CN113068038A - Moving picture decoding device, moving picture decoding method, and moving picture decoding program - Google Patents

Abstract

The invention relates to a moving picture decoding device, a moving picture decoding method, and a moving picture decoding program. In order to provide a low-load and efficient encoding technique, an image decoding device includes: a spatial motion information candidate derivation unit that derives a spatial motion information candidate from motion information of a block spatially close to a decoding target block; a temporal motion information candidate derivation unit that derives a temporal motion information candidate from motion information of a block temporally close to the decoding target block; and a historical motion information candidate derivation unit configured to derive a historical motion information candidate from a memory that holds motion information of a decoded block, wherein the temporal motion information candidate is not compared with motion information of any of the spatial motion information candidate and the historical motion information candidate.

Description

Moving picture decoding device, moving picture decoding method, and moving picture decoding program

The present application is a divisional application of the present invention based on the invention patent application No. 201980050793.9, filed on 2019, 12/20/h, entitled "moving picture decoding device, moving picture decoding method, moving picture decoding program, moving picture encoding device, moving picture encoding method, and moving picture encoding program" by JVC institute co.

Technical Field

The present invention relates to an image encoding and decoding technique for dividing an image into blocks and performing prediction.

Background

In image encoding and decoding, an image to be processed is divided into blocks, which are sets of a predetermined number of pixels, and processed in units of blocks. By dividing the block into appropriate blocks, intra prediction (intra prediction) and inter prediction (inter prediction) are appropriately set, thereby improving encoding efficiency.

In encoding/decoding of a moving picture, the encoding efficiency is improved by inter prediction predicted from an already encoded/decoded picture. Patent document 1 discloses a technique of applying affine transformation in inter-frame prediction. In a moving image, it is not uncommon for an object to be deformed such as enlarged, reduced, or rotated, and the technique of patent document 1 is applied to enable efficient encoding.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open No. 9-172644.

Disclosure of Invention

Problems to be solved by the invention

However, the technique of patent document 1 involves a problem of a large processing load because of the image conversion. In view of the above, the present invention provides a low-load and efficient coding technique.

Means for solving the problems

In order to solve the above problem, a moving picture decoding apparatus according to an aspect of the present invention includes: a spatial motion information candidate derivation unit that derives a spatial motion information candidate from motion information of a block spatially close to a decoding target block; a temporal motion information candidate derivation unit that derives a temporal motion information candidate from motion information of a block temporally close to the decoding target block; and a historical motion information candidate derivation unit configured to derive a historical motion information candidate from a memory that holds motion information of a decoded block, wherein the temporal motion information candidate is not compared with motion information of any of the spatial motion information candidate and the historical motion information candidate.

In addition, a moving picture decoding method according to another aspect of the present invention includes the steps of: deriving a spatial motion information candidate from motion information of a block spatially close to the decoding object block; deriving a temporal motion information candidate from motion information of a block temporally close to the decoding object block; and deriving a historical motion information candidate from a memory holding motion information of decoded blocks, the temporal motion information candidate not being compared with motion information of either of the spatial motion information candidate and the historical motion information candidate.

In addition, a moving picture decoding program according to another aspect of the present invention causes a computer to function as: a spatial motion information candidate derivation unit that derives a spatial motion information candidate from motion information of a block spatially close to a decoding target block; a temporal motion information candidate derivation unit that derives a temporal motion information candidate from motion information of a block temporally close to the decoding target block; and a historical motion information candidate derivation unit configured to derive a historical motion information candidate from a memory that holds motion information of a decoded block, wherein the temporal motion information candidate is not compared with motion information of any of the spatial motion information candidate and the historical motion information candidate.

ADVANTAGEOUS EFFECTS OF INVENTION

According to the present invention, efficient image encoding/decoding processing can be realized with low load.

Drawings

Fig. 1 is a block diagram of an image encoding device according to an embodiment of the present invention;

fig. 2 is a block diagram of an image decoding apparatus according to an embodiment of the present invention;

FIG. 3 is a flowchart for explaining the operation of dividing a treeblock;

fig. 4 is a diagram showing a case where an input image is divided into tree blocks;

FIG. 5 is a diagram illustrating z-scanning;

fig. 6A is a diagram showing a divided shape of a block;

fig. 6B is a diagram showing a divided shape of a block;

fig. 6C is a diagram showing a division shape of a block;

fig. 6D is a diagram showing a division shape of a block;

fig. 6E is a diagram showing a division shape of a block;

FIG. 7 is a flowchart for explaining an operation of dividing a block into 4 parts;

FIG. 8 is a flowchart for explaining an operation of dividing a block into 2 or 3 parts;

fig. 9 is a syntax for describing a shape of block division;

fig. 10A is a diagram for explaining intra prediction;

fig. 10B is a diagram for explaining intra prediction;

fig. 11 is a diagram for explaining a reference block for inter prediction;

fig. 12 is a syntax for describing a prediction mode of a coding block;

fig. 13 is a diagram illustrating a correspondence between syntax elements and modes related to inter prediction;

fig. 14 is a diagram for explaining affine transformation motion compensation in which control points are two points;

fig. 15 is a diagram for explaining affine transformation motion compensation in which control points are three points;

fig. 16 is a block diagram showing a detailed configuration of the inter prediction unit 102 of fig. 1;

fig. 17 is a block diagram showing a detailed configuration of the normal predictive motion vector mode derivation unit 301 in fig. 16;

fig. 18 is a block diagram showing a detailed configuration of the normal merge mode derivation unit 302 in fig. 16;

fig. 19 is a flowchart for explaining the normal predictive motion vector pattern derivation process by the normal predictive motion vector pattern derivation unit 301 in fig. 16;

fig. 20 is a flowchart showing the processing procedure of the normal predictive motion vector pattern derivation process;

fig. 21 is a flowchart illustrating processing steps of a normal merge mode derivation process;

fig. 22 is a block diagram showing a detailed configuration of the inter prediction unit 203 of fig. 2;

fig. 23 is a block diagram showing a detailed configuration of the normal predictive motion vector mode derivation unit 401 in fig. 22;

fig. 24 is a block diagram showing a detailed configuration of the normal merge mode derivation unit 402 in fig. 22;

fig. 25 is a flowchart for explaining the normal predictive motion vector pattern derivation process by the normal predictive motion vector pattern derivation unit 401 in fig. 22;

fig. 26 is a diagram illustrating a history prediction motion vector candidate list initialization/update process;

fig. 27 is a flowchart of the same element confirmation processing step in the history prediction motion vector candidate list initialization/update processing step;

fig. 28 is a flowchart of an element shift processing step in the history prediction motion vector candidate list initialization/update processing step;

fig. 29 is a flowchart illustrating a procedure of the history prediction motion vector candidate derivation processing;

fig. 30 is a flowchart illustrating a history merge candidate derivation processing step;

fig. 31A is a diagram for explaining an example of the history prediction motion vector candidate list update processing;

fig. 31B is a diagram for explaining an example of the history prediction motion vector candidate list update processing;

fig. 31C is a diagram for explaining an example of the history prediction motion vector candidate list update processing;

fig. 32 is a diagram for explaining motion compensation prediction in a case where the reference picture (RefL0Pic) of L0 is at a time before the processing target picture (CurPic) in L0 prediction;

fig. 33 is a diagram for explaining motion compensation prediction in a case where a reference picture predicted by L0 is at a time after a processing target picture in L0 prediction;

fig. 34 is a diagram for explaining prediction directions of motion compensation prediction in the case where a reference picture predicted by L0 is at a time before a processing target picture and a reference picture predicted by L1 is at a time after the processing target picture in bi-prediction;

fig. 35 is a diagram for explaining the prediction directions of motion compensation prediction in the case where the reference picture predicted by L0 and the reference picture predicted by L1 are at the time before the processing target picture in bi-prediction;

fig. 36 is a diagram for explaining the prediction directions of motion compensation prediction in the case where the reference picture predicted by L0 and the reference picture predicted by L1 are at a time point after the processing target picture in bi-prediction;

fig. 37 is a diagram for explaining an example of a hardware configuration of the encoding and decoding device according to the embodiment of the present invention;

fig. 38 is a block diagram showing the detailed configuration of the normal predictive motion vector mode derivation unit 301 shown in fig. 16 according to the second embodiment of the present invention;

fig. 39 is a block diagram showing the detailed configuration of the normal predictive motion vector mode derivation unit 401 in fig. 22 according to the second embodiment of the present invention;

fig. 40 is a block diagram showing the detailed configuration of the normal predictive motion vector mode derivation unit 301 shown in fig. 16 according to the third embodiment of the present invention;

fig. 41 is a block diagram showing the detailed configuration of the normal predictive motion vector mode derivation unit 401 in fig. 22 according to the third embodiment of the present invention.

Detailed Description

The technique and the technical terms used in the present embodiment are defined.

< Tree Block >

In the embodiment, the encoding/decoding processing target image is divided equally by a predetermined size. This unit is defined as a treeblock. In fig. 4, the size of the tree block is 128 × 128 pixels, but the size of the tree block is not limited thereto, and an arbitrary size may be set. The treeblocks as processing objects (corresponding to encoding objects in encoding processing and decoding objects in decoding processing) are switched in raster scan order, i.e., from left to right and from top to bottom. The interior of each tree block may be further recursively partitioned. A block to be an object of encoding and decoding after recursively dividing the tree block is defined as an encoding block. The tree block and the coding block are collectively referred to as a block. By performing appropriate block division, efficient encoding can be performed. The size of the tree block may be a fixed value predetermined by the encoding apparatus and the decoding apparatus, or may be a configuration in which the size of the tree block determined by the encoding apparatus is transmitted to the decoding apparatus. Here, the maximum size of the treeblock is 128 × 128 pixels, and the minimum size of the treeblock is 16 × 16 pixels. The maximum size of the coding block is set to 64 × 64 pixels, and the minimum size of the coding block is set to 4 × 4 pixels.

< prediction mode >

Switching between INTRA-frame prediction (MODE _ INTRA) which performs prediction according to a processed image signal of a processing target image and INTER-frame prediction (MODE _ INTER) which performs prediction according to an image signal of a processed image, in units of the processing target coding blocks.

The processed image is used for an image, an image signal, a tree block, a block, an encoding block, and the like obtained by decoding a signal for which encoding has been completed in an encoding process, and is used for an image, an image signal, a tree block, a block, an encoding block, and the like for which decoding has been completed in a decoding process.

A MODE for identifying the INTRA prediction (MODE _ INTRA) and the INTER prediction (MODE _ INTER) is defined as a prediction MODE (PredMode). The prediction MODE (PredMode) represents INTRA prediction (MODE _ INTRA) or INTER prediction (MODE _ INTER) in the form of a value.

< inter prediction >

In inter prediction in which prediction is performed from an image signal of a processed image, a plurality of processed images can be used as reference pictures. In order to manage a plurality of reference pictures, two reference lists, L0 (reference list 0) and L1 (reference list 1), are defined, and reference indexes are used to determine reference pictures, respectively. In P slice (P slice), L0 prediction can be used (Pred _ L0). In the B slice (B slice), L0 prediction (Pred _ L0), L1 prediction (Pred _ L1), and BI prediction (Pred _ BI) can be used. The L0 prediction (Pred _ L0) is inter prediction referring to a reference picture managed by L0, and the L1 prediction (Pred _ L1) is inter prediction referring to a reference picture managed by L1. BI-prediction (Pred _ BI) is inter-prediction that simultaneously performs L0 prediction and L1 prediction and refers to one reference picture managed by each of L0 and L1. Information determining the L0 prediction, the L1 prediction, and the bi-prediction is defined as an inter prediction mode. It is assumed that the constant and variable with subscript LX added to the output in the subsequent processing are processed in L0 and L1.

< predicted motion vector mode >

The prediction motion vector mode is a mode in which an index for determining a prediction motion vector, a differential motion vector, an inter prediction mode, and reference index are transmitted, and inter prediction information for determining a processing target block is determined. The prediction motion vector is derived from a prediction motion vector candidate derived from a processed block adjacent to the processing target block or a block located at the same position as or in the vicinity of (adjacent to) the processing target block among blocks belonging to the processed image, and an index for determining the prediction motion vector.

< merging mode >

The merge mode is the following: inter prediction information of a block to be processed is derived from inter prediction information of a processed block adjacent to the block to be processed or a block located at the same position as or in the vicinity of (adjacent to) the block to be processed among blocks belonging to a processed image without transmitting a differential motion vector or a reference index.

A processed block adjacent to a processing target block and inter prediction information of the processed block are defined as spatial merge candidates. A block located at the same position as or in the vicinity of (adjacent to) the block to be processed among blocks belonging to the processed image and inter prediction information derived from inter prediction information of the block are defined as temporal merging candidates. Each merge candidate is registered in the merge candidate list, and the merge candidate used for prediction of the processing target block is specified by the merge index.

