JP4150742B2 - Motion vector decoding method - Google Patents

Description

  The present invention relates to a motion vector encoding method and a motion vector decoding method using inter-picture predictive encoding.

  In recent years, the multimedia era of voice, image, and other data has been integrated, and conventional information media, that is, means for transmitting information such as newspapers, magazines, television, radio, and telephones to people are targeted for multimedia. It has come to be taken up as. In general, multimedia refers to not only characters but also figures, sounds, especially images, etc. that are associated with each other at the same time. It is an essential condition.

  However, when the amount of information possessed by each information medium is estimated as the amount of digital information, the amount of information per character in the case of characters is 1 to 2 bytes, whereas in the case of speech, 64 Kbits (phone quality) In addition, for a moving image, an information amount of 100 Mbits (current television reception quality) or more per second is required, and it is not realistic to handle the enormous amount of information in the digital format as it is with the information medium. For example, videophones have already been put into practical use by the Integrated Services Digital Network (ISDN) with a transmission speed of 64 Kbit / s to 1.5 Mbits / s, but the video from the TV camera is sent as it is via ISDN. It is impossible.

  Therefore, what is needed is information compression technology. For example, in the case of videophones, the H.261 and H.263 standards that have been internationally standardized by the ITU-T (International Telecommunication Union Telecommunication Standardization Sector) are required. A moving image compression technique is used (for example, see Non-Patent Document 1). Also, according to the MPEG-1 standard information compression technology, it is possible to put image information together with audio information on a normal music CD (compact disc).

  Here, MPEG (Moving Picture Experts Group) is an international standard for moving picture signal compression, and MPEG-1 is up to 1.5 Mbps for moving picture signals, that is, up to about 1 / 100th of TV signal information. It is a standard to compress. In addition, since the transmission speed for the MPEG-1 standard is mainly limited to about 1.5 Mbps, MPEG-2 standardized to meet the demand for higher image quality has 2 video signals. Compressed to 15Mbps. Furthermore, at present, the working group (ISO / IEC JTC1 / SC29 / WG11), which has been standardizing with MPEG-1 and MPEG-2, has achieved a compression ratio that exceeds MPEG-1 and MPEG-2, and further, on a per-object basis. MPEG-4, which enables encoding / decoding / operation and realizes new functions required in the multimedia era, has been standardized. In MPEG-4, it was originally aimed at standardizing a low bit rate encoding method, but now it has been extended to a more general purpose encoding including a high bit rate including interlaced images.

  In the above moving image coding, the amount of information is generally compressed using redundancy in the spatial direction and time direction of a moving image. Here, inter-picture predictive coding is used as a method of using temporal redundancy. In inter-picture predictive coding, when a certain picture is coded, a picture that is temporally forward or backward is used as a reference picture. Then, the amount of motion (motion vector) from the reference picture is detected, and the amount of information is compressed by removing the redundancy in the spatial direction for the difference value between the motion compensated picture and the picture to be encoded. Do.

  MPEG-1, MPEG-2, MPEG-4, H.264. 263, H.M. In a moving image coding scheme such as 26L, a picture that does not perform inter-picture predictive coding, that is, performs intra-picture coding is called an I picture. Here, a picture means one encoding unit that includes both a frame and a field. In addition, a picture that is inter-picture predictively encoded with reference to one picture is called a P picture, and a picture that is inter-picture predictively encoded with reference to two processed pictures is called a B picture.

  FIG. 18 is a relationship display diagram showing the prediction relationship of each picture in the above moving image coding system.

  In FIG. 18, the vertical line indicates one picture, and the picture type (I, P, B) is shown at the lower right of each picture. The arrows in FIG. 18 indicate that the picture at the end of the arrow performs inter-picture predictive coding using the picture at the start of the arrow as a reference picture. For example, the second B picture from the beginning is encoded by using the first I picture and the fourth P picture from the beginning as reference pictures.

  MPEG-4 and H.264 In a moving picture coding scheme such as 26L, a coding mode called a direct mode can be selected for coding a B picture.

  The inter picture predictive coding method in the direct mode will be described with reference to FIG.

  FIG. 19 is an explanatory diagram for explaining an inter-picture predictive encoding method in the direct mode.

  Now, assume that block C of picture B3 is encoded in direct mode. In this case, the motion vector MVp of the block X at the same position as the block C in the reference picture (in this case, the picture P4 which is the backward reference picture) encoded immediately before the picture B3 is used. The motion vector MVp is a motion vector used when the block X is encoded, and refers to the picture P1. For block C, bi-directional prediction is performed from pictures P1 and P4, which are reference pictures, using a motion vector parallel to motion vector MVp. The motion vector used when coding the block C in this case is the motion vector MVFc for the picture P1 and the motion vector MVBc for the picture P4.

