JP5195875B2 - Decoding apparatus and method, recording medium, and program - Google Patents

Description

  The present invention relates to a decoding device and method, a recording medium, and a program, and more particularly, to a decoding device and method, a recording medium, and a program that suppress a decrease in compression efficiency.

  In recent years, a technique has been widely used in which an image is compressed and encoded by a method such as MPEG (Moving Picture Experts Group), packetized, transmitted, and decoded on the receiving side. As a result, the user can view a high-quality moving image.

  By the way, a packet may disappear in the middle of a transmission path, or noise may be superimposed and decoding becomes impossible. Thus, it is known that when a target block of an image of a predetermined frame cannot be decoded, decoding is performed using a block adjacent to the target block (for example, Patent Document 1).

JP-A-6-311502

  However, with the technique of Patent Document 1, it is possible to restore an image that has become undecodable, but it is not possible to suppress a decrease in encoding efficiency.

  This invention is made | formed in view of such a condition, and suppresses the fall of compression efficiency.

  One aspect of the present invention provides the first encoding method when an adjacent block adjacent to a target block to be encoded is encoded by a second encoding method different from the first encoding method. For a block encoded with the above, a peripheral block located at a distance within a threshold from the target block or within a threshold from the adjacent block with respect to the direction connecting the target block and the adjacent block And a first block corresponding to the first encoding method, using the detection unit to detect the target block encoded by the first encoding method using the alternative block detected by the detection unit. And a second decoding unit that decodes a target block encoded by the second encoding method using a second decoding method corresponding to the second encoding method. Decryption A decoding apparatus comprising and.

  The detection unit can detect the substitute block based on position information indicating a position of a block encoded by the second encoding method.

  The detection unit detects the corresponding block as the substitute block when a corresponding block at a position corresponding to the target block in a picture different from the picture including the target block is encoded by the first encoding method. can do.

  The detection unit can detect an adjacent block as the substitute block when the adjacent block is encoded by the first encoding method.

The first decoding unit decodes the block encoded in the first encoding method as a block having an edge information, the second decoding unit, the second as a block having no edge information It is possible to decode a block encoded by the encoding method.

  The first decoding method is H.264. This is a decoding method corresponding to an encoding method based on the H.264 / AVC standard.

  The second decoding method is a decoding method corresponding to the texture analysis / synthesis coding method.

One aspect of the present invention is a decoding method of a decoding device including a detection unit, a first decoding unit, and a second decoding unit , wherein the detection unit is adjacent to a target block to be encoded. When the adjacent block is encoded by the second encoding method different from the first encoding method, the target block and the adjacent block are targeted for the block encoded by the first encoding method. A neighboring block located at a distance within a threshold from the target block or a distance within a threshold from the adjacent block is detected as an alternative block with respect to the direction connecting to the first block, and the first decoding unit is detected by the detection unit using a replacement block that is, the encoded target block in the first coding scheme, decodes a first decoding method corresponding to the first encoding method, the second decoding unit Is the second code The encoded target block in a manner, a decoding method for decoding in a second decoding method corresponding to the second encoding method.

An aspect of the present invention provides a computer including a detection unit, a first decoding unit, and a second decoding unit, wherein the detection unit includes a first adjacent block adjacent to a target block to be encoded. When coding with a second coding scheme different from the coding scheme of the above, with respect to the direction connecting the target block and the adjacent block with respect to the block coded by the first coding scheme A peripheral block located at a distance within the threshold from the target block or within a threshold from the adjacent block is detected as an alternative block, and the first decoding unit uses the alternative block detected by the detection unit to the coded current block in the first coding scheme, it decodes a first decoding method corresponding to the first encoding method, the second decoding unit, the second Code with encoding method The target blocks, the second second decoding scheme computer which records a program for executing the steps of decoding in corresponding to the coding scheme is a recording medium readable.

An aspect of the present invention provides a computer including a detection unit, a first decoding unit, and a second decoding unit, wherein the detection unit includes a first adjacent block adjacent to a target block to be encoded. When coding with a second coding scheme different from the coding scheme of the above, with respect to the direction connecting the target block and the adjacent block with respect to the block coded by the first coding scheme A peripheral block located at a distance within the threshold from the target block or within a threshold from the adjacent block is detected as an alternative block, and the first decoding unit uses the alternative block detected by the detection unit to the coded current block in the first coding scheme, it decodes a first decoding method corresponding to the first encoding method, the second decoding unit, the second Code with encoding method The target block is a program for executing the steps of decoding in the second decoding method corresponding to the second encoding method.

  As described above, according to one aspect of the present invention, it is possible to suppress a decrease in compression efficiency.

It is a block diagram which shows the structure of one Embodiment of the image coding apparatus to which this invention is applied. It is a figure explaining the basic process of motion threading. It is a figure explaining the calculation of a motion vector. It is a figure which shows the example of the result of motion threading. It is a flowchart explaining an encoding process. It is a flowchart explaining an alternative block detection process. It is a figure explaining an alternative block. It is a block diagram which shows the structure of one Embodiment of a 1st encoding part. It is a flowchart explaining a 1st encoding process. It is a figure explaining intra prediction. It is a figure explaining the direction of intra prediction. It is a figure explaining a process when an adjacent block is unavailable. It is a block diagram which shows the structure of one Embodiment of the image decoding apparatus to which this invention is applied. It is a flowchart explaining a decoding process. It is a figure explaining texture composition. It is a block diagram which shows the structure of one Embodiment of a 1st decoding part. It is a flowchart explaining a 1st decoding process. It is a block diagram which shows the structure of other embodiment of the image coding apparatus to which this invention is applied.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a configuration of an embodiment of an image encoding device of the present invention. The image encoding device 51 includes an A / D conversion unit 61, a screen rearrangement buffer 62, a first encoding unit 63, an alternative block detection unit 64, a determination unit 65, a second encoding unit 66, and an output unit. 67. The determination unit 65 includes a block classification unit 71, a motion threading unit 72, and an exemplar unit 73.

  The A / D conversion unit 61 performs A / D conversion on the input image, outputs it to the screen rearrangement buffer 62, and stores it. The screen rearrangement buffer 62 rearranges the stored frame images in the display order in the order of frames for encoding in accordance with GOP (Group of Picture). Of the images stored in the screen rearrangement buffer 62, the images of I picture and P picture are supplied to the first encoding unit 63 because they are pre-encoded with the first encoding method. The information of the B picture is supplied to the determination unit 65 that determines whether the target block of the image is encoded by the first encoding method or the second encoding method.