< neighboring blocks >

Fig. 11 is a diagram illustrating a reference block referred to for deriving inter prediction information in a predictive motion vector mode and a merge mode. A0, a1, a2, B0, B1, B2, and B3 are processed blocks adjacent to the processing target block. T0 is a block among the blocks belonging to the processed image which is located at the same position as or in the vicinity of (adjacent to) the processing target block in the processing target image.

A1 and a2 are blocks located on the left side of the processing target coding block and adjacent to the processing target coding block. B1 and B3 are blocks located above the processing target coding blocks and adjacent to the processing target coding blocks. A0, B0, and B2 are blocks located at the lower left, upper right, and upper left of the processing object encoding block, respectively.

Details of how the neighboring blocks are processed in the predictive motion vector mode and the merge mode are described later.

< affine transformation motion compensation >

The affine motion compensation is performed by dividing an encoding block into sub blocks of a predetermined unit, and individually determining a motion vector for each of the divided sub blocks. The motion vector of each sub-block is derived based on one or more control points derived from inter prediction information of a block located at the same position as or in the vicinity of (adjacent to) a processing target block among processed blocks adjacent to the processing target block or blocks belonging to a processed image. In the present embodiment, the size of the sub-block is set to 4 × 4 pixels, but the size of the sub-block is not limited to this, and a motion vector may be derived in units of pixels.

Fig. 14 shows an example of affine transformation motion compensation when the control points are two. In this case, the two control points have two parameters of a horizontal direction component and a vertical direction component. Therefore, the affine transformation when the control points are two is referred to as four-parameter affine transformation. CP1 and CP2 in fig. 14 are control points.

Fig. 15 shows an example of affine transformation motion compensation when the control points are three. In this case, the three control points have two parameters of a horizontal direction component and a vertical direction component. Therefore, the affine transformation when the control points are three is referred to as six-parameter affine transformation. CP1, CP2, and CP3 of fig. 15 are control points.

Affine transform motion compensation can be used in either of the predictive motion vector mode and the merge mode. A mode in which affine transformation motion compensation is applied in the prediction motion vector mode is defined as a subblock prediction motion vector mode, and a mode in which affine transformation motion compensation is applied in the merge mode is defined as a subblock merge mode.

< syntax of inter prediction >

The syntax related to inter prediction will be described with reference to fig. 12 and 13.

The merge _ flag in fig. 12 is a flag indicating whether the processing target coding block is set to the merge mode or the prediction motion vector mode. The merge _ affine _ flag is a flag indicating whether or not the subblock merge mode is applied in the processing object encoding block of the merge mode. inter _ affine _ flag is a flag indicating whether the sub-block prediction motion vector mode is applied in the processing object encoding block of the prediction motion vector mode. cu _ affine _ type _ flag is a flag for deciding the number of control points in the sub-block prediction motion vector mode.

Fig. 13 shows values of respective syntax elements and prediction methods corresponding thereto. The merge _ flag 1 and merge _ affine _ flag 0 correspond to the normal merge mode. The normal merge mode is a merge mode that is not a sub-block merge. The merge _ flag 1 and the merge _ affine _ flag 1 correspond to the subblock merge mode. merge _ flag is 0 and inter _ affine _ flag is 0, corresponding to the normal prediction motion vector mode. The normal predicted motion vector mode is a predicted motion vector merge that is not a sub-block predicted motion vector mode. The merge _ flag ═ 0 and the inter _ affine _ flag ═ 1 correspond to the subblock prediction motion vector mode. When merge _ flag is 0 and inter _ affine _ flag is 1, cu _ affine _ type _ flag is further transmitted to determine the number of control points.

<POC>

POC (Picture Order Count) is a variable associated with a Picture to be encoded, and sets a value incremented by 1 corresponding to the output Order of the Picture. From the POC value, it is possible to determine whether or not the pictures are identical, determine the front-back relationship between the pictures in the output order, and derive the distance between the pictures. For example, if the POC of two pictures has the same value, it may be determined to be the same picture. When the POC of two pictures has different values, it can be determined that a picture with a small POC value is a picture to be output first, and the difference between the POC of two pictures indicates the distance between pictures in the time axis direction.

(first embodiment)

An image encoding device 100 and an image decoding device 200 according to a first embodiment of the present invention will be described.

Fig. 1 is a block diagram of an image encoding device 100 according to a first embodiment. The image encoding device 100 according to the embodiment includes a block dividing unit 101, an inter-frame prediction unit 102, an intra-frame prediction unit 103, a decoded image memory 104, a prediction method determination unit 105, a residual generation unit 106, an orthogonal transform/quantization unit 107, a bit string encoding unit 108, an inverse quantization/inverse orthogonal transform unit 109, a decoded image signal superimposing unit 110, and an encoded information storage memory 111.

The block dividing section 101 recursively divides an image that has been input to generate an encoded block. The block dividing unit 101 includes a 4-division unit that divides a block to be divided into blocks in the horizontal direction and the vertical direction, and a 2-3 division unit that divides a block to be divided into blocks in either the horizontal direction or the vertical direction. The block dividing unit 101 sets the generated coding block as a processing target coding block, and supplies an image signal of the processing target coding block to the inter prediction unit 102, the intra prediction unit 103, and the residual generation unit 106. The block dividing unit 101 supplies information indicating the determined recursive division structure to the bit stream encoding unit 108. The detailed operation of the block dividing unit 101 will be described later.

The inter prediction unit 102 performs inter prediction of the encoding block to be processed. The inter prediction unit 102 derives a plurality of candidates for inter prediction information from the inter prediction information stored in the encoding information storage memory 111 and the decoded image signal stored in the decoded image memory 104, selects an appropriate inter prediction mode from the derived plurality of candidates, and supplies the selected inter prediction mode and a predicted image signal corresponding to the selected inter prediction mode to the prediction method determination unit 105. The detailed configuration and operation of the inter prediction unit 102 will be described later.

The intra prediction unit 103 performs intra prediction of the processing target encoding block. The intra prediction unit 103 generates a predicted image signal by intra prediction based on encoding information such as an intra prediction mode stored in the encoding information storage memory 111, with reference to the decoded image signal stored in the decoded image memory 104 as a reference pixel. In the intra prediction, the intra prediction unit 103 selects an appropriate intra prediction mode from a plurality of intra prediction modes, and supplies the selected intra prediction mode and a prediction image signal corresponding to the selected intra prediction mode to the prediction method determination unit 105.

Fig. 10A and 10B show examples of intra prediction. Fig. 10A is a diagram showing the correspondence between the prediction direction of intra prediction and the intra prediction mode number. For example, the intra prediction mode 50 generates an intra prediction image by copying reference pixels in the vertical direction. The intra prediction mode 1 is a DC mode, and is a mode in which all pixel values of the processing target block are set as an average value of the reference pixels. The intra prediction mode 0 is a Planar mode (two-dimensional mode), and is a mode for generating a two-dimensional intra prediction image from reference pixels in the vertical direction and the horizontal direction. Fig. 10B is an example of an intra prediction image in the case of generating the intra prediction mode 40. The intra prediction unit 103 copies the value of the reference pixel in the direction indicated by the intra prediction mode to each pixel of the processing target block. In the case where the reference pixel in the intra prediction mode is not an integer position, the intra prediction section 103 decides a reference pixel value by interpolation from reference pixel values at surrounding integer positions.

The decoded image memory 104 stores the decoded image generated by the decoded image signal superimposing unit 110. The decoded image memory 104 supplies the stored decoded image to the inter prediction unit 102 and the intra prediction unit 103.

The prediction method determination unit 105 determines the optimal prediction mode by evaluating each of intra prediction and inter prediction using the coding information, the coding amount of the residual, the amount of distortion between the predicted image signal and the image signal to be processed, and the like. In the case of intra prediction, the prediction method determination unit 105 supplies intra prediction information such as an intra prediction mode to the bit string encoding unit 108 as encoding information. In the case of the merge mode of inter prediction, the prediction method determination unit 105 supplies inter prediction information such as a merge index and information (sub-block merge flag) indicating whether the mode is a sub-block merge mode to the bit stream encoding unit 108 as encoding information. In the case of the motion vector predictor mode of inter prediction, the prediction method determination unit 105 supplies inter prediction information such as the inter prediction mode, the motion vector predictor index, the reference indices of L0 and L1, the differential motion vector, and information indicating whether or not the motion vector predictor mode is a subblock motion vector predictor (subblock motion vector flag) to the bit string encoding unit 108 as encoding information. The prediction method determination unit 105 supplies the determined encoded information to the encoded information storage memory 111. The prediction method determining unit 105 supplies the predicted image signal to the residual generating unit 106 and the decoded image signal superimposing unit 110.

The residual generating unit 106 generates a residual by subtracting the predicted image signal from the image signal to be processed, and supplies the residual to the orthogonal transformation/quantization unit 107.

The orthogonal transformation/quantization part 107 orthogonally transforms and quantizes the residual according to the quantization parameter to generate an orthogonally transformed/quantized residual, and supplies the generated residual to the bit string coding part 108 and the inverse quantization/inverse orthogonal transformation part 109.

The bit string encoding unit 108 encodes, for each coding block, encoding information corresponding to the prediction method determined by the prediction method determination unit 105, in addition to information of a sequence, a picture, a slice, and a coding block unit. Specifically, the bit string encoding unit 108 encodes the prediction mode PredMode for each encoding block. When the prediction MODE is INTER prediction (MODE _ INTER), the bit string encoding unit 108 encodes encoding information (INTER prediction information) such as a flag for determining whether the prediction MODE is a merge MODE, a sub-block merge flag, a merge index in the case of the merge MODE, an INTER prediction MODE in the case of the non-merge MODE, a predicted motion vector index, information on a differential motion vector, and a sub-block predicted motion vector flag, according to a predetermined syntax (a syntax rule of the bit string), and generates a first bit string. When the prediction MODE is INTRA prediction (MODE _ INTRA), encoding information (INTRA prediction information) such as the INTRA prediction MODE is encoded according to a predetermined syntax (syntax rule of a bit string) to generate a first bit string. The bit string encoding unit 108 entropy encodes the orthogonally transformed and quantized residual according to a predetermined syntax, and generates a second bit string. The bit string encoding unit 108 multiplexes the first bit string and the second bit string according to a predetermined syntax, and outputs a bit stream.

The inverse quantization/inverse orthogonal transform section 109 performs inverse quantization and inverse orthogonal transform on the orthogonally transformed/quantized residual supplied from the orthogonal transform/quantization section 107 to calculate a residual, and supplies the calculated residual to the decoded image signal superimposing section 110.

The decoded image signal superimposing unit 110 superimposes the predicted image signal corresponding to the determination by the prediction method determining unit 105 and the residual resulting from the inverse quantization and inverse orthogonal transformation performed by the inverse quantization/inverse orthogonal transformation unit 109, generates a decoded image, and stores the decoded image in the decoded image memory 104. The decoded image signal superimposing unit 110 may apply filtering processing for reducing distortion such as block distortion due to encoding to the decoded image, and store the result in the decoded image memory 104.

The coding information storage memory 111 stores coding information such as a prediction mode (inter prediction or intra prediction) determined by the prediction method determination unit 105. In the case of inter prediction, the encoding information stored in the encoding information storage memory 111 includes inter prediction information such as the decided motion vector, reference indices of the reference lists L0 and L1, and a history prediction motion vector candidate list. In the case of the merge mode of inter prediction, the encoding information stored in the encoding information storage memory 111 includes, in addition to the above-described information, merge index and inter prediction information indicating whether or not the information is a sub-block merge mode (sub-block merge flag). In the case of the motion vector predictor mode of inter prediction, the coding information stored in the coding information storage memory 111 includes inter prediction information such as the inter prediction mode, a motion vector predictor index, a differential motion vector, and information indicating whether or not the motion vector predictor mode is a sub-block motion vector predictor (sub-block motion vector predictor flag), in addition to the above information. In the case of intra prediction, the encoding information stored in the encoding information storage memory 111 includes intra prediction information such as the determined intra prediction mode.

Fig. 2 is a block diagram showing a configuration of an image decoding apparatus according to an embodiment of the present invention corresponding to the image encoding apparatus of fig. 1. The image decoding apparatus according to the embodiment includes a bit string decoding unit 201, a block dividing unit 202, an inter-frame prediction unit 203, an intra-frame prediction unit 204, a coded information storage memory 205, an inverse quantization/inverse orthogonal transform unit 206, a decoded image signal superimposing unit 207, and a decoded image memory 208.

