JPH06311505A - Motion picture coder and decoder - Google Patents

Abstract

PURPOSE:To obtain the device with less picture quality deterioration even when the device is simplified by subsampling an anticipation residual error as to a frame of acyclic prediction so as to reduce number of picture elements thereby executing in-frame coding and reducing the quantity of arithmetic operation. CONSTITUTION:In the case of a B frame, an input picture signal is led to a buffer 3 via a switch 2. The input picture signal is delayed and given to an anticipation subtractor 4 till two I frames required for 2-thetaway anticipation are inputted to the buffer 3. The subtractor 4 subtracts an inter-frame anticipation signal given from a anticipation device 12 from the picture signal and an anticipation residual signal is fed to a sub sampler 5. The anticipation residual signal in the sampler 5 is filtered corresponding to the sub sampling and both the signals in the vertical and horizontal directions are interleaved. The anticipation residual signal is inputted to a buffer 6 at a speed in matching with the output of the sampler 5 and outputted to an in-frame coder 8 in matching with the processing speed of the in-frame coder 8 from buffer 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION In recording, transmission, and display devices for processing digital signals, the present invention relates to high-efficiency coding for efficiently coding signals with a smaller code amount, and particularly coding of moving image signals. The present invention relates to a device and a decoding device.

[0002]

2. Description of the Related Art In high-efficiency coding of moving pictures, there is interframe predictive coding in which prediction is performed between frames of an image signal and a prediction error is coded. In recent years, motion-compensated inter-frame prediction, in which an image is moved and predicted in accordance with motion, has become more common. Therefore, as an encoding method using bidirectional inter-picture prediction, an IS called an MPEG method is used.
Some are standardized by O / IEC. In the MPEG method, as the first encoding, one frame is encoded independently of several frames, or predictive encoding is performed between the frames, and the other frames are first encoded by the second encoding. Predicted from frame.

The second coded frame is adaptively predicted from the first coded frames before and after it, but is not used for interframe prediction of other frames. That is, the second coding is non-cyclic prediction. FIG. 7 shows an example of inter-frame prediction in that case. FIG. 7 is an explanatory diagram of interframe prediction. In FIG. 7, I (acronym for Intra) is a frame that is independently coded, and in order to simplify the explanation, it is assumed that interframe prediction is not performed in the first coding. Since the second coded frame is bidirectionally predicted, B (acronym for Bi-directional)
Called a frame.

A conventional moving picture coding apparatus will be described below with reference to FIG. FIG. 5 is a block diagram showing a conventional example of a moving picture coding apparatus. In FIG. 5, the input image signal input to the image signal input terminal 1 is the changeover switch 2
And a frame controller 10 that generates frame control information. The changeover switches 2 and 7 are switched between when the frame of the input image corresponds to the I frame and when it corresponds to the B frame according to the control information from the frame controller 10 according to the synchronizing signal of the input image signal. The control information is also given to the multiplexer 13.

First, at the time of the I frame, the image signal input from the image signal input terminal 1 is given to the frame memory 27 and the changeover switch 7 via the changeover switch 2. Therefore, the input image signal is stored in the frame memory 27 and is also guided to the intra-frame encoder 8A via the changeover switch 7. In the intra-frame encoder 8A, DCT (discrete cosine transform), quantization, variable length coding, etc. are performed to obtain a compressed code, which is given to the multiplexer 13 as main information.

Next, in the B frame, the input image signal is given to the buffer 3 by the changeover switch 2. In the buffer 3, the input image signal is delayed until the I frame used for inter-frame prediction is prepared in the frame memory 27. The prediction subtractor 4 subtracts the prediction signal output from the predictor 12 from the output of the buffer 3, and outputs the prediction residual signal. The prediction residual signal is guided to the intra-frame encoder 8A via the changeover switch 7. The intra-frame encoder 8 performs the same processing as the I frame.

On the other hand, the image signal stored in the frame memory 27 is delayed for inter-frame prediction and given to the predictor 12. The frame memory 27 holds two I frame signals for bidirectional prediction, and is updated when the input image is an I frame. The predictor 12 determines an adaptive prediction method, detects a motion vector when performing motion compensation, and generates a prediction signal. The prediction information such as the adaptive prediction method and the motion vector at that time is given to the multiplexer 13. In the multiplexer 13, the main information, the prediction information, and the control information are multiplexed, and the multiplexed code is the encoded data output terminal 9
Is output to the decoding device.