  The block classification unit 71 of the determination unit 65 classifies a block having edge information and a block having no edge information among the B picture images supplied from the screen rearrangement buffer 62, and sets a structural block having edge information as a first block. 1 is output to the first encoding unit 63 as a block to be encoded, and a block having no edge information is supplied to the exemplar unit 73. The motion threading unit 72 detects a motion thread of the B picture image supplied from the screen rearrangement buffer 62 and supplies the motion thread to the exemplar unit 73.

  Based on the motion thread, the exemplar unit 73 calculates the STV value of the block having no edge information in accordance with equation (2) described later, and compares the value with a predetermined threshold value. When the STV value is larger than the threshold value, the B picture block image is supplied to the first encoding unit 63 as an exemplar image that is a block on which the first encoding process is performed. When the STV value is smaller than the threshold value, the exemplar unit 73 sets the block of the B picture as a removed block that is a block on which the second encoding process is performed, and sets a binary mask as position information representing the position to the second block The data is supplied to the encoding unit 66.

  The first encoding unit 63 converts the I picture and P picture supplied from the screen rearrangement buffer 62, the structural block supplied from the block classification unit 71, and the exemplar image supplied from the exemplar unit 73 to the first picture. 1 is encoded. Examples of the first encoding method include H.264. H.264 and MPEG-4 Part 10 (Advanced Video Coding) (hereinafter referred to as H.264 / AVC) can be used.

  When the adjacent block adjacent to the target block encoded by the first encoding unit 63 is encoded by the second encoding method, the alternative block detection unit 64 is connected in the direction connecting the target block and the adjacent block. The block that is the closest to the target block and is encoded by the first encoding method is detected as an alternative block. The first encoding unit 63 encodes the target block using the first encoding method using the substitute block as a peripheral block.

  The second encoding unit 66 encodes the binary mask supplied from the exemplar unit 73 with a second encoding method different from the first encoding method. As the second coding method, a texture analysis / synthesis coding method can be used.

  The output unit 67 combines the output of the first encoding unit 63 and the output of the second encoding unit 66 and outputs the result as a compressed image.

  Here, basic processing performed by the motion threading unit 72 will be described. As shown in FIG. 2, the motion threading unit 72 divides an image into a hierarchical structure in units of GOPs. In the embodiment of FIG. 2, a GOP having a GOP length of 8 is divided into three hierarchical structures of layer 0, layer 1 and layer 2. The GOP length can be, for example, a power of 2, but is not limited thereto.

  Layer 2 is the original GOP of the input image composed of nine frames (or fields) F1 to F9. Layer 1 is a layer composed of five frames F1, F3, F5, F7, and F9 by thinning out frames F2, F4, F6, and F8 of layer 2 every other frame, and layer 0 is a frame of layer 1 By thinning out F3 and F7 every other frame, this is a layer composed of three frames F1, F5 and F9.

  The motion threading unit 72 obtains a motion vector of a higher layer (a layer indicated by a smaller number positioned higher in FIG. 2), and then uses the motion vector to obtain a motion vector of the next lower layer. Ask.

That is, as shown in FIG. 3A, the motion threading unit 72 calculates the motion vector Mv (F _2n → F _{2n + 2} ) of the upper layer frame F _2n and frame F _{2n + 2} by a block matching method or the like. together, it calculates a block B _{2n + 2} of frame F _{2n + 2} corresponding to the block B _2n of the frame F _2n.

Next, as illustrated in FIG. 3B, the motion threading unit 72 performs motion vector Mv (F _2n → F) of the frame F _2n and the frame F _{2n + 1} (an intermediate frame between the frame F _2n and the frame F _{2n + 2} ). _{2n + 1)} together with calculating the block matching method, calculates a block B _{2n + 1} frame F _{2n + 1} corresponding to the block B _2n of the frame F _2n.

Then, the motion threading unit 72 calculates the motion vector Mv (F _{2n + 1} → F _{2n + 2} ) of the frame F _{2n + 1} and the frame F _{2n + 2} from the following equation.
Mv (F _{2n + 1} → F _{2n + 2} ) = Mv (F _2n → F _{2n + 2} ) −Mv (F _2n → F _{2n + 1} ) (1)

  Based on the above principle, the motion vectors of the frames F5 and F9 are obtained from the motion vectors of the frames F1 and F9 and the motion vectors of the frames F1 and F5 in the layer 0 of FIG. Next, in layer 1, the motion vectors of the frames F1 and F3 are obtained, and the motion vectors of the frames F3 and F5 are obtained from the motion vectors of the frames F1 and F5 and the motion vectors of the frames F1 and F3. The motion vectors of the frames F5 and F7 are obtained, and the motion vectors of the frames F7 and F9 are obtained from the motion vectors of the frames F5 and F9 and the motion vectors of the frames F5 and F7.

  Further, in layer 2, the motion vectors of the frames F1 and F2 are obtained, and the motion vectors of the frames F2 and F3 are obtained from the motion vectors of the frames F1 and F3 and the motion vectors of the frames F1 and F2. The motion vectors of the frames F3 and F4 are obtained, and the motion vectors of the frames F4 and F5 are obtained from the motion vectors of the frames F3 and F5 and the motion vectors of the frames F3 and F4.

  The motion vectors of the frames F5 and F6 are obtained, and the motion vectors of the frames F6 and F7 are obtained from the motion vectors of the frames F5 and F7 and the motion vectors of the frames F5 and F6. The motion vectors of the frames F7 and F8 are obtained, and the motion vectors of the frames F8 and F9 are obtained from the motion vectors of the frames F7 and F9 and the motion vectors of the frames F7 and F8.

  FIG. 4 shows an example of a motion thread calculated based on the motion vector obtained as described above. In FIG. 4, a black block represents a removed block encoded by the second encoding method, and a white block represents a block encoded by the first encoding method.

  In this example, for example, the block located at the top of the picture B0 is the second position from the top of the picture B1, the third position from the top of the picture B2, the third position from the top of the picture B3, and the picture B4. Belongs to the thread that reaches the third position from the top and the second position from the top of the picture B5.

  Further, the fifth block from the top of the picture B0 belongs to the thread that reaches the fifth position from the top of the picture B1.

  As described above, the motion thread represents a locus of a position on each picture of a predetermined block (that is, a chain of motion vectors).

  Next, the encoding process of the image encoding device 51 in FIG. 1 will be described with reference to the flowchart in FIG.

  In step S1, the A / D converter 61 performs A / D conversion on the input image. In step S2, the screen rearrangement buffer 62 stores the image supplied from the A / D conversion unit 61, and rearranges the picture from the display order to the encoding order. The rearranged I picture and P picture are determined (determined) in advance by the determination unit 65 as being pictures to be subjected to the first encoding process, and are supplied to the first encoding unit 63. The B picture is supplied to the block classification unit 71 and the motion threading unit 72 of the determination unit 65.

