfer rate input terminal 27 every unit period of time in such a manner to be adapted to the transfer rate of the inputted code.

Turning to FIG. 9, there is shown a schematic block diagram for illustrating the configuration of a first example of a variable transfer rate information reproducing apparatus embodying the present invention.

In case of the apparatus of this figure, information coded at a variable transfer rate changing every predetermined period of time and recorded on the recording medium is read intermittently by an information reading means 94 from the recording medium and subsequently is inputted to buffer means 95A having a decoding buffer for decoding. Further, information outputted intermittently from information reading means 94 is [Moreover,] written to the buffer means 95A. Moreover, the information is outputted therefrom to a demultiplexer 96 when the information is necessary for decoding.

In the demultiplexer 96, audio information and image information are separated. Then, the audio information and the image information are inputted to an audio detector 92 and an image decoder 97, respectively. Further, the audio information and the image information are decoded by the audio decoder 92 and the image decoder 97, respectively. Moreover, a reproduced audio and a reproduced image are outputted from a reproduction audio output terminal 93 and a reproduced image output terminal 98.

On the other hand, information representing the occupancy of the buffer, which information is outputted from the buffer means 95A, is fed to a reading operation controller 99. At that time, the buffer means 95A becomes almost empty when an amount of written information is small in comparison with an amount of information required for decoding. Further, the buffer means 95A becomes nearly full of information when an amount of information written thereto is larger than an amount of information used for decoding.

Then, reading operation control information is outputted from the reading operation controller 99 to the information reading means 94 according to the state of the buffer means 95A. Namely, when the buffer of the buffer means 95A is nearly empty, reading operation control information is outputted to initiate a reading operation or to continue to performed a reading operation. Further, when the buffer is nearly full of information, the reading operation control information is outputted to control the information reading means to cease a reading operation and stand by.

Next, a method for controlling the information reading means 94 will be described concretely hereinbelow.

A reading of information by the information reading means 94 from the recording medium is performed by using, for example, a period of one revolution of a disk as a unit period of time.

Further, even in case where information is not read by the information reading means 94 from the recording medium at present time and on the other hand, information is read from the buffer means at the maximum rate for decoding, a reading operation of the information reading means 94 is controlled is such a way that the buffer of the buffer means does not become empty until the next reading operation is started.

For example, in case where an amount of codes read from the recording medium during a period of the predetermined length (hereunder sometimes referred to as a reading rate) is equal to a maximum amount of codes required for decoding during a period of the predetermined length (hereunder sometimes referred to as a decoding rate), the buffer of the buffer means 95A needs capacity which is a little larger than an amount of information read two times. Further, the information reading means 94 is controlled in such a manner that if a recording area, on which information left in the buffer is recorded, is less than half of the recordable area of the buffer, the reading operation is kept performed and that if the recording area, on which information left in the buffer is recorded, is equal to or greater than half of the recordable area of the buffer, the reading operation is ceased and the information reading means stands by.

A more practical manner of such control is illustrated in FIG. 10.

FIG. 10 is a graph for illustrating a manner of such reading control and illustrates the relation among the decoding rate, the reading rate and the occupancy of the buffer.

As illustrated in this figure, the decoding rate varies every predetermined period Td. Further, information is read from the recording medium intermittently at a predetermined reading rate. It is controlled every predetermined period Tr whether or not a reading of information is performed.

In a period between the moments t13 and t14, the decoding rate has a maximum value Rmax. Further, the value of the reading rate is Rmax. Thus, during this period, the occupancy of the buffer does not change.

In contrast, in a period between the moments t1 and t2, the reading rate is greater than the decoding rate. Thus, during this period, the occupancy of the buffer increases. At a moment t2 at which a period of time Tr has passed since a reading operation is commenced at the moment t1, the occupancy of the buffer is larger than a level indicated by the dashed central line K (namely, half of the capacity of the buffer). Thus, the reading operation is stopped. After the moment t2, the occupancy of the buffer decreases and becomes equal to the level indicted by the central line K at a moment t3.

At a moment t4 when a period 2Tr has passed since the moment t2 at which the reading operation is ceased at the precedent time, the occupancy of the buffer is less than ½. Thus, the reading operation is resumed.

In case of this example, the moment when the decoding rate changes is synchronized with the moment at which the reading operation is commenced or ceased as illustrated in this figure. However, it is not necessary to synchronize former moment with the latter moment.

Further, the information reading means 94 of FIG. 9 performs an information reading operation in accordance with the reading operation control information sent from the reading operation controller 99. However, is practical method for controlling the information reading means to keep reading information from the recording medium or to cease reading such information and stand by varies with the kind of the recording medium employed.