Since the decoding process of the image decoding apparatus of fig. 2 corresponds to the decoding process provided in the image encoding apparatus of fig. 1, the configurations of the encoded information storage memory 205, the inverse quantization/inverse orthogonal transform unit 206, the decoded image signal superimposing unit 207, and the decoded image memory 208 of fig. 2 have functions corresponding to the configurations of the encoded information storage memory 111, the inverse quantization/inverse orthogonal transform unit 109, the decoded image signal superimposing unit 110, and the decoded image memory 104 of the image encoding apparatus of fig. 1.

The bit stream supplied to the bit stream decoding unit 201 is separated according to a predetermined syntax rule. The bit string decoding unit 201 decodes the separated first bit string, and obtains a sequence, a picture, a slice, information in coding block units, and coding information in coding block units. Specifically, the bit sequence decoding unit 201 decodes a prediction MODE PredMode, which determines whether INTER prediction (MODE _ INTER) or INTRA prediction (MODE _ INTRA), in units of coding blocks. When the prediction MODE is INTER prediction (MODE _ INTER), the bit string decoding unit 201 decodes, according to a predetermined syntax, encoding information (INTER prediction information) related to a flag for determining whether the prediction MODE is a merge MODE, a merge index in the merge MODE, a sub-block merge flag, an INTER prediction MODE in the prediction motion vector MODE, a prediction motion vector index, a differential motion vector, a sub-block prediction motion vector flag, and the like, and supplies the encoding information (INTER prediction information) to the encoding information storage memory 205 via the INTER prediction unit 203 and the block division unit 202. When the prediction MODE is INTRA prediction (MODE _ INTRA), encoding information (INTRA prediction information) such as an INTRA prediction MODE is decoded according to a predetermined syntax, and the encoding information (INTRA prediction information) is supplied to the encoding information storage memory 205 via the inter prediction unit 203, the INTRA prediction unit 204, and the block division unit 202. The bit string decoding unit 201 decodes the separated second bit string, calculates a residual after orthogonal transformation and quantization, and supplies the residual after orthogonal transformation and quantization to the inverse quantization and inverse orthogonal transformation unit 206.

When the prediction MODE PredMode of the encoding block to be processed is the prediction motion vector MODE in INTER prediction (MODE _ INTER), the INTER prediction unit 203 derives a plurality of candidates of prediction motion vectors using the coding information of the decoded image signal stored in the coding information storage memory 205, and registers the derived plurality of candidates of prediction motion vectors in a prediction motion vector candidate list described later. The inter-frame prediction unit 203 selects a predicted motion vector corresponding to the predicted motion vector index decoded and supplied by the bit string decoding unit 201 from among the plurality of predicted motion vector candidates registered in the predicted motion vector candidate list, calculates a motion vector from the differential motion vector decoded by the bit string decoding unit 201 and the selected predicted motion vector, and stores the calculated motion vector in the encoded information storage memory 205 together with other encoded information. Here, the coding information of the coding block to be provided/stored is a prediction mode PredMode, a flag predflag L0[ xP ] [ yP ], predflag L1[ xP ] [ yP ], reference indices refIdxL0[ xP ] [ yP ], refIdxL1[ xP ] [ yP ], motion vectors mvL0[ xP ] [ yP ], mvL1[ xP ] [ yP ] of L0, L1, and the like, which indicate whether or not to use L0 prediction and L1 prediction. Here, xP and yP are indices indicating the position of the upper left pixel of the coding block within the picture. In the case where the prediction MODE PredMode is INTER prediction (MODE _ INTER) and the INTER prediction MODE is L0 prediction (Pred _ L0), a flag predflag L0 indicating whether to use L0 prediction is 1, and a flag predflag L1 indicating whether to use L1 prediction is 0. In the case where the inter prediction mode is L1 prediction (Pred _ L1), a flag predflag L0 indicating whether L0 prediction is used is 0, and a flag predflag L1 indicating whether L1 prediction is used is 1. In the case where the inter prediction mode is BI-prediction (Pred _ BI), both the flag predflag L0 indicating whether L0 prediction is used and the flag predflag L1 indicating whether L1 prediction is used are 1. When the prediction MODE PredMode of the coding block to be processed is a merge MODE in INTER prediction (MODE _ INTER), a merge candidate is derived. A plurality of merging candidates are derived using the coding information of the decoded coding block stored in the coding information storage memory 205, and are registered in a merging candidate list described later, a merging candidate corresponding to the merging index provided by decoding by the bit string decoding unit 201 is selected from among the plurality of merging candidates registered in the merging candidate list, and inter-frame prediction information such as reference indices refIdxL0[ xP ] [ yP ], refIdxL1[ xP ] [ yP ], predFlagL1[ xP ] [ yP ], L0, and L1 indicating whether or not to use L0 prediction and L1 prediction of the selected merging candidate is stored in the coding information storage memory 205, such as motion vectors mvL0[ xP ] [ yP ], mvL1[ xP ] [ yP ]. Here, xP and yP are indices indicating the position of the upper left pixel of the coding block within the picture. The detailed configuration and operation of the inter prediction unit 203 will be described later.

When the prediction MODE PredMode of the coding block to be processed is INTRA prediction (MODE _ INTRA), the INTRA prediction unit 204 performs INTRA prediction. The encoded information decoded by the bit string decoding unit 201 includes an intra prediction mode. The intra prediction section 204 generates a predicted image signal from the decoded image signal saved in the decoded image memory 208 by intra prediction according to the intra prediction mode included in the decoding information decoded by the bit string decoding section 201, and supplies the generated predicted image signal to the decoded image signal superimposing section 207. The intra prediction unit 204 corresponds to the intra prediction unit 103 of the image encoding apparatus 100, and therefore performs the same processing as the intra prediction unit 103.

The inverse quantization/inverse orthogonal transform unit 206 performs inverse orthogonal transform and inverse quantization on the orthogonally transformed/quantized residual decoded by the bit string decoding unit 201, and obtains an inversely orthogonally transformed/inversely quantized residual.

The decoded image signal superimposing unit 207 superimposes the residual of the predicted image signal obtained by the inter prediction unit 203 or the predicted image signal obtained by the intra prediction unit 204 and the inverse orthogonal transform/inverse orthogonal transform unit 206, decodes the decoded image signal, and stores the decoded image signal in the decoded image memory 208. When stored in the decoded image memory 208, the decoded image signal superimposing unit 207 may store the decoded image in the decoded image memory 208 after performing filtering processing for reducing block distortion and the like due to encoding on the decoded image.

Next, the operation of the block dividing unit 101 in the image encoding device 100 will be described. Fig. 3 is a flowchart showing an operation of dividing an image into tree blocks and further dividing each tree block. First, an input image is divided into tree blocks of a predetermined size (step S1001). Each tree block is scanned in a predetermined order, i.e., in a raster scan order (step S1002), and the interior of the tree block to be processed is divided (step S1003).

Fig. 7 is a flowchart showing the detailed operation of the division processing in step S1003. First, it is determined whether or not a block to be processed is divided into 4 blocks (step S1101).

When it is determined that the processing target block 4 is to be divided, the processing target block 4 is divided (step S1102). Each block obtained by dividing the processing target block is scanned in the Z scanning order, that is, the order of upper left, upper right, lower left, and lower right (step S1103). Fig. 5 shows an example of the Z scanning order, and 601 in fig. 6A shows an example of dividing the processing target block 4. Reference numerals 0 to 3 in 601 in fig. 6A denote the processing procedure. Then, for each block divided in step S1101, the division processing of fig. 7 is recursively executed (step S1104).

When it is determined that the processing target block is not to be divided into 4, 2-3 division is performed (step S1105).

Fig. 8 is a flowchart showing the detailed operation of the 2-3 division processing in step S1105. First, it is determined whether or not to perform 2-3 division, that is, whether or not to perform either 2 division or 3 division on a block to be processed (step S1201).

When it is determined that the processing target block is not to be divided into 2-3 blocks, that is, when it is determined that the processing target block is not to be divided, the division is ended (step S1211). That is, the blocks divided by the recursive division processing are not further subjected to the recursive division processing.

When it is determined that the block to be processed is to be 2-3 divided, it is determined whether or not the block to be processed is to be further 2 divided (step S1202).

When it is determined that the processing target block is divided into 2, it is determined whether or not the processing target block is divided into up and down (vertical direction) (step S1203), and based on the result, the processing target block is divided into 2 in up and down (vertical direction) (step S1204) or divided into 2 in left and right (horizontal direction) (step S1205). As a result of step S1204, the processing target block is divided into two parts, upper and lower (vertical direction), as shown at 602 in fig. 6B. As a result of step S1205, the processing target block is divided into two parts, left and right (horizontal direction), as shown by 604 in fig. 6D.

In step S1202, when it is not determined that the processing target block is divided into 2, that is, when it is determined that the processing target block is divided into 3, it is determined whether or not the processing target block is divided into upper, middle, and lower (vertical direction) (step S1206), and based on the result, the processing target block is divided into 3 in upper, middle, and lower (vertical direction) (step S1207) or the processing target block is divided into 3 in left, middle, and right (horizontal direction) (step S1208). As a result of step S1207, the processing target block is divided into upper, middle, and lower (vertical direction) 3 parts as shown by 603 in fig. 6C, and as a result of step S1208, the processing target block is divided into left, middle, and right (horizontal direction) 3 parts as shown by 605 in fig. 6E.

After any of step S1204, step S1205, step S1207, and step S1208 is executed, each of the blocks into which the processing target block is divided is scanned in order from left to right and from top to bottom (step S1209). The numbers 0 to 2 from 602 to 605 in fig. 6B to 6E show the processing procedure. The 2-3 division processing of fig. 8 is recursively executed for each divided block (step S1210).

The recursive block division described here may limit whether or not division is necessary depending on the number of divisions, the size of the block to be processed, and the like. The information for limiting whether division is necessary may be realized by a configuration in which information is not transmitted by a predetermined agreement between the encoding apparatus and the decoding apparatus, or may be realized by a configuration in which the encoding apparatus determines whether division is necessary and records the information in a bit string and transmits the information to the decoding apparatus.

When a block is divided, the block before division is referred to as a parent block, and each block after division is referred to as a child block.

Next, the operation of the block dividing unit 202 in the image decoding apparatus 200 will be described. The block dividing unit 202 divides the tree block in accordance with the same processing procedure as the block dividing unit 101 of the image coding apparatus 100. However, the difference is that the block dividing unit 101 of the image encoding device 100 determines the optimal block division shape by applying an optimization method such as estimation of the optimal shape by image recognition or distortion optimization, whereas the block dividing unit 202 of the image decoding device 200 determines the block division shape by decoding the block division information recorded in the bit string.

Fig. 9 shows a syntax (syntax rule of a bit string) related to the block division of the first embodiment. coding _ quadtree () represents syntax involved in the 4-division process of a block. The multi _ type _ tree () represents a syntax involved in a 2-partition or 3-partition process of a block. qt _ split is a flag indicating whether or not a block is 4-divided. When a block is divided into 4, qt _ split is 1, and when the block is not divided into 4, qt _ split is 0. In the case of 4-division (qt _ split is 1), 4-division processing is recursively performed on each block after 4-division (coding _ quadtree (0), coding _ quadtree (1), coding _ quadtree (2), and coding _ quadtree (3), with 0 to 3 of the argument corresponding to the number of 601 in fig. 6A). When 4-division is not performed (qt _ split ═ 0), the subsequent division is determined in accordance with multi _ type _ tree (). mtt _ split is a flag indicating whether or not to perform further splitting. When the division is performed (mtt _ split is 1), mtt _ split _ vertical, which is a flag indicating whether the division is performed in the vertical direction or the horizontal direction, and mtt _ split _ bank, which is a flag for determining whether the division is performed 2 or 3, are transmitted. mtt _ split _ vertical equal to 1 indicates splitting in the vertical direction, and mtt _ split _ vertical equal to 0 indicates splitting in the horizontal direction. mtt _ split _ bank indicates 2-split, and mtt _ split _ bank indicates 3-split. In the case of 2-division (mtt _ split _ bank ═ 1), division processing is recursively performed on each block after 2-division (multi _ type _ tree (0) and multi _ type _ tree (1), with 0 to 1 of the argument corresponding to the numbers of 602 or 604 in fig. 6B to 6D). In the case of 3-division (mtt _ split _ bank ═ 0), division processing is recursively performed on each block after 3-division (multi _ type _ tree (0), multi _ type _ tree (1), multi _ type _ tree (2), 0 to 2 corresponding to the numbers of 603 in fig. 6B or 605 in fig. 6E). Hierarchical block partitioning is performed by recursively calling multi _ type _ tree until mtt _ split is 0.

< inter prediction >

The inter prediction method according to the embodiment is implemented in the inter prediction unit 102 of the image encoding apparatus of fig. 1 and the inter prediction unit 203 of the image decoding apparatus of fig. 2.

The inter prediction method according to the embodiment will be described with reference to the drawings. The inter prediction method is implemented in any one of the encoding process and the decoding process in units of encoding blocks.