  In step S3, the block classification unit 71 classifies the input B picture block. Specifically, a block (a macroblock having a size of 16 × 16 pixels or a block having a size smaller than that) as a unit of encoding performed by the first encoding unit 63 of each picture includes edge information. It is determined whether the block is a block, and the edge information is classified into a block that includes a predetermined reference value and a block that does not include the edge information. Since the block including the edge information is a block of an image that is easily visible to human eyes (that is, a block to be subjected to the first encoding process), the block is supplied to the first encoding unit 63 as a structural block. An image that does not include edge information is supplied to the exemplar unit 73.

  In step S4, the motion threading unit 72 performs motion threading on the B picture. That is, as described with reference to FIGS. 2 to 4, the motion thread represents the locus of the block position, and this information is supplied to the exemplar unit 73. The exemplar unit 73 calculates an STV, which will be described later, based on this information.

In step S5, the exemplar unit 73 extracts the exemplar. Specifically, the exemplar unit 73 calculates STV according to the following equation.

In the above equation, N represents the length of the motion thread obtained by the motion threading unit 72, and Bi represents a block included in the motion thread. μ ₆ represents a block that is adjacent to the block in time and space (up and down, left and right space and time before and after). δ represents a variance value of pixel values included in the block, and E represents an average value of pixel values included in the block. w ₁ and w ₂ are predetermined weighting factors.

  A block having a large STV value is a block having a large difference from a pixel value of an adjacent block, and is therefore an image block that is easily noticeable by humans (that is, a block to be subjected to the first encoding process). Therefore, the exemplar unit 73 outputs a block whose STV value is larger than a preset threshold value to the first encoding unit 63 as an exemplar.

  As described above, the processes in steps S2 to S5 are processes in which the determination unit 65 determines which of the first and second encoding methods is used for encoding.

  In step S6, the substitute block detector 64 executes a substitute block detection process. The details of the process will be described later with reference to FIG. 6. By this process, an alternative block is detected as peripheral information of the target block necessary for the first encoding process. In step S7, the first encoding unit 63 performs a first encoding process. The details of the processing will be described later with reference to FIGS. 8 and 9, but by this processing, the blocks determined as the blocks to be subjected to the first encoding processing by the determination unit 65, that is, I pictures and P pictures , Structural blocks, and exemplars are encoded with the first encoding scheme using alternative blocks.

  In step S8, the second encoding unit 66 encodes the binary block of the removed block supplied from the exemplar unit 73 by the second encoding method. This process does not directly encode the removed block, but can be said to be a kind of encoding because decoding is performed by synthesizing an image with an image decoding device as will be described later.

  In step S <b> 9, the output unit 67 combines the information encoded by the second encoding unit 66 with the compressed image encoded by the first encoding unit 63 and outputs it. This output is transmitted through the transmission path and decoded by the image decoding device.

  Next, the alternative block detection process in step S6 will be described with reference to FIG. As shown in the figure, in step S41, the alternative block detection unit 64 determines whether all adjacent blocks have been subjected to the first encoding process.

  The encoding process is performed in the order of blocks from the upper left to the lower right of the screen. As shown in FIG. 7, if the target block that is the target of the encoding process is the block E, the block that has already been encoded and is adjacent to the target block E is the target block. The upper left block A, the upper block B, the upper right block C, and the left block D of the block E. In step S <b> 41, it is determined whether all these adjacent blocks A to D are blocks encoded by the first encoding unit 63.

  When the blocks A to D are all blocks encoded by the first encoding unit 63, the alternative block detection unit 64 selects the adjacent blocks A to D as the peripheral blocks in step S42. That is, the first encoding unit 63 performs a prediction process based on the motion vectors of the adjacent blocks A to D when encoding the target block E. In this case, since there are usable blocks, efficient encoding is possible.

  A block that is not encoded by the first encoding unit 63 is a removed block, and is encoded by the second encoding unit 66. When the adjacent blocks A to D are blocks encoded by the second encoding unit 66 (not the blocks encoded by the first encoding unit 63), the encoding principle is different. The encoding unit 63 cannot use the adjacent blocks A to D for encoding the target block E. In this case, when an encoding process is performed as an unavailable state in which a block as peripheral information cannot be obtained, that is, for example, the target block is located at the edge of the screen and there is no adjacent block outside the block. When the same processing is performed, the encoding efficiency in this case is lower than that when there is an adjacent block.

  Therefore, when the adjacent blocks A to D are not all blocks encoded by the first encoding unit 63, in step S43, the first encoding unit 63 is a removed block among the adjacent blocks. It is determined whether there is a block on which the first encoding process is performed at a distance within a predetermined threshold from the block. That is, it is determined whether there is an alternative block used instead of the adjacent block. Then, when there is a block on which the first encoding process has been performed at a distance within a predetermined threshold (when there is a substitute block), the substitute block detection unit 64 sets the predetermined block as a peripheral block in step S44. An alternative block having a distance within the threshold of is selected.

  For example, as shown in FIG. 7, when the adjacent block A is not a block encoded by the first encoding unit 63 (when it is a block encoded by the second encoding unit 66), the target When the block is located at the shortest distance in the direction of the adjacent block A from the block E and the block encoded by the first encoding unit 63 is the block A ′, this block A ′ is set as the substitute block. The

  Since the substitute block A ′ is a block in the vicinity of the adjacent block A, it is considered that the substitute block A ′ has a feature similar to the adjacent block A. That is, the substitute block A ′ has a relatively high correlation with the adjacent block A. Therefore, by performing the first encoding on the target block E using the alternative block A ′ instead of the adjacent block A, that is, by performing the prediction process using the motion vector of the alternative block A ′. Thus, it is possible to suppress a decrease in encoding efficiency.

  However, when the distance from the adjacent block A to the alternative block A ′ is more than a predetermined threshold value set in advance, the possibility that the alternative block A ′ is an image having characteristics similar to those of the adjacent block A is reduced. (Correlation is low). As a result, it is difficult to suppress a decrease in coding efficiency even if the alternative block A ′ located at a distance greater than the threshold is used. Therefore, only blocks located at a distance within the threshold are used for coding the target block E as substitute blocks.

  The same applies to the adjacent blocks B, C, and D. When they are removed blocks, the thresholds in the direction from the target block E to the adjacent blocks B, C, and D are used instead of the adjacent blocks B, C, and D, respectively. The motion vectors of the alternative blocks B ′, C ′, and D ′ located within the distance are used for the first encoding of the target block E.

  The distance threshold may be a fixed value or may be determined by the user, encoded by the first encoding unit 63, and transmitted along with the compressed image.