  Also, MPEG-4 and H.264. In a moving image encoding scheme such as 26L, when a motion vector is encoded, a difference value between a predicted value from a motion vector of a neighboring block and a motion vector of an encoding target block is encoded. Hereinafter, when simply referred to as “predicted value”, it indicates a predicted value of a motion vector. In many cases, since the motion vectors of neighboring blocks have the same direction and size, by encoding the difference value from the predicted value from the motion vectors of the neighboring blocks, the coding amount of the motion vector is reduced. Reduction can be achieved.

  Here, a motion vector encoding method in MPEG-4 will be described with reference to FIG.

  FIG. 20 is an explanatory diagram for describing a method of encoding the motion vector MV of the encoding target block A in MPEG-4.

  In (a) to (d) of FIG. 20, blocks indicated by thick frames indicate 16 × 16 pixel macroblocks, and there are four 8 × 8 pixel blocks. Here, it is assumed that a motion vector is obtained in units of 8 × 8 pixel blocks.

  As shown in FIG. 20A, with respect to the encoding target block A located at the upper left in the macro block, the motion vector MVb of the peripheral block B on the left side and the motion vector of the peripheral block C on the upper side. A difference value between the prediction value obtained from MVc and the motion vector MVd of the peripheral block D on the upper right side and the motion vector MV of the encoding target block A is encoded.

  Similarly, as shown in FIG. 20B, for the encoding target block A located at the upper right in the macroblock, the motion vector MVb of the peripheral block B on the left side, the peripheral block on the upper side A difference value between the predicted value obtained from the motion vector MVc of C and the motion vector MVd of the peripheral block D on the upper right side and the motion vector MV of the encoding target block A is encoded.

  Also, as shown in FIG. 20 (c), with respect to the encoding target block A located at the lower left in the macroblock, the motion vector MVb of the peripheral block B on the left side and the peripheral block C on the upper side. The difference value between the motion vector MVc and the predicted value obtained from the motion vector MVd of the peripheral block D on the upper right side and the motion vector MV of the encoding target block A is encoded.

  Then, as shown in FIG. 20D, for the encoding target block A located at the lower right in the macroblock, the motion vector MVb of the peripheral block B on the left side, the peripheral block on the upper left side A difference value between the predicted value obtained from the motion vector MVc of C and the motion vector MVd of the upper peripheral block D and the motion vector MV of the encoding target block A is encoded. Here, the predicted value is obtained by taking a median value for each of the horizontal and vertical components of the three motion vectors MVb, MVc, and MVd.

  Next, H. A motion vector encoding method in 26L will be described with reference to FIG.

  FIG. It is explanatory drawing for demonstrating the encoding method of the motion vector MV of the encoding target block A in 26L.

  The encoding target block A is a block of 4 × 4 pixels, 8 × 8 pixels, or 16 × 16 pixels. When the motion vector of the encoding target block A is encoded, the left side of the encoding target block A is encoded. The motion vector of the peripheral block B including the pixel b positioned at the position B, the motion vector of the peripheral block C including the pixel c positioned above the encoding target block A, and the pixel d positioned on the upper right side of the encoding target block A The motion vector of the peripheral block D including is used. Note that the sizes of the peripheral blocks B, C, and D are not limited to the sizes indicated by the dotted lines in FIG.

  FIG. 22 is a flowchart showing a procedure in which the motion vector MV of the encoding target block A is encoded using such motion vectors of the peripheral blocks B, C, and D.

  First, a peripheral block referring to the same picture as the encoding target block A is specified from the peripheral blocks B, C, and D (step S502), and the number of the specified peripheral blocks is determined (step S504).

  If the number of peripheral blocks determined in step S504 is one, the motion vector of the one peripheral block referring to the same picture is used as the predicted value of the motion vector MV of the encoding target block A. (Step S506).

  If the number of peripheral blocks determined in step S504 is other than one, the motion vector of the peripheral block referring to a picture different from the encoding target block A among the peripheral blocks B, C, and D is set to 0. (Step S507). Then, the median value of the motion vectors of the peripheral blocks B, C, and D is set as the predicted value of the motion vector MV of the encoding target block A (step S508).

  In this way, using the prediction value derived in step S506 or step S508, a difference value between the prediction value and the motion vector MV of the encoding target block A is obtained, and the difference value is encoded (step S510).

  As described above, MPEG-4 and H.264 have been described. In the 26L motion vector encoding method, when encoding a motion vector of an encoding target block, motion vectors of peripheral blocks are used.

  However, there are cases where motion vectors are not encoded for neighboring blocks. For example, the peripheral block is processed by intra-picture encoding, the B picture is processed as a direct mode, or the P picture is processed as a skip mode. In such a case, the peripheral block is encoded using the motion vector of the other block except in the case of intra-picture encoding. In other cases, the peripheral block is motion-detected. It is encoded using its own motion vector based on the result.