In case of employing a disk medium, the practical method for controlling the reading operation varies with the manner of controlling a tracking of a reproducing head. For example, in case of employing what is called a disk of the spiral type in which information track is continuous, a usual reading operation is continuously performed when an information reading operation is kept performed. In contrast, when the information reading operation should be stopped and the apparatus should stand by, the reproducing head is skipped to the precedent track and a tracing is repeatedly performed on the track corresponding to an already read part of information. Thus the apparatus falls into a stand-by state.

In contrast with this, in case of employing what is called a disk of the concentric circle type in which information track is closed like a circle, the apparatus falls into a stand-by state by repeatedly performing a tracing on the track corresponding to am already read part of information. Then, the reproducing head is skipped to the subsequent track to read information recorded on the next track.

Meanwhile, in case of a VTR having what is called a rotary drum, information tracks are distributed discontinuously on tape. Thus, after information is once read from the track, the tape or reproducing head is moved. Further, a tracing is repeatedly performed on the portion which has been already read. Thus the apparatus is put into a stand-by state. Moreover, the reproducing head or the tape is shifted in such a manner that the reproducing head is set on the subsequent track. Thus information recorded on the next track is read.

Information recorded on the recording medium at a variable transfer rate can be realized by controlling the information reading means to keep reading information or stand by without changing the number of revolutions of the disk or drum, namely, without changing the relative speed between the reproducing head and the recording medium as described above.

Further, in the stand-by state, the reproducing head may repeatedly read information recorded on the same track and outputs the read information. Further, unnecessary information may be discarded later. In this case, information is read in a narrow sense. However, substantially, information to be read is not read. In the following description, the expression "does not read and stands by" means "does not read substantially and stands by", precisely speaking.

FIGS. 11(a), 11(b) and 11(c) are diagrams for showing examples of recording formats employed by a variable transfer rate information recording medium according to the present invention.

The formats of FIGS. 11(a), 11(b) and 11(c) are the recording formats to be used for recording information on the variable transfer rate information recording medium of the present invention (incidentally, the recording formats to be used for the recording medium of the compact disk read-only memory (CD-ROM) type are shown in these figures).

In these cases, the recording area of the recording medium is partitioned into sectors having a predetermined number of bytes as illustrated in FIG. 11(a). Each sector consists of a sector header area, on which management information concerning synchronization signals and sector addresses is recorded, and a data area, on which image information and audio information are recorded.

In case that data (or information) recorded on the data area of FIG. 11(a) are read from the recording medium in succession. The read data are an audio header, audio data, image header and image data which are recorded in this order as illustrated in FIG. 11(b). Further, as illustrated in FIG. 11(c), a synchronization code is recorded on a leading address of each of the headers.

FIG. 12 is a schematic block diagram for illustrating the configuration of a second example of a variable transfer rate information reproducing apparatus according to the present invention.

In this figure, same reference characters designate same or corresponding elements (namely, elements having the same functions) of the apparatus of FIG. 9. For simplicity of description, the explanation of these elements is omitted herein.

Differently from the apparatus of FIG. 9, the apparatus of FIG. 12 does not have the reading controller 9 but is provided with control information separation device 121. In case of the example, reading operation control information used for controlling information reading means is preliminarily set in an encoder (namely, the coding apparatus). Further, the reading operation control information is preliminarily recorded on the recording medium in a multiplex recording manner.

In case of the apparatus of FIG. 12, information read from the recording medium by information reading means 94 is inputted to buffer means 95 and control information separation device 121.

Operations of the demultiplexer 96, the audio decoder 92 and the image decoder 97, which follow the buffer means 95, are similar to those of the same elements of the first example of FIG. 9. Thus reproduced audio and image, which are decoded, are outputted from the reproduced audio output terminal 93 and the reproduced image output terminal 98, respectively.

On the other hand, the control information separation device 121 detects the synchronization code from an output of the information reading means 94 and separates the reading operation control information. The separated information is inputted to the information reading means 94 therefrom. In the information reading means 94, it is determined according to the reading operation control information whether the means 94 keeps reading information from the recording medium or stands by.

In this way, the reading operation control information is recorded on the recording medium in a multiplex recording manner. When reproducing the recorded information, the information reading means 94 is controlled according to the reading operation control information. This is rational and results in that the processing can be easily performed in the decoder or decoding apparatus. However, the delay time or the like of the control processing effected in the information reading means should be definite.

Incidentally, the control information is recorded in the sector header or the audio and image headers of the recording medium. Incidentally, in the recording medium, a control header and a control information area may be provided for recording the control information.

FIG. 13 is a diagram for showing an example of the recording format employed by the recording medium used by the reproducing apparatus of FIG. 12.

FIG. 14 is a schematic block diagram for illustrating the configuration of a third example of the variable transfer rate information reproducing apparatus according to the present invention.

In this figure, same reference characters designate same or corresponding composing elements (namely, elements having the same functions) of the apparatus of FIG. 9. For simplicity of description, the explanation of these composing elements is omitted herein.