  If it is determined in step S43 that there is no block that has undergone the first encoding process at a distance within a predetermined threshold from a block that is a removed block among adjacent blocks, in step S45, further It is determined whether an alternative process for the motion vector is possible.

  That is, the alternative block detection unit 64 determines in step S45 whether the motion vector of the corresponding block is available. The corresponding block (co-located block) is a block of a picture (picture located before or after) different from the picture of the target block, and is a block at a position corresponding to the target block. When the corresponding block is a block subjected to the first encoding process, it is determined that the motion vector of the corresponding block can be used. In this case, in step S46, the alternative block detection unit 64 selects a corresponding block as a peripheral block. That is, the first encoding unit 63 performs the encoding process by performing the prediction process based on the motion vector using the corresponding block as a substitute block of the target block. This also can suppress a decrease in encoding efficiency.

  If the motion vector of the corresponding block is not available, the alternative block detection unit 64 assumes that the block is unavailable in step S47. That is, in this case, the same processing as the conventional one is performed.

  As described above, when the first encoding is performed on the block of the image that is easily noticeable to the human eye of the B picture in addition to the block of the I picture and the P picture, the adjacent block is the first image of the image that is difficult for the human eye to see. In the case of a block that has been subjected to encoding of 2, since the first encoded alternative block that is closest in the direction is used as a peripheral block for the first encoding of the target block, the encoding efficiency is improved. The decrease can be suppressed.

  FIG. 8 shows a configuration of an embodiment of the first encoding unit 63. The first encoding unit 63 includes an input unit 81, a calculation unit 82, an orthogonal transform unit 83, a quantization unit 84, a lossless encoding unit 85, an accumulation buffer 86, an inverse quantization unit 87, an inverse orthogonal transform unit 88, The calculation unit 89 includes a deblocking filter 90, a frame memory 91, a switch 92, a motion prediction / compensation unit 93, an intra prediction unit 94, a switch 95, and a rate control unit 96.

  The input unit 81 inputs an I picture and a P picture from the screen rearrangement buffer 62, a structural block from the block classification unit 71, and an exemplar image from the exemplar unit 73. The input unit 81 supplies the input image to the alternative block detection unit 64, the calculation unit 82, the motion prediction / compensation unit 93, and the intra prediction unit 94.

  The calculation unit 82 subtracts the prediction image of the motion prediction / compensation unit 93 selected by the switch 95 or the prediction image of the intra prediction unit 94 from the image supplied from the input unit 81, and orthogonally converts the difference information thereof. Output to. The orthogonal transform unit 83 performs orthogonal transform such as discrete cosine transform and Karhunen-Loeve transform on the difference information from the calculation unit 82, and outputs the transform coefficient. The quantization unit 84 quantizes the transform coefficient output from the orthogonal transform unit 83.

  The quantized transform coefficient that is an output of the quantization unit 84 is input to the lossless encoding unit 85, where lossless encoding such as variable length encoding and arithmetic encoding is performed and compressed. The compressed image is output after being stored in the storage buffer 86. The rate control unit 96 controls the quantization operation of the quantization unit 84 based on the compressed image stored in the storage buffer 86.

  Further, the quantized transform coefficient output from the quantization unit 84 is also input to the inverse quantization unit 87, and after inverse quantization, the inverse orthogonal transform unit 88 further performs inverse orthogonal transform. The output subjected to the inverse orthogonal transform is added to the predicted image supplied from the switch 95 by the arithmetic unit 89 to be a locally decoded image. The deblocking filter 90 removes the block distortion of the decoded image, and then supplies it to the frame memory 91 for accumulation. The image before the deblocking filter processing by the deblocking filter 90 is also supplied to the frame memory 91 and accumulated.

  The switch 92 outputs the reference image stored in the frame memory 91 to the motion prediction / compensation unit 93 or the intra prediction unit 94. The intra prediction unit 94 performs an intra prediction process based on the image to be intra predicted supplied from the input unit 81 and the reference image supplied from the frame memory 91, and generates a predicted image. At that time, the intra prediction unit 94 supplies information about the intra prediction mode applied to the block to the lossless encoding unit 85. The lossless encoding unit 85 encodes this information and uses it as a part of header information in the compressed image.

  The motion prediction / compensation unit 93 detects a motion vector based on the inter-coded image supplied from the input unit 81 and the reference image supplied from the frame memory 91 via the switch 92, and converts the motion vector into the motion vector. Based on this, motion prediction and compensation processing are performed on the reference image to generate a predicted image.

  The motion compensation / prediction device 93 outputs the motion vector to the lossless encoding unit 85. The lossless encoding unit 85 also performs lossless encoding processing such as variable length encoding and arithmetic encoding on the motion vector, and inserts it into the header portion of the compressed image.

  The switch 95 selects the prediction image output from the motion prediction / compensation unit 93 or the intra prediction unit 94 and supplies it to the calculation units 82 and 89.

  The substitute block detection unit 64 determines whether the adjacent block is a removed block based on the binary mask output from the exemplar unit 73. If the adjacent block is a removed block, the substitute block detection unit 64 detects the substitute block and reversibly detects the detection result. The data is output to the encoding unit 85, the motion prediction / compensation unit 93, and the intra prediction unit 94.

  Next, the first encoding process in step S7 of FIG. 5 performed by the first encoding unit 63 will be described with reference to FIG.

  In step S81, the input unit 81 inputs an image. Specifically, the input unit 81 inputs I picture and P picture from the screen rearrangement buffer 62, structural blocks from the block classification unit 71, and exemplar images from the exemplar unit 73. In step S82, the calculation unit 82 calculates the difference between the image input in step S81 and the predicted image. The predicted image is supplied from the motion prediction / compensation unit 93 in the case of inter prediction, and from the intra prediction unit 94 in the case of intra prediction, to the calculation unit 82 via the switch 95.

  The difference data has a smaller data amount than the original image data. Therefore, the data amount can be compressed as compared with the case where the image is encoded as it is.

  In step S <b> 83, the orthogonal transform unit 83 performs orthogonal transform on the difference information supplied from the calculation unit 82. Specifically, orthogonal transformation such as discrete cosine transformation and Karhunen-Loeve transformation is performed, and transformation coefficients are output. In step S84, the quantization unit 84 quantizes the transform coefficient. At the time of this quantization, the rate is controlled as described in the process of step S95 described later.

  The difference information quantized as described above is locally decoded as follows. That is, in step S85, the inverse quantization unit 87 inversely quantizes the transform coefficient quantized by the quantization unit 84 with characteristics corresponding to the characteristics of the quantization unit 84. In step S <b> 86, the inverse orthogonal transform unit 88 performs inverse orthogonal transform on the transform coefficient inversely quantized by the inverse quantization unit 87 with characteristics corresponding to the characteristics of the orthogonal transform unit 83.