Therefore, the conventional motion vector encoding method does not have a motion vector based on the motion detection result as described above in three peripheral blocks, and there is one peripheral block encoded using the motion vector of another block. If there are two, the motion vector of the neighboring block is processed as 0. If there are two, the motion vector of the remaining one neighboring block is used as a prediction value. If there are three, the prediction is performed. The value is set to 0 and the motion vector encoding process is performed.
Information technology -Coding of audio-visual objects -Part2: video (ISO / IEC 14496-2), pp.146-148, 1999.12.1

  However, in the direct mode and the skip mode, although motion vector information is not encoded, a motion compensation process equivalent to the case of using its own motion vector based on the detection result is actually performed. Therefore, in the above-described conventional method, when the peripheral blocks are encoded in the direct mode or the skip mode, the motion vectors of the peripheral blocks are not used as prediction value candidates. There is a problem that the prediction capability of the motion vector prediction value is lowered, and the coding efficiency is lowered accordingly.

  The present invention solves the above-described problems, and an object of the present invention is to provide a motion vector encoding method and a motion vector decoding method in which the encoding efficiency is improved by increasing the prediction capability of the prediction value of the motion vector. .

  In order to achieve the above object, a motion vector encoding method according to the present invention is a motion vector encoding method for encoding a motion vector of a block constituting a picture of a moving image, and is the target of encoding. A peripheral block specifying step that specifies a peripheral block that has already been encoded around the block; a determination step that determines whether or not the peripheral block is encoded using a motion vector of another block; and When it is determined in the determination step that the peripheral block is encoded using the motion vector of another block, the motion vector obtained from the motion vector of the other block is used as the motion vector of the peripheral block. A prediction step of deriving a prediction value of a motion vector of the encoding target block; and the encoding target block The motion vectors, characterized in that it comprises an encoding step of encoding by using the prediction value.

The motion vector decoding method according to the present invention is a motion vector decoding method for decoding an encoded motion vector of a block constituting a moving picture, and is provided around the block to be decoded. A peripheral block specifying step for specifying a peripheral block that has already been decoded, and a predicted motion vector deriving step for deriving a predicted motion vector of the block to be decoded using a motion vector of the peripheral block; A motion vector decoding step of decoding a motion vector of the block to be decoded using the predicted motion vector, wherein the peripheral block uses a motion vector of another block In the case of predictive decoding, a motion vector obtained using the motion vector of the other block, The motion vectors used in predicting decoding the neighboring block, in the predicted motion vector deriving step comprises using as the motion vector of the neighboring blocks.
The motion vector decoding method according to the present invention is a motion vector decoding method for decoding an encoded motion vector of a block constituting a picture of a moving image, wherein the block to be decoded is a motion vector decoding method. A peripheral block specifying step for specifying a peripheral block that has already been decoded in the periphery, a determining step for determining whether or not the peripheral block has been encoded using a motion vector of another block, and the determining step When it is determined that the peripheral block has been encoded using the motion vector of another block, the motion vector obtained from the motion vector of the other block is used as the motion vector of the peripheral block, and the decoding is performed. A prediction step for deriving a prediction value of a motion vector of a block to be encoded, and a code of the block to be decoded A motion vector, characterized in that it comprises a decoding step of decoding by using the prediction value.

  The present invention relates to a moving picture encoding apparatus and program using the motion vector encoding method, a storage medium storing the program, a moving picture decoding apparatus and program using the motion vector decoding method, and a program thereof. It can also be realized as a storage medium for storing.

  As is clear from the above description, the motion vector encoding method according to the present invention is a motion vector encoding method for encoding a motion vector of a block constituting a moving picture, A peripheral block specifying step for specifying a peripheral block that has already been encoded around the block, and a determining step for determining whether or not the peripheral block is encoded using a motion vector of another block When the determination step determines that the peripheral block is encoded using the motion vector of another block, the motion vector obtained from the motion vector of the other block is used as the motion of the peripheral block. A prediction step for deriving a prediction value of a motion vector of the encoding target block, which is used as a vector, and the encoding The motion vector elephant block, characterized in that it comprises an encoding step of encoding by using the prediction value.

  Thereby, when the motion vector of the encoding target block is encoded using the prediction value derived from the motion vector of the peripheral block, the peripheral block is encoded using the motion vector of the other block. In this case, since the motion vector of the surrounding block is set to a motion vector obtained from the motion vector of the other block without setting it to 0, the prediction capability of the predicted value can be improved. The encoding efficiency can be improved.

  The motion vector decoding method according to the present invention is a motion vector decoding method for decoding an encoded motion vector of a block constituting a moving picture, which is a decoding target. A peripheral block specifying step that specifies a peripheral block that has already been decoded around the block; a determination step that determines whether or not the peripheral block has been encoded using a motion vector of another block; and When it is determined in the determination step that the peripheral block has been encoded using the motion vector of another block, the motion vector obtained from the motion vector of the other block is used as the motion vector of the peripheral block, A prediction step of deriving a prediction value of a motion vector of the decoding target block; and the decoding target block The encoded motion vector, characterized in that it comprises a decoding step of decoding by using the prediction value.