The apparatus of FIG. 14 is different from the apparatus of FIG. 9 in that the former apparatus is provided with a transfer rate separation device 131.

Information read from the recording medium and outputted by the information reading means 94 is inputted to the buffer means 95 and control information separation device 131. Operations of the composing elements following the buffer means 95 are similar to those of the same or corresponding elements of the second example of FIG. 12.

FIGS. 15(a) and 15(b) are diagrams each for showing an example of the recording format employed by the recording medium used by the reproducing apparatus of FIG. 14.

In case of the apparatus of FIG. 14, an information signal of the format of FIG. 15(a) is outputted from the information reading means 94. Further, in the transfer rate separation device 131, the synchronization code corresponding to code amount information is detected from the audio header and the image header. Then, amounts of codes B1 and B2 corresponding to a period of the predetermined length, which are recorded in these headers, respectively, are separated. Thus, the decoding rate (namely, the transfer rate) corresponding to the period of the predetermined length is calculated, and the calculated decoding rate is inputted to the reading operation controller 99.

As is seen from FIG. 15(a), the code amount information represents an amount of codes (namely, decoding rate (or transfer rate)) required for decoding of the recorded information following this code amount information and corresponding to the period of the predetermined length the audio code amount B1 and the image code amount B2 required for performing a decoding every 100 milli-seconds (ms) (corresponding to 3 frames in case of an NTSC (National Television System Committee) television are recorded on both of the headers.

Further, the code amount of information may be recorded by using the format of FIG. 15(b). Namely, an audio header, audio data, an image header and image data are recorded as a packet of information. Further, a total value B1 of an audio code amount and an image code amount to be decoded in a period, of, for instance, 100 ms is recorded in a packet header.

In case of the apparatus of FIG. 14, the information reading means 94 is controlled by the reading operation controller 99. Thus the code amount to the read by the information reading means 94 is preliminary known. On the other hand, information representing an amount of codes needed for performing a decoding is supplied from the transfer rate information separation device 131.

Thus, the future occupancy of the buffer means 95 can be predicted by the reading operation controller 99 from an output of the reading operation controller 99 and an output of the transfer rate information separation device 131. A control signal is supplied to the information reading means 94 to prevent occurrences of an overflow and an underflow in the buffer means 95.

Namely, let Tr denote a unit period of time for performing a reading operation by the information reading means 94 (see FIG. 10). The predicted occupancy of the buffer means 95 at a moment when the period Tr has passed since the present moment is calculated corresponding to each of the cases that the reading operation is performed and that the reading operation is not performed. The reading means 94 is controlled in such a manner that the predicted occupancy is in the vicinity of the central line K of FIG. 10.

As can be seen from a comparison between the first example of FIG. 9 and this example, in case of this example, the information reading means 94 can be controlled faster and the necessary capacity of the buffer can be reduced because an amount of codes read from the buffer is known preliminarily.

Moreover, as can be seen from a comparison between the second example of FIG. 10 and this example, in case of this example, the processing to be performed in the decoder becomes somewhat complex but the information reading means 94 can be controlled in such a manner to be fit for the throughput thereof.

FIG. 16 is a schematic block diagram for illustrating the configuration of a fourth example of a variable transfer rate information reproducing apparatus according to the present invention.

In this figure, same reference characters designate same or corresponding composing elements (namely, elements having the same functions) of the apparatus of FIG. 9. For simplicity of description, the explanation of these composing elements is omitted herein.

The example of FIG. 16 is different from the third example of FIG. 14 in that the former example is provided with a packet code amount detector 141 instead of the transfer rate separation device 131. Operations of the composing elements other than the packet code amount detector 141 are similar to those of the same or corresponding elements of the third example of FIG. 14.

In the packet code amount detector 141, a synchronization signal corresponding to a packet is detected from an output of the information reading means 94 and further an amount of codes of this packet is measured until a synchronization signal corresponding to the next packet is detected. In this way, an amount of codes of one packet is obtained and is inputted to the reading operation controller 99. The format of this packet is similar to that of, for instance, FIG. 15(b). However, it is not necessary to record the amount of information of a packet in the packet header.

Further, such a packet is established each period of the predetermined length (for example, 100 ms) required for a decoding. Thus an amount of codes of one packet is variable.

In case of the example of FIG. 16, the information reading means 94 is controlled by the reading operation controller 99. Thus the code amount to be read by the information reading means 94 is preliminarily known. On the other hand, information representing an amount of codes needed for performing a decoding is supplied from the packet code amount detector 141.

Thus, the reading operation controller 99 is controlled according to an output of the reading operation controller 99 and an output of the packet code amount detector 141, similarly as in case of the third example of FIG. 14.