< description of the encoding-side inter prediction unit 102 >

Fig. 16 is a diagram showing a detailed configuration of the inter prediction unit 102 of the image encoding apparatus of fig. 1. The normal predicted motion vector mode derivation unit 301 derives a plurality of normal predicted motion vector candidates, selects a predicted motion vector, and calculates a differential motion vector between the selected predicted motion vector and the detected motion vector. The detected inter prediction mode, reference index, motion vector, and calculated differential motion vector are inter prediction information of the normal prediction motion vector mode. The inter prediction information is supplied to the inter prediction mode determination unit 305. The detailed configuration and processing of the normal prediction motion vector mode derivation unit 301 will be described later.

The normal merge mode derivation unit 302 derives a plurality of normal merge candidates, selects a normal merge candidate, and obtains inter prediction information in the normal merge mode. The inter prediction information is supplied to the inter prediction mode determination unit 305. The detailed configuration and processing of the normal merge mode derivation unit 302 will be described later.

The sub-block motion vector prediction mode deriving unit 303 derives a plurality of sub-block motion vector prediction candidates, selects a sub-block motion vector prediction, and calculates a differential motion vector between the selected sub-block motion vector prediction and the detected motion vector. The detected inter prediction mode, reference index, motion vector and calculated differential motion vector are inter prediction information of the sub block prediction motion vector mode. The inter prediction information is supplied to the inter prediction mode determination unit 305.

The subblock merge mode deriving unit 304 derives a plurality of subblock merge candidates, selects a subblock merge candidate, and obtains inter prediction information of a subblock merge mode. The inter prediction information is supplied to the inter prediction mode determination unit 305.

The inter prediction mode determination unit 305 determines the inter prediction information based on the inter prediction information supplied from the normal prediction motion vector mode derivation unit 301, the normal merge mode derivation unit 302, the sub-block prediction motion vector mode derivation unit 303, and the sub-block merge mode derivation unit 304. The inter prediction information corresponding to the determination result is supplied from the inter prediction mode determination unit 305 to the motion compensation prediction unit 306.

The motion compensation prediction unit 306 performs inter prediction on the reference image signal stored in the decoded image memory 104 based on the determined inter prediction information. The detailed configuration and processing of the motion compensation prediction unit 306 will be described later.

< description of the decoding-side inter prediction unit 203 >

Fig. 22 is a diagram showing the detailed configuration of the inter prediction unit 203 of the image decoding apparatus of fig. 2.

The normal predicted motion vector mode derivation unit 401 derives a plurality of normal predicted motion vector candidates to select a predicted motion vector, and calculates the sum of the selected predicted motion vector and the decoded differential motion vector as a motion vector. The decoded inter prediction mode, reference index, and motion vector are inter prediction information of the normal prediction motion vector mode. The inter prediction information is supplied to the motion compensation prediction unit 406 via the switch 408. The detailed configuration and processing of the normal prediction motion vector mode deriving unit 401 will be described later.

The normal merge mode derivation unit 402 derives a plurality of normal merge candidates, selects a normal merge candidate, and obtains inter prediction information in the normal merge mode. The inter prediction information is supplied to the motion compensation prediction unit 406 via the switch 408. The detailed configuration and processing of the normal merge mode derivation unit 402 will be described later.

The sub-block motion vector prediction mode derivation unit 403 derives a plurality of sub-block motion vector prediction candidates, selects a sub-block motion vector prediction, and calculates the sum of the selected sub-block motion vector prediction and the decoded differential motion vector as a motion vector. The decoded inter prediction mode, reference index, and motion vector are inter prediction information of the sub-block prediction motion vector mode. The inter prediction information is supplied to the motion compensation prediction unit 406 via the switch 408.

The sub-block merging mode derivation unit 404 derives a plurality of sub-block merging candidates, selects a sub-block merging candidate, and obtains inter prediction information of the sub-block merging mode. The inter prediction information is supplied to the motion compensation prediction unit 406 via the switch 408.

The motion compensation prediction unit 406 performs inter prediction on the reference image signal stored in the decoded image memory 208 based on the determined inter prediction information. The detailed configuration and processing of the motion compensation prediction unit 406 are the same as those of the motion compensation prediction unit 306 on the encoding side.

< Normal prediction motion vector mode derivation unit (Normal AMVP) >

The normal predicted motion vector pattern derivation unit 301 in fig. 17 includes a spatial predicted motion vector candidate derivation unit 321, a temporal predicted motion vector candidate derivation unit 322, a historical predicted motion vector candidate derivation unit 323, a predicted motion vector candidate supplement unit 325, a normal motion vector detection unit 326, a predicted motion vector candidate selection unit 327, and a motion vector subtraction unit 328.

The normal predicted motion vector mode derivation unit 401 in fig. 23 includes a spatial predicted motion vector candidate derivation unit 421, a temporal predicted motion vector candidate derivation unit 422, a historical predicted motion vector candidate derivation unit 423, a predicted motion vector candidate supplement unit 425, a predicted motion vector candidate selection unit 426, and a motion vector addition unit 427.

The processing procedure of the encoding-side normal prediction motion vector pattern derivation unit 301 and the decoding-side normal prediction motion vector pattern derivation unit 401 will be described with reference to the flowcharts of fig. 19 and 25. Fig. 19 is a flowchart showing the procedure of the normal predictive motion vector pattern derivation process by the normal motion vector pattern derivation unit 301 on the encoding side, and fig. 25 is a flowchart showing the procedure of the normal predictive motion vector pattern derivation process by the normal motion vector pattern derivation unit 401 on the decoding side.

< normal predicted motion vector mode derivation unit (normal AMVP): description of encoding side >

The procedure of the normal predictive motion vector mode derivation processing on the encoding side will be described with reference to fig. 19. In the description of the processing steps in fig. 19, the term "normal" shown in fig. 19 may be omitted.

First, the normal motion vector detection unit 326 detects a normal motion vector for each inter prediction mode and reference index (step S100 in fig. 19).

Next, the spatial prediction motion vector candidate derivation section 321, the temporal prediction motion vector candidate derivation section 322, the historical prediction motion vector candidate derivation section 323, the prediction motion vector candidate complementation section 325, the prediction motion vector candidate selection section 327, and the motion vector subtraction section 328 calculate a differential motion vector of motion vectors used for inter-frame prediction in the normal prediction motion vector mode for each of L0 and L1 (steps S101 to S106 in fig. 19). Specifically, when the prediction MODE PredMode of the processing object block is INTER prediction (MODE _ INTER) and the INTER prediction MODE is L0 prediction (Pred _ L0), a predicted motion vector candidate list mvpListL0 of L0 is calculated, a predicted motion vector mvpL0 is selected, and a differential motion vector mvdL0 of a motion vector mvL0 of L0 is calculated. When the inter prediction mode of the processing object block is L1 prediction (Pred _ L1), a prediction motion vector candidate list mvpListL1 of L1 is calculated, a prediction motion vector mvpL1 is selected, and a differential motion vector mvdL1 of a motion vector mvL1 of L1 is calculated. When the inter prediction mode of the target block to be processed is double prediction (Pred _ BI), L0 prediction and L1 prediction are performed simultaneously, a prediction motion vector candidate list mvpListL0 of L0 is calculated, a prediction motion vector mvpL0 of L0 is selected, a differential motion vector mvdL0 of a motion vector mvL0 of L0 is calculated, a prediction motion vector candidate list mvpListL1 of L1 is calculated, a prediction motion vector mvpL1 of L1 is calculated, and differential motion vectors mvdL1 of a motion vector mvL1 of L1 are calculated, respectively.

The differential motion vector calculation processing is performed for each of L0 and L1, but L0 and L1 are common processing. Therefore, in the following description, L0 and L1 are denoted as common LX. In the process of calculating the differential motion vector of L0, X of LX is 0, and in the process of calculating the differential motion vector of L1, X of LX is 1. In addition, in the process of calculating the differential motion vector of LX, in the case of referring to information of another list without referring to LX, the other list is represented as LY.

In the case where the motion vector mvLX of LX is used (step S102: YES in FIG. 19), candidates for the predicted motion vector of LX are calculated, and a predicted motion vector candidate list mvpListLX of LX is constructed (step S103 in FIG. 19). The spatial predictive motion vector candidate derivation unit 321, the temporal predictive motion vector candidate derivation unit 322, the historical predictive motion vector candidate derivation unit 323, and the predictive motion vector candidate supplement unit 325 in the normal predictive motion vector mode derivation unit 301 derive a plurality of candidates of the predictive motion vector, and construct a predictive motion vector candidate list mvpListLX. The detailed processing procedure of step S103 in fig. 19 will be described later using the flowchart in fig. 20.

Next, the predicted motion vector candidate selection unit 327 selects the predicted motion vector mvpLX of LX from the predicted motion vector candidate list mvplsllx of LX (step S104 in fig. 19). Here, in the predicted motion vector candidate list mvpListLX, any one element (i-th element from 0) is represented as mvpListLX [ i ]. Respective differential motion vectors are calculated as differences between the motion vector mvLX and the candidate mvpListLX [ i ] of the respective predicted motion vectors held in the predicted motion vector candidate list mvpListLX. The coding amount when coding these differential motion vectors is calculated for each element (predicted motion vector candidate) of the predicted motion vector candidate list mvpListLX. Then, among the elements registered in the predicted motion vector candidate list mvpListLX, the candidate mvpListLX [ i ] of the predicted motion vector whose code amount of each candidate of the predicted motion vector is the smallest is selected as the predicted motion vector mvpLX, and the index i is acquired. When there are a plurality of candidates of a predicted motion vector that becomes the smallest generated code amount in the predicted motion vector candidate list mvpListLX, a candidate mvpListLX [ i ] of the predicted motion vector represented by a number with a small index i in the predicted motion vector candidate list mvpListLX is selected as the best predicted motion vector mvpLX, and the index i is acquired.

Next, the motion vector subtraction unit 328 subtracts the predicted motion vector mvpLX of the selected LX from the motion vector mvLX of the LX to set mvdLX to mvLX-mvpLX, thereby calculating the differential motion vector mvdLX of the LX (step S105 in fig. 19).

< normal predicted motion vector mode derivation unit (normal AMVP): description of decoding side >

Next, a procedure of the normal predictive motion vector mode processing on the decoding side will be described with reference to fig. 25. On the decoding side, the motion vector used for inter prediction in the normal prediction motion vector mode is calculated for each of L0 and L1 by the spatial prediction motion vector candidate derivation section 421, the temporal prediction motion vector candidate derivation section 422, the historical prediction motion vector candidate derivation section 423, and the prediction motion vector candidate supplementation section 425 (steps S201 to S206 in fig. 25). Specifically, when the prediction MODE PredMode of the processing object block is INTER prediction (MODE _ INTER) and the INTER prediction MODE of the processing object block is L0 prediction (Pred _ L0), a predicted motion vector candidate list mvpListL0 of L0 is calculated, a predicted motion vector mvpL0 is selected, and a motion vector mvL0 of L0 is calculated. When the inter prediction mode of the processing object block is L1 prediction (Pred _ L1), a prediction motion vector candidate list mvpListL1 of L1 is calculated, a prediction motion vector mvpL1 is selected, and a motion vector mvL1 of L1 is calculated. When the inter prediction mode of the processing target block is BI-prediction (Pred _ BI), L0 prediction and L1 prediction are performed simultaneously, a predicted motion vector candidate list mvpListL0 of L0 is calculated, a predicted motion vector mvpL0 of L0 is selected, a motion vector mvL0 of L0 is calculated, a predicted motion vector candidate list mvpListL1 of L1 is calculated, a predicted motion vector mvpL1 of L1 is calculated, and motion vectors mvL1 of L1 are calculated, respectively.

Similarly to the encoding side, the decoding side also performs motion vector calculation processing on L0 and L1, respectively, but L0 and L1 are common processing. Therefore, in the following description, L0 and L1 are denoted as common LX. LX denotes an inter prediction mode used for inter prediction of a coding block to be processed. In the process of calculating the motion vector of L0, X is 0, and in the process of calculating the motion vector of L1, X is 1. In addition, in the process of calculating the motion vector of the LX, in the case of referring to information of another reference list instead of referring to the same reference list as the LX to be calculated, the other reference list is represented as LY.

In the case where the motion vector mvLX of LX is used (step S202: YES in FIG. 25), candidates for the predicted motion vector of LX are calculated, and a predicted motion vector candidate list mvpListLX of LX is constructed (step S203 in FIG. 25). The spatial predictive motion vector candidate derivation section 421, the temporal predictive motion vector candidate derivation section 422, the historical predictive motion vector candidate derivation section 423, and the predictive motion vector candidate supplement section 425 in the normal predictive motion vector mode derivation section 401 calculate candidates of a plurality of predictive motion vectors, and construct a predictive motion vector candidate list mvpListLX. The detailed processing procedure of step S203 in fig. 25 will be described later using the flowchart in fig. 20.