An example of a conventional decoding device will be described below with reference to FIG. FIG. 6 is a diagram showing an example of a conventional decoding device. In FIG. 6, the encoded data input terminal 20
The input multiplex code is separated into main information, prediction information, and control information by the demultiplexer 26. The main information is sent to the intraframe decoder 21, the prediction information is sent to the predictor 28, and the control information is switched to a switch. Given to 2, 7 In the intra-frame decoder 21, first, the variable length code is decoded, replaced with the quantized representative value by the inverse quantization process, and further inverse DCT is performed to form a reproduced image signal, which is given to the changeover switch 2.

At the changeover switch 2, the reproduced image signal is given to the frame memory 27 for the I frame and to the inverse prediction adder 24 for the B frame. First, in the I frame, the reproduced image signal is delayed in the frame memory 27, and then the reproduced image is output from the reproduced image output terminal 25 via the changeover switch 7. This is I
This is because the frame is decoded prior to the B frame, so that the output frame order is restored.

On the other hand, in the B frame, the inverse prediction adder 24
Then, the prediction signal from the predictor 28 is added to the reproduction residual signal from the changeover switch 2, and the reproduced image is output from the reproduced image output terminal 25 via the changeover switch 7. The operation of the frame memory 27 is the same as that of the encoding device shown in FIG. In the predictor 28, a prediction signal is generated based on the output of the frame memory 27 according to adaptive prediction or motion vector information given from the outside, and is given to the inverse prediction adder 24.

[0011]

In the conventional coding system, since the DCT is used in the intraframe coding, the amount of calculation is very large. Therefore, when trying to handle a high-definition image, the processing amount increases in proportion to the definition. On the other hand, it has been found that suppressing a frequency component having a high prediction residual does not cause a visual problem in a B frame that is non-cyclic prediction, and a method of using it to improve coding efficiency is
The same inventor and the same applicant as the present invention filed the application as "interframe predictive coding apparatus" (Japanese Patent Laid-Open No. 2-288788). The present invention has been made in view of the above points, and an object of the present invention is to provide a moving picture coding apparatus and a decoding apparatus with little deterioration in image quality even if the apparatus is simplified by greatly reducing the amount of calculation. And

[0012]

A moving picture coding and decoding apparatus according to the present invention performs sub-sampling on a prediction residual signal of a frame which is non-cyclic prediction among moving picture information to obtain an information amount. Either reduce or encode, or layer moving image information according to its spatial frequency so that signals with high frequency components do not encode prediction residuals, and DCT calculation is performed without degrading image quality. The amount of coding processing is greatly reduced, and the decoding processing amount can be greatly reduced in the decoding device corresponding to the coding device. The moving picture coding apparatus of the present invention has two types of modes, a first type and a second type. The first mode is to subsample the prediction residual for a B frame that is a non-cyclic prediction, reduce the number of pixels, and then perform intra-frame coding. The coding is performed by layering into a component and a high frequency component, and the prediction residual is not coded with respect to the high frequency signal of the B frame, and only the motion vector and information of the adaptive prediction method are obtained by virtual prediction processing. It is to be encoded.

Further, the moving picture decoding apparatus of the present invention has two types, that is, first and second types. A first form is a decoding device corresponding to the moving picture coding device of the first form, and for B frames, after the number of signals reduced by sub-sampling is restored to the original by interpolation,
The second mode is a decoding device corresponding to the moving picture coding device of the second mode, in which the number of signals thinned out for low frequency components is used. Is returned to the original state, added with the high frequency component output from the prediction means, and the reproduced image signal is output. In this case, the high frequency component of the B frame is only the prediction signal component.

[0014]

In the B frame, the prediction residual is subsampled before intraframe coding is performed, and at the time of decoding, the number of signals reduced by the subsample is restored to the original number of signals by interpolation and then decoded. Further, in the coding in which the information is layered into the low frequency component and the high frequency component, if the intra-frame coding is not performed for the signal of the high frequency component of the non-cyclic prediction, the prediction residual of the B frame is high. Although the frequency component disappears, the prediction residual of the B frame corresponds to the high frequency component of the temporal filter, so the spatially high frequency component becomes a high frequency component on the time axis, and even if there is no signal component, the visual Is hardly detected.