As described above, in case of the third example, an amount of information to be read is preliminarily known before a reading operation is performed. In contrast, in case of the fourth example, the result of the measurement effected by the packet code amount decoder 141 represents an amount of codes concerning information already read. Thereby, the response to the control is a little slower than that in case of the third example. However, an amount of codes required for decoding is known in a stage precedent to the buffer means 95. Therefore, the response is faster than that in case of the first example in which the information reading means is controlled according to the occupancy of the buffer.

FIG. 17 is a schematic block diagram for illustrating the configuration of the fifth example of the variable transfer rate information reproducing apparatus according to the present invention.

In this figure, same reference characters designate same or corresponding composing elements (namely, elements having the same functions) of the apparatus of FIG. 16. For simplicity of description, the explanation of these composing elements is omitted herein.

The example of FIG. 17 is different from that of FIG. 16 in that the former example is provided with a fixed-rate detector 151, that the buffer means are connected to the rear of the demultiplexer 96 and that audio buffer means 152 and image buffer means 153 are separately provided as the buffer means. Incidentally, operations of the composing elements of the example of FIG. 17 other than the reading operation controller 99, the fixed-rate detector 151 and the buffer means 152 and 153 are similar to those of the same or corresponding elements of the fourth example.

In case of the fifth example, an audio is recorded on the recording medium by using a fixed transfer rate as illustrated in FIG. 18. Further, a reading operation is controlled in such a manner that a transfer rate of the audio information becomes constant, as will be described later.

Information read by the information reading means 94 is immediately separated by the demultiplexer 96 into audio information and image information. Then, the audio information and the image information are inputted to the audio decoder 92 and the image decoder 97 through the buffer means 152 and 153, respectively.

Furthermore, audio information outputted from the demultiplexer 96 is also inputted to the fixed rate detector 151. In the fixed rate detector 151, an amount of codes generated in a period of the predetermined length, which are generated from audio information outputted by the demultiplexer 96 is measured. Thereafter, information representing the amount of the codes generated from the audio information is outputted to the reading operation controller 99. The amount of the codes generated by the audio information can be known by recording audio data composed of a set of audio information corresponding to each unit period of, for instance, 100 ms.

Further, the information reading means 94 is controlled according to the reading operation control information sent from the reading operation controller 99 in such a way to read information from the recording medium or to stop a reading operation.

In the reading operation controller 99, it is judged from the audio code amount information corresponding to the period of the predetermined length, which is inputted from the fixed rate detector 151, whether a value indicated by the audio code amount information is less than or more than a predetermined audio average transfer rate (namely, a predetermined average decoding rate). If less than, a reading operation is kept performed. In contrast, if more than, reading operation control information, which indicates that a reading operation is inhibited and that the information reading means is caused to stand by, is outputted to the information reading means 94. Thus information can be read in synchronization with a decoding of audio information.

In this case, image information does not affect the control of the information reading means 49. As long as the image information is recorded in such a manner that there is only a small difference between a moment at which the image information is recorded and another moment at which the corresponding audio information is recorded, information sufficient for a decoding can be obtained. Thus, there is not an occurrence of an overflow in the buffer means 153.

Regarding the speed of the response of the information reading means 94 to the control information, it is the same with the fourth example. However, it is unnecessary to record image information every period of the predetermined length as a packet of information. The control operation can be easily performed.

Incidentally, audio information is employed as an example of the fixed rate information. However, other kinds of information recorded by utilizing a fixed transfer rate may be employed instead of audio information.

While the preferred embodiments of the present invention have been described above, it is to be understood that the present invention is not limited thereto and that other modifications will be apparent to those skilled in the art without departing from the spirit of the invention. The scope of the present invention, therefore, is to be determined solely by the appended claims.

Claims

1. A variable transfer rate coding apparatus for coding a plurality of moving picture signals in a total data stream, comprising:

temporary coding means for quantizing each of the moving picture signals in the total data stream according to a temporary quantization step width which is determined according to each of activities of the moving picture signals to produce a plurality of temporary quantized signals, changing the temporary quantized signals to a plurality of temporary variable length codes according to a variable length coding and calculating a temporary transfer rate indicating an amount of temporary variable length codes in one prescribed time period for each of prescribed time periods, the plurality of temporary transfer rates being variable with time;

target transfer rate setting means for preparing a plurality of transfer rate conversion characteristics respectively indicating the conversion of each temporary transfer rate calculated by the temporary coding means to a target transfer rate indicating an amount of target codes in one prescribed time period, selecting a particular transfer rate conversion characteristic from the plurality of transfer rate conversion characteristics to provide a prescribed value for a total amount of target codes which are determined by a plurality of target transfer rates obtained by converting the temporary transfer rates corresponding to the moving picture signals in the total data stream according to the particular transfer rate conversion characteristic, and calculating one target transfer rate from each of the temporary transfer rates according to the particular transfer rate conversion characteristic, the plurality of target transfer rates being variable with time, and each target transfer rate corresponding to one prescribed time period;