Next, the predicted motion vector candidate selection unit 426 extracts, from the predicted motion vector candidate list mvplsllx, the candidate mvplslx [ mvpldxlx ] of the predicted motion vector corresponding to the index mvpldxlx of the predicted motion vector provided by decoding in the bit string decoding unit 201 as the selected predicted motion vector mvpLX (step S204 in fig. 25).

Next, the motion vector adder 427 adds the difference motion vector mvdLX of LX and the predicted motion vector mvpLX of LX decoded and supplied by the bit string decoder 201, and sets mvLX to mvpLX + mvdLX, thereby calculating the motion vector mvLX of LX (step S205 in fig. 25).

< normal predicted motion vector mode derivation unit (normal AMVP): method for predicting motion vector >

Fig. 20 is a flowchart showing a procedure of a normal predictive motion vector pattern derivation process having a function common to the normal predictive motion vector pattern derivation unit 301 of the image coding apparatus and the normal predictive motion vector pattern derivation unit 401 of the image decoding apparatus according to the embodiment of the present invention.

The normal prediction motion vector mode derivation unit 301 and the normal prediction motion vector mode derivation unit 401 have a prediction motion vector candidate list mvplsllx. The predicted motion vector candidate list mvplsllx has a list structure, and a storage area for storing, as elements, a predicted motion vector index indicating a position inside the predicted motion vector candidate list and a predicted motion vector candidate corresponding to the index. The number of the predicted motion vector index starts from 0, and the predicted motion vector candidate is held in the storage area of the predicted motion vector candidate list mvpListLX. In the present embodiment, it is assumed that the predicted motion vector candidate list mvplislx can register at least two predicted motion vector candidates (inter prediction information). Further, a variable numCurrMvpCand indicating the number of predicted motion vector candidates registered in the predicted motion vector candidate list mvplilx is set to 0.

The spatial prediction motion vector candidate derivation sections 321 and 421 derive candidates of a prediction motion vector from a block adjacent to the left side. In this process, the predicted motion vector mvLXA is derived with reference to the inter prediction information of the block adjacent to the left (a 0 or a1 in fig. 11), i.e., a flag indicating whether or not the predicted motion vector candidate can be used, the motion vector, a reference index, and the like, and the derived mvLXA is added to the predicted motion vector candidate list mvpListLX (step S301 in fig. 20). In the L0 prediction, X is 0, and in the L1 prediction, X is 1 (the same applies hereinafter). Next, the spatial prediction motion vector candidate derivation sections 321 and 421 derive candidates of a prediction motion vector from a block adjacent to the upper side. In this process, the predicted motion vector mvLXB is derived with reference to the inter prediction information of the block (B0, B1, or B2 of fig. 11) adjacent to the upper side, i.e., the flag indicating whether or not the predicted motion vector candidate can be used, and the motion vector, the reference index, and the like, and if the mvLXA and the mvLXB derived respectively are not equal, the mvLXB is added to the predicted motion vector candidate list mvpListLX (step S302 of fig. 20). The processing in steps S301 and S302 in fig. 20 is common except that the positions and the numbers of the reference adjacent blocks are different, and a flag availableFlagLXN indicating whether or not the predicted motion vector candidate of the coding block can be used, a motion vector mvLXN, and a reference index refIdxN are derived (N indicates a or B, the same applies hereinafter).

Next, the historical predicted motion vector candidate derivation parts 323 and 423 add the historical predicted motion vector candidates registered in the historical predicted motion vector candidate list HmvpCandList to the predicted motion vector candidate list mvplslx (step S303 of fig. 20). Details of the registration processing step in this step S303 will be described later using the flowchart of fig. 29.

Next, the temporal prediction motion vector candidate derivation units 322 and 422 derive candidates of a prediction motion vector from a block in an image temporally different from the current processing target image. In this process, a flag availability flag LXCol, a motion vector mvLXCol, a reference index refIdxCol, and a reference list listCol indicating whether or not predicted motion vector candidates of an encoding block of a picture at a different time can be used are derived, and mvLXCol is added to a predicted motion vector candidate list mvpListLX (step S304 of fig. 20).

Further, it is assumed that the processing of the temporal prediction motion vector candidate derivation parts 322 and 422 in units of a sequence (SPS), a picture (PPS), or a slice can be omitted.

Next, the predicted motion vector candidate supplementing sections 325 and 425 add the predicted motion vector candidate of a predetermined value such as (0, 0) before satisfying the predicted motion vector candidate list mvplsllx (S305 of fig. 20).

< Normal merging mode derivation section (Normal merging) >

The normal merge mode derivation unit 302 in fig. 18 includes a spatial merge candidate derivation unit 341, a temporal merge candidate derivation unit 342, an average merge candidate derivation unit 344, a history merge candidate derivation unit 345, a merge candidate supplementation unit 346, and a merge candidate selection unit 347.

The normal merge mode derivation section 402 in fig. 24 includes a spatial merge candidate derivation section 441, a temporal merge candidate derivation section 442, an average merge candidate derivation section 444, a history merge candidate derivation section 445, a merge candidate supplementation section 446, and a merge candidate selection section 447.

Fig. 21 is a flowchart illustrating a procedure of normal merge mode derivation processing having a function common to the normal merge mode derivation unit 302 of the image encoding apparatus and the normal merge mode derivation unit 402 of the image decoding apparatus according to the embodiment of the present invention.

Hereinafter, each process will be described in order. Note that, in the following description, unless otherwise specified, a case where the slice type slice _ type is a B slice will be described, but the present invention is also applicable to a P slice. However, in case that the slice type slice _ type is a P slice, since only L0 prediction (Pred _ L0) exists as an inter prediction mode, L1 prediction (Pred _ L1) and BI-prediction (Pred _ BI) do not exist. Therefore, the processing around L1 can be omitted.

The normal merge mode derivation unit 302 and the normal merge mode derivation unit 402 have a merge candidate list mergeCandList. The merge candidate list mergeCandList has a list structure including a merge index indicating a position inside the merge candidate list and a storage area storing the merge candidate corresponding to the index as an element. The number of the merge index starts from 0, and the merge candidate is held in the storage area of the merge candidate list mergeCandList. In the subsequent processing, it is assumed that the merge candidate of the merge index i registered in the merge candidate list mergecandList is represented by a mergeCandList [ i ]. In the present embodiment, it is assumed that the merge candidate list mergeCandList can register at least six merge candidates (inter prediction information). Then, 0 is set to a variable numcurrmemrgecand indicating the number of merge candidates registered in the merge candidate list mergeCandList.

The spatial merge candidate derivation section 341 and the spatial merge candidate derivation section 441 derive spatial merge candidates from blocks (B1, a1, B0, a0, and B2 in fig. 11) adjacent to the left and upper sides of the processing target block in the order of B1, a1, B0, a0, and B2 based on the encoding information stored in the encoding information storage memory 111 of the image encoding apparatus or the encoding information storage memory 205 of the image decoding apparatus, and register the derived spatial merge candidates in the merge candidate list merecandlist (step S401 in fig. 21). Here, N representing any one of the spatial merge candidates B1, a1, B0, a0, B2, or the temporal merge candidate Col is defined. A flag availableflag N indicating whether inter prediction information of the block N can be used as a spatial merge candidate, reference indices refIdxL0N and refIdxL1N of L1 of the reference index L0 of the spatial merge candidate N, an L0 prediction flag predflag L0N indicating whether L0 prediction is performed, an L1 prediction flag predflag L1N indicating whether L1 prediction is performed, a motion vector mvL0N of the L0, and a motion vector mvL1N of the L1 are derived. However, in the present embodiment, since the merge candidate is derived without referring to the inter prediction information of the block included in the coding block to be processed, the spatial merge candidate using the inter prediction information of the block included in the coding block to be processed is not derived. (B1, A1, B0, A0, B2 in FIG. 11)

Next, the temporal merging candidate derivation unit 342 and the temporal merging candidate derivation unit 442 derive temporal merging candidates from pictures at different times, and register the derived temporal merging candidates in the merging candidate list mergeCandList (step S402 in fig. 21). A flag availableflag Col indicating whether or not temporal merging candidates can be used, an L0 prediction flag predflag L0Col indicating whether or not L0 prediction of temporal merging candidates is performed, an L1 prediction flag predflag L1Col indicating whether or not L1 prediction is performed, and a motion vector mvL1Col of L0, mvL0Col and L1 are derived.

Note that the processing of the temporal merging candidate derivation unit 342 and the temporal merging candidate derivation unit 442 in units of a sequence (SPS), a picture (PPS), or a slice can be omitted.

Next, in the history merge candidate derivation part 345 and the history merge candidate derivation part 445, the history prediction motion vector candidates registered in the history prediction motion vector candidate list HmvpCandList are registered in the merge candidate list mergeCandList (step S403 in fig. 21).

Further, in the case where the merge candidate number numcurrmeasurcand registered in the merge candidate list mergeCandList is smaller than the maximum merge candidate number maxnummemrgecand, the merge candidate number numcurrmeasurcand registered in the merge candidate list mergeCandList derives a history merge candidate with the maximum merge candidate number maxnummemrgecand as an upper limit, and registers it in the merge candidate list mergeCandList.

Next, in the average merge candidate derivation part 344 and the average merge candidate derivation part 444, an average merge candidate is derived from the merge candidate list mergeCandList, and the derived average merge candidate is added to the merge candidate list mergeCandList (step S404 in fig. 21).

Further, in the case where the merge candidate number numcurrmeasurcand registered in the merge candidate list mergeCandList is smaller than the maximum merge candidate number maxnummemrgecand, the merge candidate number numcurrmeasurcand registered in the merge candidate list mergeCandList is upper-limited by the maximum merge candidate number maxnummemrgecand, an average merge candidate is derived, and is registered in the merge candidate list mergeCandList.

Here, the average merge candidate is a new merge candidate having a motion vector obtained by averaging the motion vectors possessed by the first merge candidate and the second merge candidate registered in the merge candidate list mergeecandlist in each of the L0 prediction and the L1 prediction.

Next, in the merge candidate supplementation part 346 and the merge candidate supplementation part 446, when the merge candidate number numcurrmemegacand registered in the merge candidate list mergeecandlist is smaller than the maximum merge candidate number maxnummemegand, the merge candidate number numcurrmemegand registered in the merge candidate list mergeecand derives the additional merge candidate with the maximum merge candidate number maxnummemegand as an upper limit, and registers the additional merge candidate in the merge candidate list mergeecandlist (step S405 of fig. 21). With the maximum merge candidate number MaxNumMergeCand as an upper limit, a merge candidate for L0 prediction (Pred _ L0) is added to the P slice in which the prediction mode in which the motion vector has a (0, 0) value. In the B slice, a prediction mode in which a motion vector has a value of (0, 0) is added as a merging candidate for BI-prediction (Pred _ BI). The reference index when the merge candidate is added is different from the reference index that has been added.

Next, the merge candidate selector 347 and the merge candidate selector 447 select a merge candidate from among the merge candidates registered in the merge candidate list mergeCandList. The merge candidate selector 347 on the encoding side selects a merge candidate by calculating the amount of code and the amount of distortion, and supplies the merge index indicating the selected merge candidate and the inter prediction information of the merge candidate to the motion compensation predictor 306 via the inter prediction mode determiner 305. On the other hand, the merge candidate selection unit 447 on the decoding side selects a merge candidate based on the decoded merge index, and supplies the selected merge candidate to the motion compensation prediction unit 406.

< update of historical predicted motion vector candidate list >

Next, the initialization method and the update method of the history predicted motion vector candidate list hmvpandlist included in the encoding-side encoding information storage memory 111 and the decoding-side encoding information storage memory 205 will be described in detail. Fig. 26 is a flowchart for explaining the history prediction motion vector candidate list initialization/update processing steps.

In the present embodiment, it is assumed that the update of the historical predicted motion vector candidate list hmvpandlist is performed in the coding information storage memory 111 and the coding information storage memory 205. The inter prediction unit 102 and the inter prediction unit 203 may be provided with a history prediction motion vector candidate list update unit to update the history prediction motion vector candidate list hmvpandlist.

The historical predicted motion vector candidate list HmvpCandList is initially set at the head of the slice, and when the normal predicted motion vector mode or the normal merge mode is selected by the prediction method determination unit 105 on the encoding side, the historical predicted motion vector candidate list HmvpCandList is updated, and when the prediction information decoded by the bit string decoding unit 201 is the normal predicted motion vector mode or the normal merge mode, the historical predicted motion vector candidate list HmvpCandList is updated on the decoding side.