Since the B frame is not used for prediction of other frames, subsampling does not affect other frames. On the other hand, the number of pixels that must be processed in the B frame is significantly reduced, and the B frame occupies a large proportion of all the frames. As a result, the calculation amount of intraframe coding and intraframe decoding is significantly reduced. be able to.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the moving picture coding apparatus of the present invention will be described in detail below with reference to FIG. FIG. 1 is a block diagram showing a first embodiment of the moving picture coding apparatus according to the present invention. In FIG. 1, the same components as those of the conventional example shown in FIG. 5 are designated by the same reference numerals, and the description thereof will be omitted. The main difference in structure between the device of the present invention shown in FIG. 1 and the conventional device shown in FIG. 5 is that a sub-sampler 5 and a buffer 6 are provided. The encoding method of the first embodiment shown in FIG. 1 is basically the same as the conventional example, but the timing of the encoding process is different.

FIG. 8 is a diagram showing the timing of encoding in the first embodiment of the present invention. As shown in FIG.
In the frame, the intra-frame processing is performed using twice the time of the input image signal, and the inter-frame processing is not performed. On the other hand, in the B frame, the inter-frame processing is performed for 1.5 times the input image signal, and the intra-frame processing is performed for half the input image signal. This is because the number of pixels for the intra-frame processing of the B frame is reduced as described later. It should be noted that the I-frame signal is used in the inter-frame processing of the B-frame, but when motion compensation is performed, more images are required for the vertical motion range, and therefore the processing timing is slightly increased for the range. Need to be delayed.

In FIG. 1, the prediction means 50 for obtaining the prediction residual signal is composed of a switch 2, a buffer 3, a subtractor 4, a frame memory 11, a predictor 12, and the like. In FIG. 1, the changeover switches 2 and 7 are changed over in accordance with the control information from the frame controller 10 in accordance with the synchronizing signal of the input image signal in the I frame and the B frame. The control information is also given to the multiplexer 13. The encoding procedure will be described below. In FIG. 1, the input image signal applied to the image signal input terminal 1 is transmitted through the changeover switch 2 to the frame memory 1 in the I frame.
Input to 1. Two different output signals are output from the frame memory 11 to the predictor 12 and the changeover switch 7, respectively.

The signal given to the changeover switch 7 is supplied to the intraframe encoder 8 through the changeover switch 7. The supply of this signal is performed at a timing matched with the intraframe encoding processing of the I frame. The operation of the intra-frame encoder 8 is basically the same as that of the conventional example of FIG. 5, but the processing time for an I frame is twice as long as the input image signal. This coding result is given to the multiplexer 13 as main information. Next, in the case of the B frame, the input image signal is guided to the buffer 3 via the changeover switch 2. In the buffer 3, the input image signal is delayed until two I-frame signals required for bidirectional prediction are input, and then provided to the prediction subtractor 4.

The predictive subtractor 4 subtracts the inter-frame predictive signal supplied from the predictor 12 and supplies it as a predictive residual signal to the subsampler 5. In the sub-sampler 5, the input prediction residual signal is first filtered corresponding to the sub-samples, and then 1 in both the vertical and horizontal directions.
/ 2 is thinned out. As a result, the intra-frame coding processing amount of the B frame becomes 1/4, and assuming that the I frame is once every three frames, the processing amount of three consecutive frames is one.
+ 0.25 + 0.25 = 1.5 frames, half the number. Therefore, the processing capacity of the intraframe encoder 8 is half that of the conventional example.

The output of the subsampler 5 is guided to the buffer 6. The buffer 6 is for coping with the difference in timing between the inter-frame processing and the intra-frame processing, and the prediction residual signal is input to the buffer 6 at a speed suitable for the output of the subsampler 5, 6 to the intraframe encoder 8 according to the processing speed of the intraframe encoder 8. Here, since the number of pixels of the signal of the buffer 6 is 1/4 due to the sub-sampling and the processing speed of the intra-frame encoder 8 is 1/2, the main information for one frame corresponds to the conventional example. Is output to the multiplexer 13 in 1/2 time.

The output of the buffer 6 is guided to the intraframe encoder 8 through the changeover switch 7 and is encoded in the intraframe encoder 8 in the same manner as the I frame. on the other hand,
The I-frame image for two frames is held in the frame memory 11 and is output to the predictor 12 at the timing of the inter-frame processing of the B frame. In the predictor 12,
A prediction signal is created and given to the prediction subtractor 4, and
The prediction information is given to the multiplexer 13. Here, since the interframe processing is not performed for the I frame, the interframe processing for the B frame is performed by taking 1.5 times as long as the input image signal.