storing buffer means for temporarily storing codes, outputting the codes at one corresponding target transfer rate for each prescribed time period, the target transfer rates for the prescribed time periods being variable with time, and outputting a buffer filling rate indicating a filling rate occupancy information representing an occupancy degree of the codes in the storing buffer means; and

real coding means for quantizing each of the moving picture signals in the total stream according to a real quantization step width which is determined according to each of the activities of the moving picture signals and the buffer filling rate occupancy information output from the storing buffer means to produce a plurality of real quantized signals so that a volume of variable length codes obtained from each of the real quantized signals according to the variable length coding is increased or decreased with the decrease or increase of the buffer filling rate occupancy information and so that a total sum of variable length codes obtained from the real quantized signals becomes the prescribed value, changing the real quantized signals to a plurality of real variable length codes having a total volume which is equal to the prescribed value according to the variable length coding, and outputting the real variable length codes to the storing buffer means one after another to output the real variable length codes from the storing buffer means at one corresponding target transfer rate for each prescribed time period, the target transfer rates for the prescribed time periods are variable with time.

2. A variable transfer rate coding apparatus according to claim 1 in which the target transfer rate setting means comprises:

a code amount controller for selecting the particular transfer rate conversion characteristics; and

a target transfer rate setting device for setting the target transfer rate for each prescribed time period by converting each of the temporary transfer rates into one target transfer rate according to the particular transfer rate conversion characteristic selected by the code amount controller so that increase of the target transfer rates is less than increase of the temporary transfer rates and so that a maximum value of each of the target transfer rates is lower than a constant value.

3. A variable transfer rate coding apparatus according to claim 2 in which the code amount controller comprises:

a plurality of transfer rate converting devices for respectively converting one temporary transfer rate into a converted transfer rate according to one of the transfer rate conversion characteristic for each prescribed time period;

a plurality of accumulation adders for respectively accumulating a plurality of converted transfer rates obtained from all the temporary transfer rates in each of the transfer rate converting devices and respectively generating a total amount of codes from the converted transfer rates; and

a judgement device for selecting one total amount of codes having a maximum value from the total amounts generated in the accumulation adders, the selected one total amount of codes being lower than a target total code amount, and selecting one transfer rate conversion characteristic relating to the selected one total amount of codes as the particular transfer rate conversion characteristic.

4. A variable transfer rate coding apparatus according to claim 3, in which the target total code amount in the judgement device denotes a recording capacity of a recording medium.

5. A variable transfer rate coding apparatus according to claim 1 in which the temporary coding means comprises:

a quantizer for quantizing each of the moving picture signals in the total data stream according to the temporary quantization step width for each prescribed time period;

a variable length coder for calculating the temporary variable length codes from the temporary quantized signals obtained by the quantizer according to the variable length coding; and

a temporary code amount counter for calculating the temporary transfer rate from the amount of the temporary variable length codes for each prescribed time period.

6. A variable transfer rate coding apparatus according to claim 1 in which the real coding means comprises:

a quantizer for quantizing each of the moving picture signals in the total data stream according to the real quantization step width for each prescribed time period;

a variable length coder for calculating the real variable length codes for each of the real quantized signals obtained by the quantizer according to the variable length coding; and

a quantization controller for adjusting the real quantization step width according to the buffer filling rate occupancy information output from the storing buffer means to control the quantization performed by the quantizer.

7. A variable transfer rate information reproducing apparatus for reproducing pieces of moving picture information recorded on a recording medium, comprising:

information reading means for intermittently reading the pieces of moving picture information from the recording medium at a constant information reading rate, the pieces of moving picture information being recorded coded at a variable transfer rate changing every prescribed time period being recorded;

buffer means for temporarily storing the pieces of moving picture information read by the information reading means and outputting the pieces of moving picture information at an information decoding rate;

reading operation controlling means for detecting an occupancy information filling rate representing an occupancy degree of the buffer means and controlling a reading operation performed by the information reading means according to the occupancy information filling rate to prevent an overflow of the pieces of moving picture information stored in the buffer means and an information empty condition of the buffer means; and

decoding means for decoding the pieces of moving picture information output from the buffer means to obtain pieces of reproduced moving picture information.

8. A variable transfer rate information reproducing apparatus according to claim 7 in which the information decoding rate is equal to or lower than the constant information reading rate, the reading operation performed by the information reading means is stopped under the control of the reading operation controlling means in cases where the occupancy information filling rate is higher than a prescribed upper limit, and the reading operation stopped by the reading operation controlling means is restarted under the control of the reading operation controlling means in cases where the occupancy information filling rate is lower than a prescribed lower limit.

9. A variable transfer rate information reproducing apparatus according to claim 7 in which the information decoding rate is changeable.