Inter prediction information used when inter prediction is performed in the normal prediction motion vector mode or the normal merge mode is registered in the history prediction motion vector candidate list hmvpcrst as an inter prediction information candidate hmvpcrnd. The inter prediction information candidate hmvpland includes reference indexes refIdxL1 of reference indexes refIdxL0 and L1 of L0, a L0 prediction flag predflag L0 indicating whether or not L0 prediction is performed, and motion vectors mvL1 of motion vectors mvL0 and L1 of L1 prediction flags predflag L1, L0 indicating whether or not L1 prediction is performed.

When inter-prediction information having the same value as the inter-prediction information candidate hmvpland exists among the elements (i.e., inter-prediction information) registered in the history prediction motion vector candidate list hmvpland in the encoding-side encoding information storage memory 111 and the decoding-side encoding information storage memory 205, the elements are deleted from the history prediction motion vector candidate list hmvpland. On the other hand, in the case where there is no inter prediction information of the same value as the inter prediction information candidate hmvpcad, the element at the beginning of the history prediction motion vector candidate list hmvpcad is deleted, and the inter prediction information candidate hmvpcad is added to the end of the history prediction motion vector candidate list hmvpcad.

The number of elements of the history predicted motion vector candidate list hmvpandlist included in the encoding-side encoding information storage memory 111 and the decoding-side encoding information storage memory 205 of the present invention is set to 6.

First, the history prediction motion vector candidate list hmvpandlist is initialized in slice units (step S2101 of fig. 26). At the head of the slice, all elements of the history prediction motion vector candidate list HmvpCandList are set to null, and the value of the history prediction motion vector candidate number (current candidate number) numhmvpland registered in the history prediction motion vector candidate list HmvpCandList is set to 0.

Note that, although it is assumed that the initialization of the history prediction motion vector candidate list HmvpCandList is performed in slice units (first encoding blocks of slices), it may be performed in picture units, rectangle (tile) units, or tree block row units.

Next, the following process of updating the historical predicted motion vector candidate list hmvpandlist is repeated for each coding block in the slice (steps S2102 to S2111 in fig. 26).

First, initial setting is performed in units of code blocks. A FALSE value is set to the flag indicating whether or not the same candidate exists, and "0" is set to the deletion target index removeIdx indicating the candidate of the deletion target (step S2103 in fig. 26).

It is determined whether or not the inter prediction information candidate hmvpland to be registered exists (step S2104 of fig. 26). When the encoding-side prediction method determination unit 105 determines that the motion vector mode is the normal prediction motion vector mode or the normal merge mode, or when the bit string decoding unit 201 decodes the motion vector mode into the normal prediction motion vector mode or the normal merge mode, the inter prediction information is set as the inter prediction information candidate hmvpand to be registered. When the prediction method determination unit 105 on the encoding side determines that the intra prediction mode, the sub block prediction motion vector mode, or the sub block merge mode is used, or when the bit string decoding unit 201 on the decoding side decodes the intra prediction mode, the sub block prediction motion vector mode, or the sub block merge mode, the update process of the historical prediction motion vector candidate list hMvpCand is not performed, and the inter prediction information candidate hmvpland to be registered does not exist. If there is no registration target inter-frame prediction information candidate hmvpland, steps S2105 to S2106 are skipped (no in step S2104 of fig. 26). If the inter-frame prediction information candidate hmvpland to be registered exists, the processing after step S2105 is executed (yes in step S2104 of fig. 26).

Next, it is determined whether or not the same value element (inter prediction information) as the inter prediction information candidate hmvpland to be registered exists among the elements of the historical predicted motion vector candidate list HmvpCandList, that is, whether or not the same element exists (step S2105 in fig. 26). Fig. 27 is a flowchart of the same element confirmation processing procedure. If the number of historical predicted motion vector candidates numhmmvpcand has a value of 0 (no in step S2121 of fig. 27), the historical predicted motion vector candidate list hmvpandlist is empty, and since there are no identical candidates, steps S2122 to S2125 of fig. 27 are skipped to complete the identical element confirmation processing step. If the number of historical predicted motion vector candidates numhmvppcand is greater than 0 (yes in step S2121 of fig. 27), the historical predicted motion vector index hMvpIdx is from 0 to numhmvppcand-1, and the process of step S2123 is repeated (steps S2122 to S2125 of fig. 27). First, whether the hMvpIdx-th element hmvpandlist [ hMvpIdx ] from 0 of the historical predicted motion vector candidate list is the same as the inter-prediction information candidate hmvpand is compared (step S2123 of fig. 27). If they are the same (yes in step S2123 of fig. 27), the value of TRUE is set to the flag indicating whether or not there is a match candidate, the value of the current historical predicted motion vector index hMvpIdx is set to the deletion target index removeIdx indicating the position of the deletion target element, and the same element confirmation processing is ended. If they are not the same (step S2123: NO in FIG. 27), the hMvpidx is increased by 1, and if the historical predicted motion vector index hMvpidx is not more than NumHmvpCand-1, the processing from step S2123 onward is performed.

Returning again to the flowchart of fig. 26, the shift and addition processing of the elements of the historical predicted motion vector candidate list hmvpandlist is performed (step S2106 of fig. 26). Fig. 28 is a flowchart of the element shift/addition processing step of the history prediction motion vector candidate list hmvpandlist of step S2106 of fig. 26. First, it is determined whether to add a new element after removing an element stored in the history prediction motion vector candidate list hmvpandlist or to add a new element without removing an element. Specifically, whether the flag indicating whether there is the same candidate is TRUE or not is compared with whether or not TRUE or 6 is numhmmvvpcsand (step S2141 of fig. 28). When either a condition that a flag indicating whether or not the same candidate exists is TRUE or the current number of candidates numhmpcandis 6 is satisfied (step S2141: yes in fig. 28), the element stored in the historical predicted motion vector candidate list hmvpandlist is removed and a new element is added. The initial value of index i is set to the value of removeIdx + 1. From this initial value to numhmvppcand, the element shift processing of step S2143 is repeated. (steps S2142 to S2144 in FIG. 28). Elements of HmvpCandList [ i ] are copied to HmvpCandList [ i-1], and the elements are shifted forward (step S2143 in FIG. 28), and i is increased by 1 (steps S2142 to S2144 in FIG. 28). Next, the interframe prediction information candidate hmmvpcand is added to the (numhmmvpcand-1) th hmmvpcandlist [ numhmmvpcand-1 ] starting from 0 corresponding to the last of the history prediction motion vector candidate list (step S2145 of fig. 28), and the element shift/addition process of the history prediction motion vector candidate list hmmvpcandlist is ended. On the other hand, if neither of the conditions of TRUE flag indicating whether or not the same candidate exists and 6 numhmvpexist (step S2141 in fig. 28: no), the inter prediction information candidate hmvpexist is added to the end of the history prediction motion vector candidate list without removing the elements stored in the history prediction motion vector candidate list hMvpCand (step S2146 in fig. 28). Here, the last of the historical predicted motion vector candidate list is the numhmmvpcand hmvpandlist [ numhmvpland ] starting from 0. Further, numhmpcland is increased by 1, and the process of shifting and adding the elements of the history prediction motion vector candidate list hmvpandlist is ended.

Fig. 31 is a diagram for explaining an example of the update process of the historical predicted motion vector candidate list. When a new element is added to the history predicted motion vector candidate list hmvpandlist in which six elements (inter prediction information) are registered, the new element is compared with the new inter prediction information in order from the element before the history predicted motion vector candidate list hmmvpcandlist (fig. 31A), if the new element is the same value as the element HMVP2 third from the beginning of the history predicted motion vector candidate list hmmvpcandlist, the element HMVP2 is deleted from the history predicted motion vector candidate list hmmvpcandlist, the elements HMVP3 to HMVP5 after are shifted (copied) one by one to the front, and the new element is added to the last of the history predicted motion vector candidate list hmmvpcandlist (fig. 31B), thereby completing the update of the history predicted motion vector candidate list hmvpandlist hmpcandlist (fig. 31C).

< historical predicted motion vector candidate derivation processing >

Next, a method of deriving a motion vector candidate for historical prediction from the motion vector candidate list HmvpCandList will be described in detail as a processing step of step S304 in fig. 20, and the processing step of step S304 in fig. 20 is processing common to the motion vector candidate derivation unit 323 in the normal prediction motion vector mode derivation unit 301 on the encoding side and the motion vector candidate derivation unit 423 in the normal prediction motion vector mode derivation unit 401 on the decoding side. Fig. 29 is a flowchart illustrating the procedure of the history prediction motion vector candidate derivation processing.

If the current predicted motion vector candidate number numpredictor mvpcand is equal to or greater than the maximum number of elements (here, 2) of the predicted motion vector candidate list mvplsllx or the value of the historical predicted motion vector candidate number numhmmvpcand is 0 (step S2201: no in fig. 29), the processing from steps S2202 to S2209 in fig. 29 is omitted, and the historical predicted motion vector candidate derivation processing step ends. When the current predicted motion vector candidate number numCurrMvpCand is less than the maximum element number 2 of the predicted motion vector candidate list mvplsllx and the value of the historical predicted motion vector candidate number numhmmvpcand is greater than 0 (step S2201: yes in fig. 29), the processes of steps S2202 to S2209 in fig. 29 are executed.

Next, the processing of steps S2203 to S2208 of fig. 29 is repeated until the index i is smaller than any one of the index i from 1 to 4 and the historical predicted motion vector candidate number numceckedhmvpcand (steps S2202 to S2209 of fig. 29). If the current predicted motion vector candidate number numpredictor mvpcand is equal to or greater than 2, which is the maximum number of elements of the predicted motion vector candidate list mvpListLX (no in step S2203 of fig. 29), the processing in steps S2204 to S2209 of fig. 29 is omitted, and the historical predicted motion vector candidate derivation processing step is ended. In the case where the current predicted motion vector candidate number numCurrMvpCand is less than the maximum element number 2 of the predicted motion vector candidate list mvpListLX (step S2203: yes in fig. 29), the processes after step S2204 in fig. 29 are performed.

Next, the processing from steps S2205 to S2207 is performed for Y of 0 and 1(L0 and L1), respectively (steps S2204 to S2208 of fig. 29). If the current predicted motion vector candidate number numpredictor mvpcand is equal to or greater than 2, which is the maximum number of elements of the predicted motion vector candidate list mvpListLX (no in step S2205 in fig. 29), the processing in steps S2206 to S2209 in fig. 29 is omitted, and the historical predicted motion vector candidate derivation processing step is ended. In the case where the current predicted motion vector candidate number numCurrMvpCand is less than the maximum element number 2 of the predicted motion vector candidate list mvpListLX (step S2205: yes in fig. 29), the processes subsequent to step S2206 in fig. 29 are performed.

Next, in the history prediction motion vector candidate list hmvrpcandlist, when the element is the same reference index as the reference index refIdxLX of the encoding/decoding target motion vector and is an element different from any element of the prediction motion vector list mvlistlx (yes in step S2206 of fig. 29), the motion vector of LY of the history prediction motion vector candidate hmpcandlist [ numrmmvpcand-i ] is added to the element mvlistlx [ numcrmvpcand ] of nummrmvpcand list starting from 0 of the prediction motion vector candidate list (step S2207 of fig. 29), and the current prediction motion vector candidate nummrmvpcand is increased by 1. In the case where there is no element of the same reference index as the reference index refIdxLX of the encoding/decoding target motion vector in the history prediction motion vector candidate list hmvpandlist and no element different from any element of the prediction motion vector list mvpListLX (no in step S2206 of fig. 29), the addition processing in step S2207 is skipped.

The above processing of steps S2205 to S2207 of fig. 29 (steps S2204 to S2208 of fig. 29) is performed in both L0 and L1. If the index i is increased by 1 and the index i is equal to or less than 4 and the number of historical predicted motion vector candidates numhmvpland is small, the processing from step S2203 onward is performed again (steps S2202 to S2209 in fig. 29).

< history merge candidate derivation processing >

Next, a method of deriving a history merge candidate from the history merge candidate list hmvpandlist, which is a processing step of step S404 of fig. 21, which is processing common to the history merge candidate derivation unit 345 of the normal merge mode derivation unit 302 on the encoding side and the history merge candidate derivation unit 445 of the normal merge mode derivation unit 402 on the decoding side, will be described in detail. Fig. 30 is a flowchart illustrating the history merge candidate derivation processing step.

First, initialization processing is performed (step S2301 in fig. 30). A FALSE value is set for each of the elements from 0 to the (numcurrMergeCand-1) th element of ispired [ i ], and the number of elements numcurrMergeCand registered in the current merge candidate list is set for the variable numOrigMergeCand.