  Thereby, the motion vector encoded by the motion vector encoding method according to the present invention can be correctly decoded, and its practical value is high.

(Embodiment 1)
Hereinafter, a moving picture coding apparatus according to a first embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram of a moving picture coding apparatus 100 according to the first embodiment of the present invention.

  This moving image encoding apparatus 100 has improved encoding efficiency by increasing the prediction capability of a motion vector prediction value, and includes a frame memory 101, a difference calculation unit 102, a prediction error encoding unit 103, a code string, Generation unit 104, prediction error decoding unit 105, addition operation unit 106, frame memory 107, motion vector detection unit 108, mode selection unit 109, encoding control unit 110, switches 111 to 115, motion vector storage unit 116, and motion A vector encoding unit 117 is provided.

  The frame memory 101 is an image memory that holds an input image in units of pictures, and outputs the input images acquired in time order in units of pictures in the order of encoding. The rearrangement is controlled by the encoding control unit 110.

  FIG. 2A shows a picture that is input to the frame memory 101.

  In FIG. 2A, the vertical line indicates a picture, and among the symbols shown at the lower right of each picture, the first letter alphabet indicates the picture type (I, P or B), and the second and subsequent letters. The numbers indicate picture numbers in time order. The pictures input to the frame memory 101 are rearranged in the encoding order. The rearrangement to the coding order is performed based on the reference relationship in the inter-picture predictive coding, and the pictures used as the reference pictures are arranged before the pictures using the pictures as the reference pictures. Be replaced. For example, the reference relationship between the pictures P7 to P13 is as indicated by the arrows shown in FIG. In FIG. 2A, the start point of the arrow indicates the picture to be referred to, and the end point of the arrow indicates the picture to be referred to. In this case, the result of rearranging the pictures in FIG. 2A is as shown in FIG.

  FIG. 2B shows a state where the input pictures are rearranged as shown in FIG. Each picture rearranged in the frame memory 101 in this way is read in units of macroblocks. Here, the macroblock has a size of horizontal 16 × vertical 16 pixels.

  The difference calculation unit 102 acquires image data in units of macroblocks from the frame memory 101 via the switch 111 and acquires a motion compensated image from the mode selection unit 109. The difference calculation unit 102 calculates the difference between the image data in units of macroblocks and the motion compensated image, and generates and outputs a prediction error image.

  The prediction error encoding unit 103 encodes the image data acquired from the frame memory 101 via the switch 112 or the prediction error image obtained by the difference calculation unit 102 by frequency conversion such as discrete cosine transform or quantization. By performing processing, encoded data is created. For example, frequency conversion and quantization processing are performed in units of horizontal 8 × vertical 8 pixels. Then, the prediction error encoding unit 103 outputs the encoded data to the code string generation unit 104 and the prediction error decoding unit 105.

  The code string generation unit 104 performs variable length encoding on the encoded data from the prediction error encoding unit 103, converts the encoded data into a format of an encoded bit stream for output, and further a motion vector encoding unit 117. A code string is generated by adding motion vector information input from, information on encoding mode input from the mode selection unit 109, other header information, and the like.

  The prediction error decoding unit 105 performs inverse frequency transform such as inverse discrete cosine transform after decoding the encoded data from the prediction error encoding unit 103, and decodes it into a prediction error image.

  The addition operation unit 106 adds the motion compensated image to the prediction error image that is the decoding result, and outputs a decoded image that is an image data that has been encoded and decoded and that represents an image of one picture.

  The frame memory 107 is an image memory that holds a picture used as a reference picture at the time of encoding other pictures among decoded pictures output from the addition operation unit 106 in units of pictures.

  The motion vector detection unit 108 detects a motion vector for each block in the macroblock to be encoded using the decoded image stored in the frame memory 107 as a reference picture. The detected motion vector is output to the mode selection unit 109.

  The mode selection unit 109 determines a macroblock coding mode using the motion vector detected by the motion vector detection unit 108. Here, the encoding mode indicates how the macroblock is encoded. For example, when the encoding target picture is a P picture, the mode selection unit 109 performs intra-picture encoding, inter-picture prediction encoding using a motion vector, and skip mode (motion determined from motion vectors of other blocks). By performing predictive coding using a vector, the motion vector is not coded, and as a result of the prediction error coding, the coefficient values are all 0, and inter-picture predictive coding in which the coefficient values are not coded) , One of them is determined as the encoding mode. In general, a coding mode that minimizes a coding error with a predetermined bit amount is determined.