In the multiplexer 13, three types of information (main information, prediction information, control information) are multiplexed, and this multiplexed code is output from the encoded data output terminal 9 to the decoding device. The first embodiment of the encoding device of the present invention is a DS
The processing time when realized by P (Digital Signal Processor) is different from the processing time by the hardware shown in FIGS. FIG. 10 is a diagram showing the processing ratio of the DSP according to the first embodiment of the encoding apparatus of the present invention, and shows the contents of the processing in each frame when the present embodiment is realized by the DSP.

In the DSP, the processing is performed by software,
Although it is possible to change processing significantly on a frame-by-frame basis, there is a limit to the processing capacity. In the first embodiment, the motion compensation (MC) is required for the B frame, but since the processing amount of DCT becomes 1/4, the overall processing amount does not change much, which is rational. In this case, since the processing of each frame is completed within the time of the frame, the capacity of the buffer 6 is small.

The first embodiment of the moving picture decoding apparatus of the present invention will be described below. FIG. 2 is a block diagram showing a first embodiment of the moving picture decoding apparatus of the present invention, and shows a moving picture decoding apparatus corresponding to the coding apparatus shown in FIG. The same components as those of the conventional example shown in FIG. 6 or the encoding device shown in FIG. 1 are designated by the same reference numerals, and the description thereof will be omitted. The main difference in configuration between the decoding device shown in FIG. 2 and the conventional example shown in FIG. 6 is that a buffer 22 and an interpolator 23 are provided. FIG. 9 is a diagram showing the timing of the decoding process in the first embodiment of the present invention. As shown in the figure, the timing of the intraframe processing is the same as that in the case of the encoding apparatus, but since the interframe processing of the B frame is performed after the intraframe decoding of the B frame is started,
Delayed by a frame.

Further, the time for interframe processing of B frame is not 1.5 times as long as the time for I frame as in the encoding device of FIG. 1, and the image output output from the decoding device to the outside is not made. Same time as. This requires a buffer if the timings of image output and processing are different, and on the other hand, inter-frame prediction processing of the decoding device can be easily performed using the prediction information, so there is no need to extend the processing time. In Figure 2,
The operations of the demultiplexer 26, the intraframe decoder 21, and the changeover switches 2 and 7 are the same as those in the conventional example.

In the I frame, the intraframe decoder 21
The decoded image signal from is delayed in order to restore the frame order in the frame memory 27, and then output from the reproduced image output terminal 25 via the changeover switch 7.
In the B frame, the prediction residual signal decoded by the intraframe decoder 21 is input to the buffer 22. Buffer 2
2, the input / output timing and the sample rate are opposite to those of the buffer 6 of the encoder shown in FIG. 1 as shown in FIG. 9, and the output is given to the interpolator 23.

In the interpolator 23, the pixels decimated by the sub-sampler are created by interpolation and returned to the same number of pixels as the original image. The output of the interpolator 23 is added to the prediction signal output from the predictor 28 in the inverse prediction adder 24, and the reproduced image signal is output from the reproduced image output terminal 25 via the changeover switch 7. The operations of the frame memory 27 and the predictor 28 are the same as in the conventional example. Incidentally, the interpolator 23
Output and the prediction signal from the predictor 28 are added to obtain a reproduced image signal. The predictions here are acyclic. That is, a predictive addition unit 60 for obtaining a reproduced image signal by performing non-cyclic predictive addition between frames is provided, which is composed of a frame memory 27, a predictor 28, an inverse predictive adder 24, and the like.

A second embodiment of the moving picture coding apparatus according to the present invention will be described below with reference to FIG. FIG. 3 is a block diagram showing a second embodiment of the moving picture coding apparatus of the present invention.
In FIG. 3, the coding is hierarchical, and the feature is that coding is not performed on the prediction residual of the B frame at high frequency components, but the first embodiment is generally The operation is similar to the example. Further, in the second embodiment, in order to simplify the explanation, it is assumed that the signal of the low frequency component is not subjected to interframe coding but only intraframe coding.