10. A variable transfer rate information reproducing apparatus according to claim 7 in which the reading operation performed by the information reading means is continued under the control of the reading operation controlling means to read the pieces of moving picture information stored in the buffer means in duplicate as pieces of unnecessary information and discard the unnecessary information in cases where the information filling rate is higher than a prescribed upper limit.

11. A variable transfer rate information reproducing apparatus according to claim 7 in which the decoding means comprises:

a demultiplexer for demultiplexing each of the pieces of moving picture information to a piece of audio information and a piece of image information;

an audio decoder for decoding the pieces of audio information obtained by the demultiplexer to obtain a piece of reproduced audio information; and

an image decoder for decoding the pieces of image information obtained by the demultiplexer to obtain a piece of reproduced image information.

12. A variable transfer rate information reproducing apparatus for reproducing pieces of moving picture information recorded on a recording medium, comprising:

information reading means for intermittently reading at a constant information reading rate the pieces of moving picture information and a piece of reading operation control information from the recording medium, in which the pieces of moving picture information are recorded coded at a variable transfer rate changing every prescribed time period are recorded;

buffer means for temporarily storing the pieces of moving picture information read by the information reading means and outputting the pieces of moving picture information at an information decoding rate;

control information separating means for separating the reading operation control information from the pieces of moving picture information read by the information reading means and controlling a reading operation performed by the information reading means according to the reading operation control information to prevent an overflow of the pieces of moving picture information stored in the buffer means and an information empty condition of the buffer means; and

decoding means for decoding the pieces of moving picture information output from the buffer means to obtain pieces of reproduced moving picture information.

13. A variable transfer rate information reproducing apparatus according to claim 12 in which the information decoding rate is equal to or lower than the constant information reading rate, and the reading operation performed by the information reading means is stopped or restarted according to the reading operation control information to maintain an occupancy information filling rate representing an occupancy degree of the buffer means within an allowable range.

14. A variable transfer rate information reproducing apparatus according to claim 12 in which the decoding means comprises:

a demultiplexer for demultiplexing each of the pieces of moving picture information to a piece of audio information and a piece of image information;

an audio decoder for decoding the pieces of audio information obtained by the demultiplexer to obtain a piece of reproduced audio information; and

an image decoder for decoding the pieces of image information obtained by the demultiplexer to obtain a piece of reproduced image information.

15. A variable transfer rate information reproducing apparatus for reproducing pieces of moving picture of information recorded on a recording medium, comprising:

information reading means for intermittently reading the pieces of moving picture information and a piece of transfer rate information from the recording medium at a constant information reading rate for each prescribed time period, in which the pieces of moving picture information are recorded coded at a variable transfer rate changing every prescribed time period, are recorded, the transfer rate information indicating the variable transfer rate;

transfer rate information separating means for separating the transfer rate information from the pieces of moving picture information read by the information reading means;

buffer means for temporarily storing the pieces of moving picture information read by the information reading means and outputting the pieces of moving picture information at an information decoding rate;

reading operation controlling means for controlling a reading operation performed by the information reading means according to the transfer rate information obtained by the transfer rate information separating means to prevent an overflow of the pieces of moving picture information stored in the buffer means and to prevent an information empty condition of the buffer means; and

decoding means for decoding the pieces of moving picture information output from the buffer means to obtain pieces of reproduced moving picture information.

16. A variable transfer rate information reproducing apparatus according to claim 15 in which the information decoding rate is equal to or lower than the constant information reading rate, and the reading operation performed by the information reading means is stopped or restarted under the control of the reading operation controlling means to maintain an occupancy information filling rate representing an occupancy degree of the buffer means within an allowable range.

17. A variable transfer rate information reproducing apparatus according to claim 15 in which the decoding means comprises:

a demultiplexer for demultiplexing each of the pieces of moving picture information to a piece of audio information and a piece of image information;

an audio decoder for decoding the pieces of audio information obtained by the demultiplexer to obtain a piece of reproduced audio information; and

an image decoder for decoding the pieces of image information obtained by the demultiplexer to obtain a piece of reproduced image information.

18. A variable transfer rate information reproducing apparatus for reproducing pieces of moving picture information recorder in a packet on a recording medium for each prescribed time period comprising:

information reading means for intermittently reading the pieces of moving picture information and code amount of the pieces of the moving picture information in one packet from the recording medium at a constant information reading rates for each prescribe time period, in which the pieces of moving picture information are recorded with a changeable amount of code indicating the pieces of the moving picture information in one packet;

packet code amount detecting means for detecting the code amount of the pieces of moving pictures information in one packet read by the information reading means for each prescribed time period;

buffer means for temporarily storing the pieces moving picture information in one packet read by the information reading means for each prescribed time period and outputting the pieces of moving picture information at an information decoding rate;

reading operation controlling means for controlling a reading operation performed by the information reading means according to the code amount obtained by the packet code amount detecting means to prevent an overflow of the pieces of moving picture information stored in the buffer means and an information empty condition of the buffer means; and

decoding means for decoding the pieces of moving picture information output from the buffer means to obtain pieces of reproduced moving picture information.