  In step S87, the calculation unit 89 adds the predicted image input via the switch 95 to the locally decoded difference information, and the locally decoded image (image corresponding to the input to the calculation unit 82). Is generated. In step S88, the deblocking filter 90 filters the image output from the calculation unit 89. Thereby, block distortion is removed. In step S89, the frame memory 91 stores the filtered image. Note that an image that has not been filtered by the deblocking filter 90 is also supplied to the frame memory 91 from the arithmetic unit 89 and stored therein.

  When the processing target image supplied from the input unit 81 is an image to be inter-processed, the referenced image is read from the frame memory 91 and supplied to the motion prediction / compensation unit 93 via the switch 92. In step S90, the motion prediction / compensation unit 93 refers to the image supplied from the frame memory 91, predicts the motion, performs motion compensation based on the motion, and generates a predicted image.

  If the processing target image supplied from the input unit 81 (for example, the pixels a to p in FIG. 10) is an image of a block to be intra-processed, the decoded image to be referred to (pixels A to L in FIG. 10). Are read from the frame memory 91 and supplied to the intra prediction unit 94 via the switch 92. Based on these images, in step S91, the intra prediction unit 94 performs intra prediction on the pixels of the processing target block in a predetermined intra prediction mode. Note that pixels that have not been deblocked filtered by the deblocking filter 90 are used as the decoded pixels to be referred to (pixels A to L in FIG. 10). This is because intra prediction is performed by sequential processing for each macroblock, whereas deblock filtering processing is performed after a series of decoding processes.

  The luminance signal intra prediction modes include nine types of 4 × 4 pixel and 8 × 8 pixel block units, and four types of 16 × 16 pixel macroblock unit prediction modes. There are four types of prediction modes in units of 8 × 8 pixel blocks. The color difference signal intra prediction mode can be set independently of the luminance signal intra prediction mode. As for the 4 × 4 pixel and 8 × 8 pixel intra prediction modes of the luminance signal, one intra prediction mode is defined for each block of the luminance signal of 4 × 4 pixels and 8 × 8 pixels. For the 16 × 16 pixel intra prediction mode for luminance signals and the intra prediction mode for color difference signals, one prediction mode is defined for one macroblock.

  The types of prediction modes correspond to the directions indicated by numbers 0 to 8 in FIG. Prediction mode 2 is average value prediction.

  In step S92, the switch 95 selects a predicted image. That is, in the case of inter prediction, the prediction image of the motion prediction / compensation unit 93 is selected, and in the case of intra prediction, the prediction image of the intra prediction unit 94 is selected and supplied to the calculation units 82 and 89. As described above, this predicted image is used for the calculations in steps S82 and S87.

  In step S93, the lossless encoding unit 85 encodes the quantized transform coefficient output from the quantization unit 84. That is, the difference image is subjected to lossless encoding such as variable length encoding and arithmetic encoding, and is compressed. At this time, the motion vector detected by the motion prediction / compensation unit 93 in step S90 and the information on the intra prediction mode applied to the block by the intra prediction unit 94 in step S91 are also encoded and added to the header information. Is done.

  In step S94, the accumulation buffer 86 accumulates the difference image as a compressed image. The compressed image stored in the storage buffer 86 is appropriately read out and transmitted to the decoding side via the transmission path.

  In step S95, the rate control unit 96 controls the quantization operation rate of the quantization unit 84 based on the compressed image stored in the storage buffer 86 so that overflow or underflow does not occur.

  In the motion prediction process, the intra prediction process, and the encoding process in steps S90, S91, and S93, the peripheral blocks selected in steps S44 and S46 in FIG. 6 are used. That is, the prediction process is performed using the motion vector for the alternative block selected instead of the adjacent block. Therefore, when all the adjacent blocks are not the blocks subjected to the first encoding process, as in the case of the process in step S47, compared to the case where the neighboring information is processed as unavailable, the first code that is more efficient for the block. Can be processed.

  Here, a process when it is determined that the peripheral information is unavailable will be described.

  First, in intra prediction, a process performed when peripheral information is unavailable will be described using an intra 4 × 4 prediction mode as an example.

  In FIG. 12A, it is assumed that X is a 4 × 4 target block, and A and B are 4 × 4 blocks adjacent to the left and top of the block X. When the block A or B is unavailable, the flag dcPredModePredictedFlag = 1, and at this time, the prediction mode of the target block X is the prediction mode 2 (average value prediction mode). That is, a block including pixels having an average pixel value of the target block X is set as a prediction block.

  The same applies to the processing for the motion prediction mode when the target block X is an intra 8 × 8 prediction mode, an intra 16 × 16 prediction mode, or a block of color difference signals.

  In motion vector encoding, processing performed when peripheral information is unavailable is as follows.

  In FIG. 12B, it is assumed that X is a target motion prediction block, and A to D are motion prediction blocks adjacent to the left, top, top right, and top left of the target block X, respectively. When the motion vectors of the motion prediction blocks A to C are available, the motion vector prediction value PredMV for the target motion prediction block X is generated by the median of the motion vectors of the motion prediction blocks A to C.

  On the other hand, when one of the motion vectors of the motion prediction blocks A to C is unavailable, the following processing is performed.

  First, when the motion vector of block C is unavailable, when the motion vectors of blocks A, B, and D are available, the motion vector of block X is generated by the median of the motion vectors of blocks A, B, and D. The When both block B and block C are unavailable, and when both block C and block D are unavailable, median prediction is not performed, and the motion vector for block A is the predicted value of the motion vector of block X. Is done. However, when the motion vector for the block A is unavailable, the predicted value of the motion vector of the block X is 0.

  Next, variable length coding processing when peripheral information is unavailable will be described.

  In FIG. 12A, it is assumed that X is a 4 × 4 or 8 × 8 target orthogonal transform block, and A and B are adjacent blocks. If the number of orthogonal transform coefficients whose values in block A and block B are not 0 is nA and nB, the variable length transform table for block X is selected by the numbers nA and nB. However, if the block A is unavailable, the number nA = 0 is assumed. If the block B is unavailable, the number nB = 0 is assumed, and the corresponding conversion table is selected.

  The arithmetic encoding process when the peripheral information is unavailable is as follows.

  Here, the flag mb_skip_flag will be described as an example, but the same applies to processing for other syntax elements.

  For macroblock K, the context ctx (K) is defined as follows: That is, the context ctx (K) is set to 1 when the macroblock K is a skipped macroblock that directly uses pixels at spatially corresponding positions in the reference frame, and is set to 0 otherwise.