  The mode selection unit 109 outputs the determined encoding mode to the code stream generation unit 104 and the motion vector used in the encoding mode to the motion vector encoding unit 117. Further, when the determined encoding mode is inter-picture prediction encoding using a motion vector, the mode selection unit 109 sets the motion vector and encoding mode used in the inter-picture prediction encoding to the motion vector storage unit 116. Remember me.

  Further, the mode selection unit 109 creates a motion compensated image by performing motion compensation based on the determined coding mode and the motion vector detected by the motion vector detection unit 108, and performs a difference calculation on the motion compensated image. Output to the unit 102 and the addition operation unit 106. However, when intra-picture encoding is selected, no motion compensated image is output. Further, when intra-picture encoding is selected by the mode selection unit 109, the mode selection unit 109 sets both switches 111, 111 so that the switch 111 is connected to the terminal a and the switch 112 is connected to the terminal c. When the inter-picture prediction encoding is selected, both switches 111 and 112 are controlled so that the switch 112 is connected to the terminal b and the switch 112 is connected to the terminal d. The motion compensation described above is performed in units of blocks (here, 8 × 8 pixels).

  The encoding control unit 110 determines which type of picture (I, P, or B picture) to encode the input picture, and controls the switch switches 113, 114, and 115 according to the picture type. Here, for example, a method of periodically assigning a picture type is generally used for determining the picture type.

  The motion vector storage unit 116 acquires the motion vector and encoding mode used in inter-picture predictive encoding from the mode selection unit 109 and stores them.

  When the mode selection unit 109 selects inter-picture predictive encoding using a motion vector, the motion vector encoding unit 117 uses the method described with reference to FIGS. Is encoded. That is, the motion vector encoding unit 117 identifies three peripheral blocks around the encoding target block, determines a prediction value from the motion vectors of these peripheral blocks, and becomes a target of the prediction value and encoding. The difference value with the motion vector of the current block is encoded.

  In addition, when encoding the motion vector of the current block, the motion vector encoding unit 117 according to the present embodiment uses the motion vectors of other blocks such as skip mode and direct mode as the peripheral blocks. If the motion vector of the peripheral block is not set to 0 as in the conventional example, the motion vector obtained from the motion vector of the other block at the time of encoding the peripheral block is Treat as motion vector of surrounding blocks.

  FIG. 3 is a flowchart showing a general operation of the motion vector encoding unit 117 in the present embodiment.

  First, the motion vector encoding unit 117 identifies three peripheral blocks that have already been encoded around the encoding target block (step S100).

  Then, the motion vector encoding unit 117 encodes each of the identified peripheral blocks without using the peripheral block Ba encoded using the motion vector of the other block or the motion vector of the other block. It is determined whether it is a peripheral block Bb (step S102).

  As a result, the motion vector encoding unit 117 determines whether or not the peripheral block Ba is included in the three specified peripheral blocks (step S104).

  When it is determined in step S104 that the peripheral block Ba is included (Y in step S104), the motion vector encoding unit 117 is obtained from the motion vectors of other blocks to encode the peripheral block Ba. The motion vector is treated as the motion vector of the surrounding block Ba, and the predicted value is derived from the motion vectors of the three surrounding blocks as described above (step S106).

  On the other hand, when it is determined in step S104 that the peripheral block Ba is not included (N in step S104), the motion vector encoding unit 117 performs motion detection based on the respective motion detection and mode selection results of the three peripheral blocks Bb. A predicted value is derived from the vector (step S108).

  Then, the motion vector encoding unit 117 encodes the difference between the motion vector of the encoding target block and the prediction value derived in steps S106 and S108 (step S110). The motion vector encoding unit 117 outputs the motion vector encoded in this way to the code string generation unit 104.

  Here, the encoding process of the moving image encoding apparatus 100 as described above will be specifically described by taking the encoding of the picture P13 and the picture B11 shown in FIG. 2 as an example.

<Encoding process of picture P13>
Since the picture P13 is a P picture, the moving picture coding apparatus 100 performs inter-picture predictive coding using another one picture as a reference picture when coding the picture P13. In this case, the reference picture is the picture P10. The picture P10 has already been encoded, and the decoded image of the picture P10 is stored in the frame memory 107.

  The encoding control unit 110 controls each switch so that the switches 113, 114, and 115 are turned on in encoding the P picture. Therefore, the macroblock of the picture P13 read from the frame memory 101 is acquired by the motion vector detection unit 108, the mode selection unit 109, and the difference calculation unit 102.

  The motion vector detection unit 108 uses the decoded image of the picture P10 stored in the frame memory 107 as a reference picture, detects a motion vector for each block in the macroblock, and uses the detected motion vector as a mode. Output to the selection unit 109.