Next, the initial value of the index hMvpIdx is set to 1, and the addition processing from step S2303 to step S2310 in fig. 30 is repeated from this initial value to numhmvppcand (steps S2302 to S2311 in fig. 30). If the number of elements numcurmergercargecand registered in the current merge candidate list is not (maximum merge candidate number MaxNumMergeCand-1) or less, the history merge candidate derivation process is ended because merge candidates are added to all elements in the merge candidate list (step S2303 of fig. 30: no). If the number of elements numcurmergercargecand registered in the current merge candidate list is equal to or less than (maximum merge candidate number MaxNumMergeCand-1), the processing from step S2304 onward is executed. A FALSE value is set for sameMotion (step S2304 in fig. 30). Next, the initial value of the index i is set to 0, and the processing of steps S2306 and S2307 in fig. 30 is performed from this initial value to numOrigMergeCand-1 (S2305 to S2308 in fig. 30). Whether or not the element hmvpandlist [ numhmvppcand-hMvpIdx ] of the ith from 0 of the past motion vector prediction candidate list is the same value as the element mergeCandList [ i ] of the ith from 0 of the merge candidate list is compared (step S2306 of fig. 30).

The identical value of the merge candidates means that the merge candidates are identical when the values of all the components (inter prediction mode, reference index, and motion vector) of the merge candidates are identical. If the merge candidates are the same value and ispred [ i ] is FALSE (yes in step S2306 in fig. 30), both sameMotion and ispred [ i ] are set to TRUE (step S2307 in fig. 30). If not (no in step S2306 of fig. 30), the process of step S2307 is skipped. After the repetition process of steps S2305 to S2308 of fig. 30 is completed, it is compared whether sameMotio N is FALSE (step S2309 of fig. 30), and in the case where sameMotion is FALSE (step S2309: yes of fig. 30), since the (numhmvppcand-hMvpIdx) th element hmvpandlist [ N umHvpCand-hMvpIdx ] from 0 of the history prediction motion vector candidate list does not exist in the mergetcandlist, the (numhmmvpcand-hMvpIdx) th element hmmvandlist from 0 of the history prediction motion vector candidate list is added to the (numhmvmncargecand [ numurvmidcand ] of the nth umcurrmerge candidate list, and the (numhmmvpcidx) number hMvpIdx from 0 of the history prediction motion vector candidate list is added to the (numhmmvpcandvmjnex) hmvcandlist [ hmvmjnadlist ], and the map is increased 2310 (step S2310). The index hMvpIdx is incremented by 1 (step S2302 in fig. 30), and the process of steps S2302 to S2311 in fig. 30 is repeated.

After completion of the confirmation of all the elements in the history predicted motion vector candidate list or the addition of the merge candidate to all the elements in the merge candidate list, the derivation processing of the history merge candidate is completed.

< motion compensated prediction processing >

The motion compensation prediction unit 306 acquires the position and size of the block to be subjected to the current prediction processing during encoding. The motion compensation prediction unit 306 acquires inter prediction information from the inter prediction mode determination unit 305. A reference index and a motion vector are derived from the acquired inter-prediction information, and a prediction signal is generated after acquiring an image signal in which a reference image specified by the reference index in the decoded image memory 104 is moved by the motion vector amount from the same position as the image signal of the prediction block.

When the inter prediction mode in the inter prediction is prediction from a single reference picture, such as L0 prediction or L1 prediction, a prediction signal obtained from one reference picture is used as a motion compensated prediction signal, and when the inter prediction mode is prediction from two reference pictures, such as BI prediction, a signal obtained by weighted averaging the prediction signals obtained from the two reference pictures is used as a motion compensated prediction signal, and the motion compensated prediction signal is supplied to the prediction method determination unit 105. Here, the ratio of the weighted average of the bi-prediction is set to 1: 1, but the weighted average may be performed using another ratio. For example, the weighting ratio may be set to be larger as the picture interval between the picture to be predicted and the reference picture is closer. Further, the calculation of the weighting ratio may be performed using a correspondence table of the combination of the picture intervals and the weighting ratio.

The motion compensation prediction unit 406 has the same function as the motion compensation prediction unit 306 on the encoding side. The motion compensation prediction unit 406 acquires inter prediction information from the normal prediction motion vector mode derivation unit 401, the normal merge mode derivation unit 402, the sub-block prediction motion vector mode derivation unit 403, and the sub-block merge mode derivation unit 404 via the switch 408. The motion compensation prediction unit 406 supplies the obtained motion compensation prediction signal to the decoded image signal superimposing unit 207.

< regarding inter prediction mode >

A process of performing prediction from a single reference picture is defined as mono prediction. In the case of uni-prediction, prediction using either one of two reference pictures registered in the reference list L0 or L1, such as L0 prediction or L1 prediction, is performed.

Fig. 32 shows a case where the reference picture (RefL0Pic) of L0 in the uni-prediction is at a time before the processing target picture (CurPic). Fig. 33 shows a case where the reference picture predicted by L0 in the uni-prediction is at a time after the processing target picture. Similarly, uni-prediction can be performed by replacing the reference picture predicted by L0 in fig. 32 and 33 with the reference picture predicted by L1 (RefL1 Pic).

A process of performing prediction from two reference pictures is defined as BI-prediction, and in the case of BI-prediction, BI-prediction is expressed using both L0 prediction and L1 prediction. Fig. 34 shows a case where the reference picture predicted by L0 in bi-prediction is at a time before the processing target picture, and the reference picture predicted by L1 is at a time after the processing target picture. Fig. 35 shows a case where the L0 predicted reference picture and the L1 predicted reference picture in bi-prediction are at a time before the processing target picture. Fig. 36 shows a case where the L0 predicted reference picture and the L1 predicted reference picture in bi-prediction are at a time after the processing target picture.

In this way, the relationship between the prediction category of L0/L1 and time can be used when L0 is not limited to the past direction and L1 is not limited to the future direction. In addition, in the case of bi-prediction, each of L0 prediction and L1 prediction may be performed using the same reference picture. Further, it is determined whether the motion compensation prediction is performed by the uni-prediction or the bi-prediction based on information (e.g., flag) indicating whether the L0 prediction is used and whether the L1 prediction is used.

< with respect to reference index >

In the embodiments of the present invention, in order to improve the accuracy of motion compensated prediction, it is possible to select an optimal reference picture from a plurality of reference pictures in motion compensated prediction. Therefore, a reference picture utilized in motion compensated prediction is used as a reference index, and the reference index is encoded into a bitstream together with a differential motion vector.

< motion compensation processing based on the normal prediction motion vector mode >

As shown in the inter prediction unit 102 on the encoding side in fig. 16, when the inter prediction information from the normal prediction motion vector mode derivation unit 301 is selected by the inter prediction mode determination unit 305, the motion compensation prediction unit 306 acquires the inter prediction information from the inter prediction mode determination unit 305, derives the inter prediction mode, the reference index, and the motion vector of the block to be currently processed, and generates a motion compensation prediction signal. The generated motion compensated prediction signal is supplied to the prediction method determination section 105.

Similarly, as shown in the inter prediction unit 203 on the decoding side of fig. 22, when the switch 408 is connected to the normal prediction motion vector mode derivation unit 401 during decoding, the motion compensation prediction unit 406 acquires inter prediction information based on the normal prediction motion vector mode derivation unit 401, derives an inter prediction mode, a reference index, and a motion vector of a block to be currently processed, and generates a motion compensation prediction signal. The generated motion-compensated prediction signal is supplied to the decoded image signal superimposing section 207.

< motion compensation processing based on normal merge mode >

As also shown in the inter prediction unit 102 on the encoding side of fig. 16, when the inter prediction information from the normal merge mode derivation unit 302 is selected by the inter prediction mode determination unit 305, the motion compensation prediction unit 306 acquires the inter prediction information from the inter prediction mode determination unit 305, derives the inter prediction mode, the reference index, and the motion vector of the block to be currently processed, and generates a motion compensation prediction signal. The generated motion compensated prediction signal is supplied to the prediction method determination section 105.

Similarly, as shown in the inter prediction unit 203 on the decoding side of fig. 22, when the switch 408 is connected to the normal merge mode derivation unit 402 during decoding, the motion compensation prediction unit 406 acquires inter prediction information from the normal merge mode derivation unit 402, derives an inter prediction mode, a reference index, and a motion vector of a block to be currently processed, and generates a motion compensation prediction signal. The generated motion-compensated prediction signal is supplied to the decoded image signal superimposing section 207.

< motion compensation processing based on sub-block prediction motion vector mode >

As also shown in the inter prediction unit 102 on the encoding side of fig. 16, when the inter prediction mode determination unit 305 selects the inter prediction information by the sub-block prediction motion vector mode derivation unit 303, the motion compensation prediction unit 306 acquires the inter prediction information from the inter prediction mode determination unit 305, derives the inter prediction mode, the reference index, and the motion vector of the block to be currently processed, and generates a motion compensation prediction signal. The generated motion compensated prediction signal is supplied to the prediction method determination section 105.

Similarly, as shown in the inter prediction unit 203 on the decoding side of fig. 22, when the switch 408 is connected to the sub-block predicted motion vector mode derivation unit 403 during decoding, the motion compensation prediction unit 406 acquires inter prediction information based on the sub-block predicted motion vector mode derivation unit 403, derives an inter prediction mode, a reference index, and a motion vector of a block to be currently processed, and generates a motion compensation prediction signal. The generated motion-compensated prediction signal is supplied to the decoded image signal superimposing section 207.

< motion compensation processing based on subblock merge mode >

As also shown in the inter prediction unit 102 on the encoding side of fig. 16, when the inter prediction mode determination unit 305 selects the inter prediction information by the sub-block merging mode derivation unit 304, the motion compensation prediction unit 306 acquires the inter prediction information from the inter prediction mode determination unit 305, derives the inter prediction mode, the reference index, and the motion vector of the block to be currently processed, and generates a motion compensation prediction signal. The generated motion compensated prediction signal is supplied to the prediction method determination section 105.

Similarly, as shown in the inter prediction unit 203 on the decoding side of fig. 22, when the switch 408 is connected to the sub-block merging mode derivation unit 404 during decoding, the motion compensation prediction unit 406 acquires inter prediction information based on the sub-block merging mode derivation unit 404, derives an inter prediction mode, a reference index, and a motion vector of a block to be currently processed, and generates a motion compensation prediction signal. The generated motion-compensated prediction signal is supplied to the decoded image signal superimposing section 207.

< motion compensation processing based on affine transformation prediction >

In the normal prediction motion vector mode and the normal merge mode, affine model-based motion compensation can be used based on the following flags. The following flag is reflected in the following flag based on the inter prediction condition determined by the inter prediction mode determination unit 305 in the encoding process, and is encoded in the bitstream. In the decoding process, whether to perform affine model-based motion compensation is determined based on the following flags in the bitstream.

sps _ affine _ enabled _ flag indicates whether affine model based motion compensation can be used in inter prediction. If sps _ affine _ enabled _ flag is 0, suppression is performed in units of a sequence so as not to be affine model-based motion compensation. In addition, inter _ affine _ flag and CU _ affine _ type _ flag are not transmitted in the CU (coding block) syntax of the coded video sequence. If the sps _ affine _ enabled _ flag is 1, affine model based motion compensation can be used in encoding the video sequence.

The sps _ affine _ type _ flag indicates whether motion compensation based on a six-parameter affine model can be used in inter prediction. If sps _ affine _ type _ flag is 0, then motion compensation that is not based on a six-parameter affine model is suppressed. In addition, CU _ affine _ type _ flag is not transmitted in the CU syntax of the encoded video sequence. If sps _ affine _ type _ flag is 1, then motion compensation based on a six-parameter affine model can be used in encoding the video sequence. In the case where there is no sps _ affine _ type _ flag, it is set to 0.

In the case of decoding a P slice or a B slice, if inter _ affine _ flag is 1 in a CU that is a current processing target, a motion compensation prediction signal of the CU that is the current processing target is generated using motion compensation based on an affine model. If inter _ affine _ flag is 0, the affine model is not used for the CU that is the current processing object. If there is no inter _ affine _ flag, it is set to 0.

In the case of decoding a P slice or a B slice, in a CU that becomes a current processing target, if CU _ affine _ type _ flag is 1, a motion compensation prediction signal of the CU that becomes the current processing target is generated using motion compensation based on a six-parameter affine model. If CU _ affine _ type _ flag is 0, motion compensation based on a four-parameter affine model is used to generate a motion compensated prediction signal of the CU that is the current processing object.

In the affine model-based motion compensation, since a reference index or a motion vector is derived in units of sub-blocks, a motion compensation prediction signal is generated in units of sub-blocks using a reference index or a motion vector to be processed.

The four-parameter affine model is the following pattern: the motion vector of the sub-block is derived from the four parameters of the horizontal component and the vertical component of the motion vector of each of the two control points, and motion compensation is performed on a sub-block basis.