The input image signal input to the image signal input terminal 1 is supplied to the band dividing means 70 and the frame controller 10. The band dividing unit 70 is a unit that hierarchically divides an input image signal into high frequency components and low frequency components according to spatial frequencies, and includes a subsampler 5, a subtractor 31,
It is composed of an interpolator 23 and the like. In subsampler 5,
After filtering corresponding to sub-samples for both I frame and B frame, the number of pixels is thinned out to 1/2 in both vertical and horizontal directions. The output of the subsampler 5 is the interpolator 23.
To the buffer 6.

The interpolator 23 performs the same processing as that of the interpolator 23 shown in FIG. 2, and the signal having the same number of pixels as the original image is given to the subtractor 31 as a subtraction input. It should be noted that the output signal of the interpolator 23 has only low frequency components whose band is limited by the subsampler 5. The subtracter 31 subtracts the output of the interpolator 23 from the input image signal, and outputs a high frequency component signal obtained by removing the low frequency component from the input image signal. The signal of the high frequency component is input to the frame memory 11 and held for detecting the motion vector by the virtual predictor 32 and for determining the adaptive prediction method. Although the motion vector is detected in the virtual predictor 32 and a prediction method in bidirectional prediction is determined, no prediction signal is generated and only prediction information is multiplexed via the prediction information encoder 33 that encodes prediction information. It is output to the digitizer 13.

The high frequency component of the I frame is given from the frame memory 11 to the intraframe encoder 8 via the changeover switch 30. At other timings, that is, in the low frequency component of the I frame and in the B frame, the sub-sampled signal which is the low frequency component is given from the buffer 6 to the intraframe encoder 8 via the changeover switch 30. In the intra-frame encoder 8, the first of the encoding devices
Processing similar to that in the embodiment is performed. Here, all the sub-sampled signals are encoded, but the signals of high frequency components are I
It exists only in the frame. Therefore, in the I frame, all frequency components are intra-frame encoded, but in the B frame, only the sub-sampled signal, that is, the low frequency component is encoded. However, as will be described later, a decoding apparatus corresponding to the present encoding apparatus performs motion-compensated inter-frame prediction, so that a high frequency component is reproduced even in a B frame.

The moving picture decoding apparatus of the present invention will be described below with reference to FIG. FIG. 4 is a block diagram showing a second embodiment of the moving picture decoding apparatus of the present invention, and shows a moving picture decoding apparatus corresponding to the moving picture coding apparatus of FIG. In FIG. 4, the same components as those of the decoding device of FIG. 6 or 2 are designated by the same reference numerals and the description thereof will be omitted. The main structural difference between the second embodiment shown in FIG. 4 and the first embodiment shown in FIG. 2 is that the changeover switch 7 is in front of the adder 41. In FIG. 4, operations of the demultiplexer 26, the intraframe decoder 21, the buffer 22, and the interpolator 23 are the same as those in the conventional example shown in FIG.

The operation of the changeover switch 40 is different from that of the changeover switch 2 and is controlled so that the sub-sampled signal (low frequency component) is given to the buffer 22 and the signal of high frequency component is given to the prediction means 80. This prediction means 80
Is a means for obtaining a reproduced image signal of a high frequency component of a moving image signal layered according to a spatial frequency using the motion vector and the information of the adaptive prediction method obtained by the prediction information decoder 34. Yes, frame memory 27, predictor 2
8, a changeover switch 7 and the like. The output of the frame memory 27 is given to the predictor 28. The predictor 28 generates a prediction signal from the prediction information as in the case of FIG. This prediction signal is used as a reproduced image signal of high frequency component without being added to the prediction residual.

The changeover switch 7 is switched between the B frame and the I frame, and in the I frame, the frame memory 2
The output of 7 is the output of the predictor in the B frame, which is given to the adder 41 as a reproduced image signal of a high frequency component. In the adder 41, the interpolated low frequency component reproduction signal and the high frequency component reproduction signal are added and output as a reproduction image signal. Therefore, in the B frame, the high frequency component of the reproduced image signal is only the prediction signal component, which is the same as in the first embodiment. In the above description, the intra-frame coding, the intra-frame decoding, the intra-frame processing, the inter-frame processing, and the like have been described on a frame-by-frame basis. It goes without saying that it does not depart from the spirit of the present invention.