  The mode selection unit 109 uses the motion vector detected by the motion vector detection unit 108 to determine the encoding mode of the macroblock of the picture P13. That is, since the picture P13 is a P picture, the mode selection unit 109 calculates the intra-picture encoding, the inter-picture prediction encoding using the motion vector, and the skip mode (determined from the motion vectors of other blocks as described above. Inter-picture predictive coding in which no motion vector is encoded and all coefficient values are 0 as a result of prediction error encoding, and the coefficient values are not encoded. To determine the encoding mode.

  Then, when the mode selection unit 109 selects inter-picture predictive encoding using a motion vector as described above, the motion vector encoding unit 117 according to the present embodiment uses the method described with reference to FIG. The motion vector of the encoding target block of P13 is encoded. If the peripheral blocks around the encoding target block are encoded in the skip mode, the motion vector of the peripheral block is set to 0. Instead, a motion vector obtained from another block in order to encode the peripheral block is handled as a motion vector of the peripheral block.

  A description will be given of a method of encoding a motion vector of an encoding target block when such a peripheral block is encoded in the skip mode.

  FIG. 4 is an explanatory diagram for explaining how the peripheral block C is encoded in the skip mode.

  As shown in FIG. 4, when the peripheral block C of the picture P13 is encoded in the skip mode, the motion vector MVe of the block E, the motion vector MVf of the block F, which are located around the peripheral block C, The median value of the motion vector MVg of the block G is obtained, and the peripheral block C is encoded using the motion vector MVcm indicating the median value. Here, the median value of the motion vector is obtained, for example, by obtaining the median value for each of the horizontal component and the vertical component.

  When the motion vector encoding unit 117 encodes the motion vector of the encoding target block A shown in FIG. 4, the motion vector encoding unit 117 specifies three peripheral blocks B, C, and D around the encoding target block A (block B , C, D (see FIG. 20 and FIG. 21), it is determined whether each of the peripheral blocks B, C, D is a block encoded using the motion vector of another block. As a result, if the motion vector encoding unit 117 determines that only the peripheral block C is encoded in the skip mode, that is, encoded using another block, the motion vector encoding unit 117 performs other encoding to encode the peripheral block C as described above. The median value (motion vector MVcm) obtained from the motion vectors of the blocks E, F, and G, which are the blocks of, is treated as the motion vector of the peripheral block C. Is obtained, and this median value is used as the predicted value of the motion vector of the encoding target block A. Then, the motion vector encoding unit 117 encodes a difference value between the predicted value and the motion vector of the encoding target block A.

  The motion vector storage unit 116 stores the encoding mode of the encoded block. Based on the encoding mode stored in the motion vector storage unit 116, the motion vector encoding unit 117 , C, and D are discriminated whether or not they are encoded blocks using the motion vectors of other blocks. Furthermore, the motion vector storage unit 116 stores the motion vector of a block that is encoded using its own motion vector detected from the reference picture without using the motion vector of another block. is doing. That is, the motion vector storage unit 116 stores the respective motion vectors MVe, MVf, and MVg of the blocks E, F, and G, and the motion vector encoding unit 117 encodes the motion vector of the encoding target block A. When doing so, the above-mentioned motion vector MVcm is obtained for the peripheral block C using these motion vectors stored in the motion vector storage unit 116. Note that the motion vector storage unit 116 stores in advance a motion vector obtained by taking a median value for encoding a block encoded using a motion vector of another block. You can leave it. In this case, since the motion vector storage unit 116 stores the motion vector MVcm in advance, when the motion vector encoding unit 117 encodes the motion vector of the block A to be encoded, There is no need to obtain the vector MVcm, and the motion vector MVcm stored in advance by the motion vector storage unit 116 can be used as the motion vector of the peripheral block C as it is.

  On the other hand, the prediction error image indicating the difference between the macroblock to be encoded of the picture P13 and the motion compensated image is encoded by the prediction error encoding unit 103 and the code string generation unit 104 and generated as encoded data. The information of the motion vector encoded as described above is added to the encoded data by the code string generation unit 104. However, for the macroblock encoded in the skip mode, the difference between the macroblock and the motion compensated image is 0, and the motion vector information is not added to the encoded data.

  Thereafter, the encoding process is performed on the remaining macroblocks of the picture P13 by the same process. When all macroblocks in the picture P13 are processed, the encoding process for the picture B11 is performed next.

<Encoding process of picture B11>
Since the picture B11 is a B picture, the moving picture coding apparatus 100 performs inter-picture predictive coding using the other two pictures as reference pictures when coding the picture B11. As shown in FIG. 2, the reference pictures in this case are a picture P10 in front of the picture B11 and a picture P13 in the rear of the picture B11. These pictures P10 and P13 have already been encoded, and the decoded images of the pictures P10 and P13 are stored in the frame memory 107.

  The encoding control unit 110 controls each switch so that the switch 113 is turned on and the switches 114 and 115 are turned off in encoding the B picture. Therefore, the macroblock of the picture B11 read from the frame memory 101 is acquired by the motion vector detection unit 108, the mode selection unit 109, and the difference calculation unit 102.