In the present embodiment, in deriving the predicted motion vector candidate list in the normal predicted motion vector mode, candidates are added in the order of the spatial predicted motion vector candidate, the historical predicted motion vector candidate, and the temporal predicted motion vector candidate. With such a configuration, the following effects can be obtained.

1. In the historical predicted motion vector candidate derivation process, the same element confirmation step is performed for elements that have been added to the predicted motion vector candidate list and elements in the historical predicted motion vector candidate list, and elements in the historical predicted motion vector candidate list are added to the predicted motion vector candidate list only in the case where they are not the same, thus ensuring that the predicted motion vector candidate lists have different elements, respectively. Further, the spatial prediction motion vector candidate using the spatial correlation and the historical prediction motion vector candidate using the processing history have different characteristics, respectively. Therefore, the possibility that a plurality of predicted motion vector candidates having different characteristics can be provided increases, and the encoding efficiency can be improved.

2. The historical predicted motion vector candidate derivation process performs the same element confirmation as the spatial predicted motion vector candidate, but does not perform the same element confirmation as the temporal predicted motion vector candidate. Therefore, the number of times of confirmation of the same element can be limited, and thus the processing load related to derivation of the predicted motion vector candidate list can be reduced.

3. The temporal prediction motion vector candidate derivation process does not perform the same element verification as the spatial prediction motion vector candidate and the historical prediction motion vector candidate. Thus, the historical predicted motion vector candidate and the temporal predicted motion vector candidate may be derived independently. An improvement in throughput based on parallel processing can be achieved.

(second embodiment)

In the second embodiment, in the generation of the predicted motion vector candidate list in the normal predicted motion vector mode, the temporal predicted motion vector candidate is not derived, but candidates are added in the order of the spatial predicted motion vector candidate and the historical predicted motion vector candidate.

Fig. 38 is a block diagram showing the detailed configuration of the normal predicted motion vector mode derivation unit 301 in fig. 16 according to the second embodiment.

Fig. 39 is a block diagram showing the detailed configuration of the normal predictive motion vector mode derivation unit 401 in fig. 22 according to the second embodiment.

In the second embodiment, the predicted motion vector candidate list is generated without deriving the temporal predicted motion vector candidate, so that the processing load can be reduced. In the normal predicted motion vector mode, the predicted motion vector candidate list is sufficiently filled with the historical predicted motion vector candidates, and therefore, the encoding efficiency is not lowered.

(third embodiment)

In the third embodiment, in the generation of the predicted motion vector candidate list in the normal predicted motion vector mode, candidates are added in the order of the spatial predicted motion vector candidate, the temporal predicted motion vector candidate, and the historical predicted motion vector candidate. Here, in the historical predicted motion vector candidate derivation process, the same elements as those of the spatial predicted motion vector candidate and the temporal predicted motion vector candidate are not checked.

Fig. 40 is a block diagram showing the detailed configuration of the normal predicted motion vector mode derivation unit 301 in fig. 16 according to the third embodiment.

Fig. 41 is a block diagram showing the detailed configuration of the normal predicted motion vector mode derivation unit 401 in fig. 22 according to the third embodiment.

In the third embodiment, as in the first embodiment, the number of times of confirmation of the same element can be limited, and thus the processing load related to derivation of the predicted motion vector candidate list can be reduced. Further, by adding the temporally predicted motion vector candidate to the predicted motion vector candidate list in a higher order than the historically predicted motion vector candidate, it is possible to generate the predicted motion vector candidate list with high encoding efficiency by giving priority to the temporally predicted motion vector candidate with high encoding efficiency over the historically predicted motion vector candidate without performing the same element check of the predicted motion vector between the candidates of different types (spatial predicted motion vector candidate, temporal predicted motion vector candidate, historically predicted motion vector candidate) to suppress the processing load.

A plurality of the above-described embodiments may be combined.

In all the embodiments described above, the bit stream output by the image encoding apparatus has a specific data format so as to be able to be decoded according to the encoding method used in the embodiments. Further, the image decoding device corresponding to the image encoding device can decode the bit stream of the specific data format.

In the case of using a wired or wireless network for exchanging a bit stream between an image encoding apparatus and an image decoding apparatus, the bit stream may be converted into a data format suitable for a transmission form of a communication line for transmission. In this case, there are provided: a transmission device that converts the bit stream output from the image encoding device into encoded data in a data format suitable for a transmission format of a communication line and transmits the encoded data to a network; and a receiving device that receives encoded data from the network, restores the encoded data to a bit stream, and supplies the bit stream to the image decoding device. The transmission device includes: a memory for buffering a bit stream output from the image encoding apparatus; a packet processing unit for grouping bit streams; and a transmitting unit that transmits the encoded data grouped via the network. The receiving apparatus includes: a receiving unit that receives encoded data that has been grouped via a network; a memory for buffering the received encoded data; and a packet processing unit that performs packet processing on the encoded data to generate a bit stream and supplies the bit stream to the image decoding device.

In addition, a display unit for displaying the image decoded by the image decoding apparatus may be added to the configuration as the display apparatus. In this case, the display section reads out the decoded image signal generated by the decoded image signal superimposing section 207 and stored in the decoded image memory 208, and displays it on the screen.

In addition, the imaging unit may be added to the configuration, and the captured image may be input to the image coding apparatus as an imaging apparatus. In this case, the image pickup section inputs the picked-up image signal to the block division section 101.

Fig. 37 shows an example of the hardware configuration of the codec device according to this embodiment. The encoding/decoding device includes the configurations of the image encoding device and the image decoding device according to the embodiments of the present invention. The codec 9000 includes a CPU 9001, a codec IC9002, an I/O interface 9003, a memory 9004, an optical disk drive 9005, a network interface 9006, and a video interface 9009, and these units are connected by a bus 9010.

The image encoding unit 9007 and the image decoding unit 9008 are typically mounted as a codec IC 9002. The image encoding process of the image encoding device according to the embodiment of the present invention is executed by the image encoding unit 9007, and the image decoding process of the image decoding device according to the embodiment of the present invention is executed by the image decoding unit 9008. The I/O interface 9003 is implemented by a USB interface, for example, and is connected to an external keyboard 9104, a mouse 9105, and the like. The CPU 9001 controls the codec device 9000 to execute an action desired by a user based on a user operation input through the I/O interface 9003. Operations performed by the user via the keyboard 9104, the mouse 9105, and the like include selection of a function of executing either encoding or decoding, setting of encoding quality, input/output destinations of a bitstream, input/output destinations of an image, and the like.

When a user wishes to perform an operation of reproducing an image recorded in the disk recording medium 9100, the optical disk drive 9005 reads out a bitstream from the inserted disk recording medium 9100 and transmits the read bitstream to the image decoding portion 9008 of the codec IC9002 via the bus 9010. The image decoding unit 9008 performs image decoding processing in the image decoding apparatus according to the embodiment of the present invention on the input bit stream, and transmits the decoded image to the external monitor 9103 via the video interface 9009. Further, the codec 9000 has a network interface 9006, and is connectable to an external distribution server 9106 and a mobile terminal 9107 via a network 9101. When the user wishes to reproduce an image recorded on the distribution server 9106 or the mobile terminal 9107 instead of an image recorded on the disk recording medium 9100, the network interface 9006 acquires a bitstream from the network 9101 instead of reading out the bitstream from the input disk recording medium 9100. When the user desires to reproduce an image recorded in the memory 9004, the image decoding process in the image decoding apparatus according to the embodiment of the present invention is executed on the bit stream recorded in the memory 9004.

In a case where a user desires an operation of encoding an image captured by the external camera 9102 and recording the encoded image in the memory 9004, the video interface 9009 inputs an image from the camera 9102 and transmits the input image to the image encoding unit 9007 of the codec IC9002 via the bus 9010. The image encoding unit 9007 performs image encoding processing in the image encoding device according to the embodiment of the present invention on an image input via the video interface 9009, and generates a bitstream. The bit stream is then sent to the memory 9004 over the bus 9010. When the user wishes to record a bit stream on the disk recording medium 9100 instead of in the memory 9004, the optical disk drive 9005 performs writing of a bit stream with respect to the inserted disk recording medium 9100.

A hardware configuration having an image encoding device without an image decoding device or a hardware configuration having an image decoding device without an image encoding device may also be realized. Such a hardware configuration is realized by replacing the codec IC9002 with the image encoding unit 9007 or the image decoding unit 9008, respectively.

The processing related to the above-described encoding and decoding may of course be implemented as transmission, storage, and reception means using hardware, and may be implemented by firmware stored in a ROM (read only memory), flash memory, or the like, or software of a computer or the like. The firmware program and the software program may be recorded in a computer-readable recording medium, may be provided from a server via a wired or wireless network, or may be provided as data broadcast of terrestrial or satellite digital broadcast.

The present invention has been described above based on the embodiments. The embodiment is illustrative, and various modifications are possible in combination of these respective constituent elements and the respective processing steps, and such modifications are also within the scope of the present invention, which can be understood by those skilled in the art.

Description of the symbols

100 image coding device, 101 block division unit, 102 inter prediction unit, 103 intra prediction unit, 104 decoded image memory, 105 prediction method determination unit, 106 residual generation unit, 107 orthogonal transformation/quantization unit, 108 bit string coding unit, 109 inverse quantization/inverse orthogonal transformation unit, 110 decoded image signal superposition unit, 111 coded information storage memory, 200 image decoding device, 201 bit string decoding unit, 202 block division unit, 203 inter prediction unit, 204 intra prediction unit, 205 coded information storage memory, 206 inverse quantization/inverse orthogonal transformation unit, 207 decoded image signal superposition unit, and 208 decoded image memory.

Claims (8)

1. A moving picture decoding apparatus comprising:

a spatial motion information candidate derivation unit that derives a spatial motion information candidate from motion information of a block spatially close to a decoding target block;

a temporal motion information candidate derivation unit that derives a temporal motion information candidate from motion information of a block temporally close to the decoding target block; and

a historical motion information candidate derivation unit that derives a historical motion information candidate from a memory that holds motion information of a decoded block,

the historical motion information candidate is compared with the spatial motion information candidate for motion information, but not with the temporal motion information candidate for motion information.

2. A moving picture decoding method, which is a method in a moving picture decoding apparatus, the moving picture decoding method comprising the steps of:

deriving a spatial motion information candidate from motion information of a block spatially close to the decoding object block;

deriving a temporal motion information candidate from motion information of a block temporally close to the decoding object block; and

historical motion information candidates are derived from a memory holding motion information for decoded blocks,

the historical motion information candidate is compared with the spatial motion information candidate for motion information, but not with the temporal motion information candidate for motion information.

3. A moving picture decoding program for causing a computer to execute:

deriving a spatial motion information candidate from motion information of a block spatially close to the decoding object block;

deriving a temporal motion information candidate from motion information of a block temporally close to the decoding object block; and

historical motion information candidates are derived from a memory holding motion information for decoded blocks,

the historical motion information candidate is compared with the spatial motion information candidate for motion information, but not with the temporal motion information candidate for motion information.

4. A moving picture encoding device comprising:

a spatial motion information candidate derivation unit that derives a spatial motion information candidate from motion information of a block spatially close to the encoding target block;

a temporal motion information candidate derivation unit that derives a temporal motion information candidate from motion information of a block temporally close to the encoding target block; and

a historical motion information candidate derivation unit that derives a historical motion information candidate from a memory that holds motion information of the encoded block,

the historical motion information candidate is compared with the spatial motion information candidate for motion information, but not with the temporal motion information candidate for motion information.

5. A moving picture encoding method, which is a method in a moving picture encoding device, is characterized by comprising the steps of:

deriving a spatial motion information candidate from motion information of a block spatially close to the encoding target block;

deriving a temporal motion information candidate from motion information of a block temporally close to the block to be encoded; and

a step of deriving historical motion information candidates from a memory holding motion information of encoded blocks,

the historical motion information candidate is compared with the spatial motion information candidate for motion information, but not with the temporal motion information candidate for motion information.

6. A moving picture encoding program for causing a computer to execute:

deriving a spatial motion information candidate from motion information of a block spatially close to the encoding target block;

deriving a temporal motion information candidate from motion information of a block temporally close to the block to be encoded; and

a step of deriving historical motion information candidates from a memory holding motion information of encoded blocks,

the historical motion information candidate is compared with the spatial motion information candidate for motion information, but not with the temporal motion information candidate for motion information.

7. The moving picture decoding apparatus according to claim 1,

the temporal motion information candidate is registered in a motion information candidate list without a comparison of motion information with the spatial motion information candidate, and the historical motion information candidate is registered in the motion information candidate list if the spatial motion information candidate is not identical to the motion information candidate.

8. The moving picture decoding apparatus according to claim 7,

registering with the motion information candidate list in the order of the spatial motion information candidate, the temporal motion information candidate, and the historical motion information candidate.

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