[0035]

In the moving picture coding apparatus and the decoding apparatus of the present invention, the prediction residual is subsampled for a frame which is a non-cyclic prediction, the number of pixels is reduced, and then intraframe coding and decoding are performed. In addition, in hierarchical coding of low-frequency components and high-frequency components, intra-frame coding of prediction residuals is not performed for high-frequency components of non-cyclic prediction, which significantly reduces the number of signals that need to be processed in-frame. As a result, the amount of calculation for intra-frame coding / decoding can be significantly reduced, and the device can be simplified. There is also an advantage that the deterioration of the image quality is small. As described above, the moving picture coding apparatus and the decoding apparatus of the present invention have extremely excellent practical effects.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment of a moving picture coding apparatus according to the present invention.

FIG. 2 is a block diagram showing a first embodiment of a moving picture decoding apparatus according to the present invention.

FIG. 3 is a block diagram showing a second embodiment of the moving picture coding apparatus of the present invention.

FIG. 4 is a block diagram showing a second embodiment of the moving picture decoding apparatus of the present invention.

FIG. 5 is a block diagram showing an example of a conventional moving image encoding device.

FIG. 6 is a block diagram showing an example of a conventional moving picture decoding apparatus.

FIG. 7 is an explanatory diagram of inter-frame prediction.

FIG. 8 is a diagram showing an encoding timing in the first embodiment of the present invention.

FIG. 9 is a diagram showing the timing of the decoding process in the first embodiment of the present invention.

FIG. 10 shows D according to the first embodiment of the encoding device of the present invention.
The figure which shows the ratio of processing of SP.

[Explanation of symbols]

 2, 7, 30, 40 ... Changeover switch 3, 6, 22 ... Buffer 4 ... Predictive subtractor 5 ... Subsampling means (subsampler) 8 ... Encoding means (intraframe encoder) 10 ... Frame controller 11, 27 ... Frame memory 12, 28 ... Predictor 13 ... Multiplexer 21 ... Decoding means (intraframe decoder) 23 ... Interpolation means (interpolator) 24 ... Inverse prediction adder 26 ... Demultiplexing separator 31 ... Subtractor 32 ... Virtual prediction means (virtual predictor) 33 ... Prediction information coding means (prediction information encoder) 34 ... Prediction information decoding means (prediction information decoder) 41 ... Addition means (adder) 50, 80 ... Prediction means 60 ... Prediction addition means 70 ... Band division means

Claims (4)

[Claims] 1. A moving picture coding apparatus using inter-frame prediction or inter-field prediction of a moving picture signal, prediction means for obtaining a prediction residual signal by non-cyclic prediction between frames or fields, and said prediction. Sub-sampling means for thinning out the prediction residual signal obtained by the means to reduce the number of signals, and coding means for intra-frame coding or intra-field coding of the prediction residual signal with the reduced number of signals by the sub-sampling means And a moving picture coding device. 2. A moving picture decoding apparatus for decoding encoded moving picture information, and decoding means for decoding intra-frame coded or intra-field coded picture information, said decoding Interpolation means for performing interpolation on the signal obtained by the means, and converting the number of signals reduced by sub-sampling to the original number of signals; and an acyclic prediction signal between frames or fields at the output of the interpolation means. And a predictive addition unit that obtains a reproduced image signal by adding. 3. A band for hierarchically dividing an input image signal into a high frequency component and a low frequency component according to a spatial frequency in a moving image encoding apparatus using inter-frame prediction or inter-field prediction of a moving image signal. Dividing means, encoding means for encoding the signal of the low frequency component obtained by the band dividing means, and for the signal of the high frequency component obtained by the band dividing means, the frame without performing actual prediction processing Virtual prediction means for detecting an inter-field or inter-field motion vector and setting an adaptive prediction method; and prediction information coding means for coding the information of the motion vector and adaptive prediction method obtained by the virtual prediction means. And a moving picture coding device. 4. A moving picture decoding apparatus for decoding coded moving picture information, wherein a low frequency component of moving picture information layered according to a spatial frequency is decoded and the low frequency component of the low frequency component is decoded. Decoding means for obtaining a reproduced image signal, prediction information decoding means for decoding motion vector information and adaptive prediction method information, and motion vector and adaptive prediction method information obtained by the prediction information decoding means are used. A prediction means for obtaining a reproduced image signal of a high frequency component of a moving image signal layered according to a spatial frequency; and a reproduced image obtained by adding the reproduced image signal of the low frequency component and the reproduced image signal of the high frequency component. A moving picture decoding apparatus, comprising: an addition means for obtaining a signal.