The context ctx (X) for the target block X is calculated as the sum of the context ctx (A) of the left adjacent block A and the context ctx (B) of the upper adjacent block B as shown in the following equation.
ctx (X) = ctx (A) + ctx (B) (4)

  When the block A or the block B is unavailable, the context ctx (A) = 0 or the context ctx (B) = 0.

  As described above, if processing is performed assuming that the peripheral information is unavailable, efficient processing becomes difficult, but efficient processing is possible by using an alternative block as a peripheral block as described above. .

  The encoded compressed image is transmitted via a predetermined transmission path and decoded by the image decoding device. FIG. 13 shows a configuration of an embodiment of such an image decoding apparatus.

  The image decoding apparatus 101 includes a storage buffer 111, a first decoding unit 112, an alternative block detection unit 113, a second decoding unit 114, a screen rearrangement buffer 115, and a D / A conversion unit 116. The second decoding unit 114 includes an auxiliary information decoding unit 121 and a texture synthesis unit 122.

  The accumulation buffer 111 accumulates the transmitted compressed image. The 1st decoding part 112 decodes the compressed image in which the 1st encoding is performed among the compressed images accumulate | stored in the accumulation buffer 111 by a 1st decoding process. This first decoding process is a process corresponding to the first encoding process performed by the first encoding unit 63 of the image encoding device 51 of FIG. This is processing of a decoding method corresponding to the H.264 / AVC method. The substitute block detector 113 detects a substitute block based on the binary mask supplied from the auxiliary information decoder 121. Its function is the same as that of the alternative block detector 64 of FIG.

  The second decoding unit 114 performs a second decoding process on the compressed image on which the second encoding supplied from the accumulation buffer 111 is performed. Specifically, the auxiliary information decoding unit 121 performs a decoding process corresponding to the second encoding process by the second encoding unit 66 in FIG. 1, and the texture synthesis unit 122 supplies from the auxiliary information decoding unit 121. A texture synthesis process is performed based on the binary mask. For this reason, the texture synthesis unit 122 is supplied with the image of the target frame (B picture image) from the first decoding unit 112 and the reference image is supplied from the screen rearrangement buffer 115.

  The screen rearrangement buffer 115 rearranges the I picture and P picture images decoded by the first decoding unit 112 and the B picture image synthesized by the texture synthesis unit 122. That is, the order of frames rearranged for the encoding order by the screen rearrangement buffer 62 in FIG. 1 is rearranged in the original display order. The D / A converter 116 performs D / A conversion on the image supplied from the screen rearrangement buffer 115, and outputs and displays it on a display (not shown).

  Next, a decoding process executed by the image decoding apparatus 101 will be described with reference to FIG.

  In step S131, the accumulation buffer 111 accumulates the transmitted image. In step S <b> 132, the first decoding unit 112 performs the first decoding process on the image that has been read from the accumulation buffer 111 and is subjected to the first encoding process. The details thereof will be described later with reference to FIGS. 16 and 17. As a result, the I picture and the P picture encoded by the first encoding unit 63 in FIG. 1 and the B block structural block and the exemplar image are displayed. (An image of a block whose STV value is larger than the threshold value) is decoded. Images of I picture and P picture are supplied to the screen rearrangement buffer 115 and stored. The B picture image is supplied to the texture synthesis unit 122.

  In step S133, the substitute block detecting unit 113 executes a substitute block detecting process. This process is as described with reference to FIG. 6. When the adjacent block is a block that has not been subjected to the first encoding, a substitute block is detected. In order to perform this processing, the binary mask decoded by the auxiliary information decoding unit 121 in step S134 described later is supplied to the alternative block detection unit 113. The alternative block detection unit 113 uses a binary mask to check whether each block is a block on which the first encoding process has been performed or a block on which the second encoding process has been performed. The first decoding process of step S132 is performed using the detected substitute block.

  Next, the second decoding unit 114 performs second decoding in steps S134 and S135. That is, in step S134, the auxiliary information decoding unit 121 decodes the binary mask subjected to the second encoding process supplied from the accumulation buffer 111. The decoded binary mask is output to the texture synthesis unit 122 and the alternative block detection unit 113. The binary mask represents the position of the removed block, that is, the position of the block that has not been subjected to the first encoding process (the position of the block that has been subjected to the second encoding process). Therefore, as described above, the substitute block detector 113 detects substitute blocks using this binary mask.

In step S135, the texture synthesis unit 122 performs texture synthesis on the removed block specified by the binary mask. This texture synthesis is a process of reproducing a removed block (an image block whose STV value is smaller than the threshold value), and its principle is shown in FIG. As shown in the figure, the target block B ₁ is a block to be processed in the decoding frame B picture belongs to a target frame F _C. If the target block B ₁ is a removed block, the position is represented by a binary mask.

Texture synthesis unit 122 receives a binary mask from the auxiliary information decoder 121, a forward reference frame F _P of one frame before the target frame F _C, a search range to a predetermined range around the position corresponding to the target block Set R. Object frame F _C from the first decoding unit 112, the forward reference frame F _P from the screen rearrangement buffer, are supplied to the texture synthesis part 122. Then, the texture synthesis unit 122 searches for a block B ₁ ′ having the highest correlation with the target block B ₁ within the search range R. However, since the target block B ₁ is a removed block and the first encoding process is not performed, there is no pixel value.

Accordingly, the texture combining unit 122 is used to search in place of the pixel value of the region of the predetermined range in the vicinity of the target block B ₁ to the pixel value of the target block B _1. For the embodiment of FIG. 15, an area A ₁ that is adjacent above the current block B _1, the pixel value of the region A ₂ adjacent to the lower side is used. Texture synthesis unit 122, the forward reference frame F _P, the target block B _1, the reference block B ₁ corresponding to the area A _1, A ₂ ', regions A _1', A ₂ 'assume, reference block B _1' Is the range located within the search range R, the difference absolute value sum and the difference square sum of the regions A ₁ and A ₂ and the regions A ₁ ′ and A ₂ ′ are calculated.

Similar operations are also performed in the backward reference frame F _b after one frame of the target frame F _C. The backward reference frame F _{b is} also supplied from the screen rearrangement buffer 115 to the texture synthesis unit 122. The calculated value is the smallest (most correlated) area A ₁ of the position ', A _2' reference block B ₁ corresponding to 'is searched, the reference block B _1' target block B in the target frame F _C It is synthesized as a pixel value of ₁ . The B picture combined with the removed block is supplied to the screen rearrangement buffer 115 and stored therein.

  As described above, since the second encoding / decoding system in this embodiment is a texture analysis / synthesis encoding / decoding system, the binary mask as auxiliary information is encoded and transmitted, and the target block These pixel values are not directly encoded and transmitted, but the target block is synthesized based on the binary mask on the image decoding apparatus side.