  The motion vector detection unit 108 uses the decoded image of the picture P10 stored in the frame memory 107 as a forward reference picture, and uses the decoded image of the picture P13 as a backward reference picture, so that each block in the macroblock is detected. Thus, the forward motion vector and the backward motion vector are detected, and the detected forward motion vector and backward motion vector are output to the mode selection unit 109.

  The mode selection unit 109 determines the coding mode of the macroblock of the picture B11 using the forward motion vector and the backward motion vector detected by the motion vector detection unit 108. That is, since the picture B11 is a B picture, the mode selection unit 109 performs, for example, intra-picture encoding, inter-picture prediction encoding using a forward motion vector, inter-picture prediction encoding using a backward motion vector, bidirectional Codes from inter-picture predictive coding using motion vectors and direct mode (inter-picture predictive coding that performs motion compensation using motion vectors obtained from motion vectors of other blocks and does not encode motion vectors) Determine the mode.

  Then, when the mode selection unit 109 selects inter-picture predictive encoding using a motion vector as described above, the motion vector encoding unit 117 according to the present embodiment uses the method described with reference to FIG. The motion vector of the encoding target block of B13 is encoded.

  Specifically, when inter-picture predictive coding using a bidirectional motion vector is selected by the mode selection unit 109, the motion vector coding unit 117 codes the motion vector of the block to be coded as follows. To do.

  FIG. 5 is an explanatory diagram for explaining inter-picture predictive coding using bidirectional motion vectors.

  When the motion vector encoding unit 117 encodes the motion vector of the encoding target block A, the motion vector encoding unit 117 performs encoding on the forward motion vector MVF and the backward motion vector MVB.

  That is, the motion vector encoding unit 117 uses the median value of the forward motion vectors MVF1, MVF2, and MVF3 of the peripheral blocks B, C, and D as the predicted value of the forward motion vector MVF, and the forward motion vector MVF and its predicted value. The difference value is encoded. Then, the motion vector encoding unit 117 uses the median value of the backward motion vectors MVB1, MVB2, and MVB3 of the peripheral blocks B, C, and D as the predicted value of the backward motion vector MVB, and the backward motion vector MVB and its predicted value. The difference value is encoded. Here, the median value of the motion vector is obtained by taking the median value for each of the horizontal component and the vertical component, for example.

  Here, the motion vector encoding unit 117 according to the present embodiment encodes the motion vector of the B picture encoding target block, and if the peripheral block is encoded in the direct mode, Instead of setting the motion vector to 0, a motion vector obtained from another block in order to encode the peripheral block is set as a motion vector of the peripheral block. There are two types of direct modes: temporal direct mode and spatial direct mode.

  First, a description will be given of a method of encoding a motion vector of an encoding target block when peripheral blocks are encoded in a temporal direct mode.

  FIG. 6 is an explanatory diagram for explaining how the peripheral block C is encoded in the temporal direct mode.

  As shown in FIG. 6, when the peripheral block C of the picture B11 is encoded in the direct mode, the block X at the same position as the peripheral block C in the picture P13 which is the backward reference picture encoded immediately before. The motion vector MVp is used. The motion vector MVp is a motion vector used when the block X is encoded, and is stored in the motion vector storage unit 116. This motion vector MVp refers to the picture P10. For encoding of the peripheral block C, bi-directional prediction is performed from the picture P10 and the picture P13 which are reference pictures using a motion vector parallel to the motion vector MVp. In this case, the motion vectors used when coding the peripheral block C are the motion vector MVFc for the picture P10 and the motion vector MVBc for the picture P13.

Here, the magnitude of the motion vector MVFc that is the forward motion vector is mvf, the magnitude of the motion vector MVBc that is the backward motion vector is mvb, the magnitude of the motion vector MVp is mvp, and the picture to be encoded (picture B11) ) Of the backward reference picture (picture P13) and the picture (picture P10) referenced by the block of the backward reference picture is TRD, the picture to be coded (picture B11) and the block of the backward reference picture If the temporal distance to the picture (picture P10) referred to by TRB is TRB, mvf and mvb are obtained by (Expression 1) and (Expression 2) shown below, respectively.
mvf = mvp × TRB / TRD ---- (Equation 1)
mvb = (TRB-TRD) × mvp / TRD ---- (Equation 2)

  Here, mvf and mvb represent the horizontal component and the vertical component of the motion vector, respectively. The direction of the motion vector MVp is indicated by a positive value, and the direction opposite to the motion vector MVp is indicated by a negative value.

  The peripheral block C is encoded using the motion vectors MVFc and MVBc thus obtained.