19. A variable transfer rate information reproducing apparatus according to claim 18 in which the information decoding rate is equal to or lower than the constant information reading rate, and the reading operation performed by the information reading means is stopped or restarted under the control of the reading operation controlling means to maintain an occupancy information filling rate representing an occupancy degree of the buffer means within an allowable range.

20. A variable transfer rate information reproducing apparatus according to claim 18 in which the decoding means comprises:

a demultiplexer for demultiplexing each of the pieces of moving picture information to a piece of audio information and a piece of image information;

an audio decoder for decoding the pieces of audio information obtained by the demultiplexer to obtain a piece of reproduced audio information; and

an image decoder for decoding the pieces of image information obtained by the demultiplexer to obtain a piece of reproduced image information.

21. A variable transfer rate information reproducing apparatus for reproducing pieces of moving picture information recorded on a recording medium, comprising:

information reading means for intermittently reading at a constant information reading rate the pieces of moving picture information from the recording medium, the pieces of moving picture information being classified into pieces of first information coded at a fixed transfer rate and recorded on the recording medium at a fixed transfer rate and pieces of second information coded at a variable transfer rate changing every prescribed time period and recorded on the recording medium at a variable transfer rate changing every prescribed time period, at a constant information reading rate;

demultiplexing means for demultiplexing the pieces of moving picture information read by the information reading means to the pieces of first information and the pieces of second information;

first buffer means for temporarily storing the pieces of first information demultiplexed by the demultiplexing means and outputting the pieces of first information at an information decoding rate;

second buffer means for temporarily storing the pieces of second information demultiplexed by the demultiplexing means and outputting the pieces of second information at the information decoding rate;

fixed transfer rate detecting means for detecting the fixed transfer rate from the pieces of first information;

reading operation controlling means for controlling a reading operation performed by the information reading means according to the fixed transfer rate detected by the fixed transfer rate detecting means to prevent an overflow of the pieces of first information stored in the first buffer means and to prevent an information empty condition of the first buffer means;

first decoding means for decoding the pieces of first information output from the first buffer means to obtain pieces of reproduced first information; and

second decoding means for decoding the pieces of second information output from the second buffer means to obtain pieces of reproduced second information, pieces of reproduced moving picture information being composed of the pieces of reproduced first information obtained by the first decoding means and the pieces of second information.

22. A variable transfer rate information reproducing apparatus according to claim 21 in which the information decoding rate is equal to or lower than the constant information reading rate, and the reading operation performed by the information reading means is stopped or restarted under the control of the reading operation controlling means to maintain an occupancy information filling rate representing an occupancy degree of the first buffer means within an allowable range.

23. A recording medium on which codes are recorded, comprising:

a recording region having a prescribed storing capacity value; and

information of a plurality of moving picture signals in a total data stream being stored in the recording medium so that a sum of a plurality of real variable length codes indicating the moving picture signals in the total data stream is equal to the prescribed storing capacity value, wherein each of the moving picture signals in the total data stream is quantized according to a temporary quantization step width which is determined according to each of activities of the moving picture signals to produce a plurality of temporary quantized signals which are changed to a plurality of temporary variable length codes, a temporary transfer rate indicating an amount of temporary variable length codes in one prescribed time period being calculated for each of prescribed time periods, a plurality of target transfer conversion characteristics respectively indicating the conversion of each of the temporary transfer rates to a target transfer rate indicating an amount of target codes in one prescribed time period are prepared, a particular target transfer conversion characteristic being selected from the plurality of target transfer conversion characteristics on condition that a total amount of target codes which are determined by a plurality of target transfer rates obtained by converting the temporary transfer rates corresponding to the moving picture signals in the total data stream according to the particular target transfer conversion characteristic is the prescribed storing capacity value of the recording region, one target transfer rate being calculated from each of the temporary transfer rates according to the particular target transfer conversion characteristic on condition that the plurality of target transfer rates for the prescribed time periods are variable with time, a buffer in which codes are temporarily stored, the codes are output at one corresponding target transfer rate for each prescribed time period on condition that the target transfer rates for the prescribed time periods are variable with time and that a buffer filling rate indicating a filling rate of the codes in the buffer is output is prepared, each of the moving picture signals in the total data stream being quantized according to a real quantization step width which is determined according to each of the activities of the moving picture signals and the buffer filling rate output from the buffer to produce a plurality of real quantized signals on condition that a volume of variable length codes obtained from each of the real quantized signals is increased or decreased with the decrease or increase of the buffer filling rate and that a total sum of variable length codes obtained from the real quantized signals becomes the prescribed storing capacity value of the recording region, the real quantized signals being changed to the plurality of real variable length codes of which a total volume is equal to the prescribed storing capacity value of the recording region, the real variable length codes being temporarily stored in the buffer one after another, and the real variable length codes stored in the buffer are recorded in the recording region of the recording medium at one corresponding target transfer rate for each prescribed time period on condition that the plurality of target transfer rates for the prescribed time periods are variable with time.