  In step S136, the screen rearrangement buffer 115 performs rearrangement. That is, the order of frames rearranged for encoding by the screen rearrangement buffer 62 of the image encoding device 51 is rearranged to the original display order.

  In step S137, the D / A converter 116 D / A converts the image from the screen rearrangement buffer 115. This image is output to a display (not shown), and the image is displayed.

  FIG. 16 illustrates a configuration of an embodiment of the first decoding unit 112. The first decoding unit 112 includes a lossless decoding unit 141, an inverse quantization unit 142, an inverse orthogonal transform unit 143, a calculation unit 144, a deblock filter 145, a frame memory 146, a switch 147, a motion prediction / compensation unit 148, and intra prediction. The unit 149 and the switch 150 are included.

  The lossless decoding unit 141 decodes the information supplied from the accumulation buffer 111 and encoded by the lossless encoding unit 85 in FIG. 8 using a method corresponding to the encoding method of the lossless encoding unit 85. The inverse quantization unit 142 inversely quantizes the image decoded by the lossless decoding unit 141 by a method corresponding to the quantization method of the quantization unit 84 in FIG. The inverse orthogonal transform unit 143 performs inverse orthogonal transform on the output of the inverse quantization unit 142 by a method corresponding to the orthogonal transform method of the orthogonal transform unit 83 in FIG.

  The inverse orthogonal transformed output is added to the predicted image supplied from the switch 150 by the arithmetic unit 144 and decoded. The deblocking filter 145 removes the block distortion of the decoded image, and then supplies the frame to the frame memory 146 for accumulation. The deblocking filter 145 rearranges the I picture and the P picture into the texture synthesis unit 122 shown in FIG. Each is output to the buffer 115.

  The switch 147 reads an image to be inter-coded and an image to be referred to from the frame memory 146, outputs the image to the motion prediction / compensation unit 148, and reads an image used for intra prediction from the frame memory 146, 149.

  Information about the intra prediction mode obtained by decoding the header information is supplied from the lossless decoding unit 141 to the intra prediction unit 149. The intra prediction unit 149 generates a predicted image based on this information.

  A motion vector obtained by decoding the header information is supplied from the lossless decoding unit 141 to the motion prediction / compensation unit 148. The motion prediction / compensation unit 148 performs motion prediction and compensation processing on the image based on the motion vector, and generates a predicted image.

  The switch 150 selects the prediction image generated by the motion prediction / compensation unit 148 or the intra prediction unit 149 and supplies the selected prediction image to the calculation unit 144.

  The alternative block detection unit 113 detects an alternative block based on the binary mask output from the auxiliary information decoding unit 121 in FIG. 13, and the detection result is a lossless decoding unit 141, a motion prediction / compensation unit 148, and an intra prediction unit 149. Output to.

  Next, the first decoding process in step S132 in FIG. 14 performed by the first decoding unit 112 in FIG. 16 will be described with reference to FIG.

  In step S161, the lossless decoding unit 141 decodes the compressed image supplied from the accumulation buffer 111. That is, the structural blocks and exemplars of I picture, P picture, and B picture encoded by the lossless encoding unit 85 in FIG. 8 are decoded. At this time, the motion vector and the intra prediction mode are also decoded, the motion vector is supplied to the motion prediction / compensation unit 148, and the intra prediction mode is supplied to the intra prediction unit 149.

  In step S162, the inverse quantization unit 142 inversely quantizes the transform coefficient decoded by the lossless decoding unit 141 with characteristics corresponding to the characteristics of the quantization unit 84 in FIG. In step S163, the inverse orthogonal transform unit 143 performs inverse orthogonal transform on the transform coefficient inversely quantized by the inverse quantization unit 142 with characteristics corresponding to the characteristics of the orthogonal transform unit 83 in FIG. As a result, the difference information corresponding to the input of the orthogonal transform unit 83 in FIG. 8 (the output of the calculation unit 82) is decoded.

  In step S164, the calculation unit 144 adds the prediction image selected in the process of step S169 described later and input via the switch 150 to the difference information. As a result, the original image is decoded. In step S165, the deblocking filter 145 filters the image output from the calculation unit 144. Thereby, block distortion is removed. Of these images, the B picture is supplied to the texture synthesis unit 122 in FIG. 13 and the I picture and the P picture are supplied to the screen rearrangement buffer 115, respectively. In step S166, the frame memory 146 stores the filtered image.

  When the image to be processed is an image to be inter-processed, a necessary image is read from the frame memory 146 and supplied to the motion prediction / compensation unit 148 via the switch 147. In step S167, the motion prediction / compensation unit 148 performs motion prediction based on the motion vector supplied from the lossless decoding unit 141, and generates a predicted image.

  When the image to be processed is an image to be intra-processed, a necessary image is read from the frame memory 146 and supplied to the intra prediction unit 149 via the switch 147. In step S168, the intra prediction unit 149 performs intra prediction according to the intra prediction mode supplied from the lossless decoding unit 141, and generates a predicted image.

  In step S169, the switch 150 selects a predicted image. That is, one of the prediction images generated by the motion prediction / compensation unit 148 or the intra prediction unit 149 is selected, supplied to the calculation unit 144, and added to the output of the inverse orthogonal transform unit 143 in step S164 as described above. .

  In the decoding process of the lossless decoding unit 141 in step S161, the motion prediction / compensation process of the motion prediction / compensation unit 148 in step S167, and the intra prediction process of the intra prediction unit 149 in step S168, the alternative block detection unit 113 The detected alternative block is used. Therefore, efficient processing is possible.

  The above processing is performed in step S132 in FIG. This decoding process is basically the same as the local decoding process in steps S85 to S92 in FIG. 9 performed by the first encoding unit 63 in FIG.

  FIG. 18 shows a configuration of another embodiment of the image encoding device. The determination unit 70 of the image encoding device 51 further includes a global motion vector detection unit 181. The global motion vector detection unit 181 detects global motion such as translation, enlargement, reduction, and rotation of the entire screen of the frame supplied from the screen rearrangement buffer 62, and substitutes the global motion vector corresponding to the detection result. This is supplied to the block detector 64 and the second encoder 66.

  The substitute block detector 64 detects substitute blocks by translating, enlarging, reducing, or rotating the entire screen so as to return to the original based on the global motion vector. Thereby, even when the entire screen is translated, enlarged, reduced, or rotated, the substitute block can be accurately detected.

  The second encoding unit 66 performs the second encoding process on the global motion vector in addition to the binary mask, and transmits the result to the decoding side.

  Other configurations and operations are the same as those of the image encoding device 51 of FIG.

  An image decoding apparatus corresponding to the encoding apparatus in FIG. 18 has the same configuration as that shown in FIG. The auxiliary information decoding unit 121 also decodes the global motion vector together with the binary mask, and supplies it to the alternative block detection unit 113. Similar to the alternative block detector 64, the alternative block detector 113 detects the alternative block by translating, enlarging, reducing, or rotating the entire screen so as to return to the original based on the global motion. Thereby, even when the entire screen is translated, enlarged, reduced, or rotated, the substitute block can be accurately detected.

  The binary mask and global motion vector decoded by the auxiliary information decoding unit 121 are also supplied to the texture synthesis unit 122. The texture synthesis unit 122 performs texture synthesis by translating, enlarging, reducing, or rotating the entire screen so as to return to the original based on the global motion. Thereby, even when the entire screen is translated, enlarged, reduced, or rotated, texture synthesis can be performed accurately.

  Other configurations and operations are the same as those of the image decoding apparatus 101 in FIG.

  As described above, when the adjacent block adjacent to the target block is encoded by the second encoding method, the block closest to the target block in the direction connecting the target block and the adjacent block, By using the alternative block encoded by the first encoding method and encoding the image by the first encoding method, it is possible to suppress a decrease in the compression rate.

  In the above, the first encoding method is H.264. The H.264 / AVC scheme is used as the first decoding scheme, the corresponding decoding scheme is used as the second coding scheme, and the texture / synthesis coding scheme is used as the second decoding scheme, and the corresponding decoding scheme is used as the second decoding scheme. However, other encoding / decoding schemes may be used.

  The series of processes described above can be executed by hardware or can be executed by software. When a series of processing is executed by software, a program constituting the software executes various functions by installing a computer incorporated in dedicated hardware or various programs. For example, it is installed from a program recording medium in a general-purpose personal computer or the like.

  Program recording media for storing programs that are installed in a computer and are ready to be executed by the computer are magnetic disks (including flexible disks), optical disks (CD-ROM (Compact Disc-Read Only Memory), DVD (Digital Versatile). Disk), a magneto-optical disk), or a removable medium that is a package medium made of semiconductor memory, or a ROM or hard disk in which a program is temporarily or permanently stored. The program is stored in the program recording medium using a wired or wireless communication medium such as a local area network, the Internet, or digital satellite broadcasting via an interface such as a router or a modem as necessary.

  In the present specification, the steps for describing a program are not only processes performed in time series in the order described, but also processes that are executed in parallel or individually even if they are not necessarily processed in time series. Is also included.

  The embodiments of the present invention are not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

51 Image Encoding Device, 61 A / D Converter, 62 Screen Rearrangement Buffer, 63 First Encoding Unit, 64 Alternative Block Detection Unit, 65 Judgment Unit, 66 Second Encoding Unit, 67 Output Unit, 71 Block classification unit, 72 motion threading unit, 73 exemplar unit, 101 image decoding device, 111 storage buffer, 112 first decoding unit, 113 alternative block detection unit, 114 second decoding unit, 115 screen rearrangement buffer, 116 D / A conversion unit, 121 auxiliary information decoding unit, 122 texture synthesis unit

Claims (10)

When an adjacent block adjacent to a target block to be encoded is encoded by a second encoding scheme different from the first encoding scheme, a block encoded by the first encoding scheme is As a target, a detection unit that detects, as an alternative block, a peripheral block located at a distance within a threshold from the target block or a distance within a threshold from the adjacent block with respect to a direction connecting the target block and the adjacent block;
A first block that decodes a target block encoded by the first encoding scheme using a first decoding scheme corresponding to the first encoding scheme, using the alternative block detected by the detection unit A decryption unit of
A decoding apparatus comprising: a second decoding unit configured to decode a target block encoded by the second encoding method using a second decoding method corresponding to the second encoding method. The decoding device according to claim 1, wherein the detection unit detects the substitute block based on position information indicating a position of a block encoded by the second encoding method. The detection unit detects the corresponding block as the substitute block when a corresponding block at a position corresponding to the target block in a picture different from the picture including the target block is encoded by the first encoding method. The decoding device according to claim 1. The detection unit detects an adjacent block as the substitute block when the adjacent block is encoded by the first encoding method.
The decoding device according to claim 3 . The first decoding unit decodes the block encoded in the first encoding method as a block having an edge information, the second decoding unit, the second as a block having no edge information The decoding device according to claim 1, wherein a block encoded by the encoding method is decoded. The first decoding method is H.264. The decoding apparatus according to claim 1, wherein the decoding apparatus corresponds to an encoding system based on the H.264 / AVC standard. The decoding device according to claim 1, wherein the second decoding method is a decoding method corresponding to a texture analysis / synthesis coding method. A detection unit;
A first decoding unit;
A second decryption unit and
A decoding method of a decoding device comprising:
When the adjacent block adjacent to the target block to be encoded is encoded with a second encoding scheme different from the first encoding scheme, the detection unit performs encoding with the first encoding scheme. As a substitute block, a peripheral block located within a threshold distance from the target block or within a threshold distance from the adjacent block in the direction connecting the target block and the adjacent block is detected as a substitute block. And
Wherein the first decoding unit uses the detected replacement block by the detection unit, the encoded target block in the first encoding method, the first corresponding to the first encoding method Decryption with
The decoding method, wherein the second decoding unit decodes a target block encoded by the second encoding method using a second decoding method corresponding to the second encoding method. A detection unit;
A first decoding unit;
A computer comprising: a second decryption unit;
When the adjacent block adjacent to the target block to be encoded is encoded with a second encoding scheme different from the first encoding scheme, the detection unit performs encoding with the first encoding scheme. As a substitute block, a peripheral block located within a threshold distance from the target block or within a threshold distance from the adjacent block in the direction connecting the target block and the adjacent block is detected as a substitute block. And
Wherein the first decoding unit uses the detected replacement block by the detection unit, the encoded target block in the first encoding method, the first corresponding to the first encoding method Decryption with
The second decoding unit executes a program for executing a step of decoding a target block encoded by the second encoding method by a second decoding method corresponding to the second encoding method. A recorded computer- readable recording medium. A detection unit;
A first decoding unit;
A computer comprising: a second decryption unit;
When the adjacent block adjacent to the target block to be encoded is encoded with a second encoding scheme different from the first encoding scheme, the detection unit performs encoding with the first encoding scheme. As a substitute block, a peripheral block located within a threshold distance from the target block or within a threshold distance from the adjacent block in the direction connecting the target block and the adjacent block is detected as a substitute block. And
Wherein the first decoding unit uses the detected replacement block by the detection unit, the encoded target block in the first encoding method, the first corresponding to the first encoding method Decryption with
The second decoding unit is a program for executing a step of decoding a target block encoded by the second encoding method using a second decoding method corresponding to the second encoding method.

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