24. A recording medium according to claim 23, further comprising:

reading operation control information stored in the recording medium, wherein the information of the moving picture signals in the total stream and the reading operation control information are intermittently read from the recording region of the recording medium at a constant information reading rate, the reading operation control information is separated from the information of the moving picture signals, the information of the moving picture signals is temporarily stored in a buffer unit and is output at an information decoding rate, a reading operation is controlled according to the reading operation control information to prevent an overflow of the information of the moving picture signals stored in the buffer unit and an information empty condition of the buffer unit, and the information of the moving picture signals output from the buffer unit is decoded to obtain pieces of reproduced moving picture information.

25. A variable transfer rate coding apparatus for coding a plurality of moving picture signals in a total data stream, comprising:

temporary coding means for quantizing each of the moving picture signals in the total data stream according to a temporary quantization step width which is determined according to each of activities of the moving picture signals to produce a plurality of temporary quantized signals, changing the temporary quantized signals to a plurality of temporary variable length codes according to a variable length coding and calculating a temporary transfer rate indicating an amount of temporary variable length codes in one prescribed time period for each of prescribed time periods, the plurality of temporary transfer rates being variable with time;

target transfer rate setting means for setting a target transfer rate from each of the temporary transfer rates calculated by the temporary coding means so that a maximum value of each of the target transfer rates is lower than a prescribed constant value, and so as to provide a prescribed value for a total amount of target codes which are determined by a plurality of the target transfer rates corresponding to the moving picture signals in the total data stream, the plurality of target transfer rates being variable with time, and each target transfer rate corresponding to one prescribed time period;

buffer means for temporarily storing codes, outputting the codes at one corresponding target transfer rate for each prescribed time period, the target transfer rates for the prescribed time periods being variable with time, and outputting occupancy information representing an occupancy degree of the codes in the buffer means; and

real coding means for quantizing each of the moving picture signals in the total stream according to a real quantization step width which is determined according to each of the activities of the moving picture signals and the occupancy information output from the buffer means to produce a plurality of real quantized signals so that a volume of variable length codes obtained from each of the real quantized signals according to the variable length coding is increased or decreased with the decrease or increase of the occupancy information and so that a total sum of variable length codes obtained from the real quantized signals becomes the prescribed value, changing the real quantized signals to a plurality of real variable length codes having a total volume which is equal to the prescribed value according to the variable length coding, and outputting the real variable length codes to the buffer means one after another to output the real variable length codes from the buffer means at the one corresponding target transfer rate for each prescribed time period, the target transfer rates for the prescribed time periods being variable with time.

26. A variable transfer rate coding method for coding a plurality of moving picture signals in a total data stream, comprising:

a temporary coding step of quantizing each of the moving picture signals in the total data stream according to a temporary quantization step width which is determined according to each of activities of the moving picture signals to produce a plurality of temporary quantized signals, changing the temporary quantized signals to a plurality of temporary variable length codes according to a variable length coding and calculating a temporary transfer rate indicating an amount of temporary variable length codes in one prescribed time period for each of prescribed time periods, the plurality of temporary transfer rates being variable with time;

a target transfer rate setting step of setting a target transfer rate from each of the temporary transfer rates calculated by the temporary coding step so that a maximum value of each of the target transfer rates is lower than a prescribed constant value, and so as to provide a prescribed value for a total amount of target codes which are determined by a plurality of the target transfer rates corresponding to the moving picture signals in the total data stream, the plurality of target transfer rates being variable with time, and each target transfer rate corresponding to one prescribed time period;

a buffering steps of temporarily storing codes, outputting the codes at one corresponding target transfer rate for each prescribed time period, the target transfer rates for the prescribed time periods being variable with time, and outputting occupancy information representing an occupancy degree of the codes in the buffering step; and

a real coding step of quantizing each of the moving picture signals in the total stream according to a real quantization step width which is determined according to each of the activities of the moving picture signals and the occupancy information output from the buffering step to produce a plurality of real quantized signals so that a volume of variable length codes obtained from each of the real quantized signals according to the variable length coding is increased or decreased with the decrease or increase of the occupancy information and so that a total sum of variable length codes obtained from the real quantized signals becomes the prescribed value, changing the real quantized signals to a plurality of real variable length codes having a total volume which is equal to the prescribed value according to the variable length coding, and performing the buffering step on the real variable length codes one after another to output the real variable length codes from the buffering step at one corresponding target transfer rate for each prescribed time period, the target transfer rates for the prescribed time periods being variable with time.