  When encoding the motion vectors MVF and MVB of the encoding target block A shown in FIG. 5, the motion vector encoding unit 117 specifies three peripheral blocks B, C, and D around the encoding target block A. It is determined whether each of the peripheral blocks B, C, and D is a block encoded using a motion vector of another block. As a result, when the motion vector encoding unit 117 determines that only the peripheral block C is encoded in the temporal direct mode, that is, encoded using the motion vector of another block, as shown in FIG. The motion vectors MVFc and MVBc obtained from the motion vector MVp of the block X, which is another block in order to encode the peripheral block C, are treated as the motion vectors of the peripheral block C, and these motion vectors MVFc and MVBc and the peripheral block B , D to obtain the median value of each of the motion vectors, the prediction value of the motion vector of the encoding target block A is derived. Such derivation of the predicted value is performed separately in the forward direction and the backward direction. Then, the motion vector encoding unit 117 encodes a difference value between the predicted value and the motion vectors MVF and MVB of the encoding target block A.

  The motion vector storage unit 116 stores the encoding mode of the encoded block. Based on the encoding mode stored in the motion vector storage unit 116, the motion vector encoding unit 117 , C, and D are discriminated whether or not they are encoded blocks using the motion vectors of other blocks. Furthermore, the motion vector storage unit 116 stores the motion vector of a block that is encoded using its own motion vector detected from the reference picture without using the motion vector of another block. is doing. That is, when encoding the motion vector of the encoding target block A, the motion vector encoding unit 117 uses the motion vector stored in the motion vector storage unit 116 as it is for the peripheral blocks B and D. For the block C, the motion vector MVp of the block X stored in the motion vector storage unit 116 is read to obtain the motion vectors MVFc and MVBc. It should be noted that the motion vector storage unit 116 stores in advance a motion vector obtained from a motion vector of another block in order to encode that block for a block encoded using the motion vector of another block. You can keep it. In this case, since the motion vector storage unit 116 stores the motion vectors MVFc and MVBc in advance, when the motion vector encoding unit 117 encodes the motion vector of the encoding target block A, the motion vector storage unit 116 Thus, it is not necessary to read out the motion vector MVp of the block X and obtain the motion vectors MVFc and MVBc using (Equation 1) and (Equation 2). It can be used as a motion vector for block C.

  Next, a description will be given of a method for encoding a motion vector of an encoding target block when peripheral blocks are encoded in a spatial direct mode.

  FIG. 7 is an explanatory diagram for explaining a state in which peripheral blocks are encoded in the spatial direct mode.

  As shown in FIG. 7, when the peripheral block C of the picture B11 is encoded in the spatial direct mode, the motion vectors MVFe and MVBe of the block E around the peripheral block C and the motion vector MVFf of the block F , MVBf and the motion vectors MVFg and MVBg of the block G are encoded using motion vectors MVFc and MVBc which are obtained by dividing each of them in the front-rear direction and taking the median value.

  When encoding the motion vectors MVF and MVB of the encoding target block A shown in FIG. 5, the motion vector encoding unit 117 specifies three peripheral blocks B, C, and D around the encoding target block A. It is determined whether each of the peripheral blocks B, C, and D is a block encoded using a motion vector of another block. As a result, when the motion vector encoding unit 117 determines that only the peripheral block C is encoded in the spatial direct mode, that is, encoded using the motion vector of another block, as shown in FIG. The motion vectors MVFc and MVBc obtained from the motion vectors of the blocks E, F, and C, which are other blocks in order to encode the peripheral block C, are treated as the motion vectors of the peripheral block C. These motion vectors and the peripheral block B , D to obtain the median value of each of the motion vectors, the prediction value of the motion vector of the encoding target block A is derived. Then, the motion vector encoding unit 117 encodes a difference value between the predicted value and the motion vectors MVF and MVB of the encoding target block A.

  In addition, the motion vector storage unit 116 stores the motion vector of a block that is encoded using its own motion vector detected from the reference picture without using the motion vector of another block. Therefore, two motion vectors in the front-rear direction are stored for each of the blocks E, F, and G, and the motion vector encoding unit 117 encodes the motion vector of the encoding target block A. The motion vectors MVFc and MVBc are obtained for the peripheral block C using these motion vectors stored in the motion vector storage unit 116. It should be noted that two motion vectors in the front-rear direction obtained by the motion vector storage unit 116 taking a median value to encode a block encoded using the motion vector of another block. May be stored in advance. In this case, since the motion vector storage unit 116 stores the motion vectors MVFc and MVBc in advance, the motion vector encoding unit 117 stores the motion vector of the encoding target block A in the peripheral block C. On the other hand, there is no need to obtain the motion vectors MVFc and MVBc, and the motion vectors MVFc and MVBc stored in the motion vector storage unit 116 can be used as they are as the motion vectors of the peripheral block C.

  Thus, when the peripheral block C is encoded in the temporal direct mode described above, the motion vector of the backward reference picture (picture P13 in the above example) of the encoding target picture is stored in the motion vector storage unit 116. Although it was necessary to store them, when the peripheral block C is encoded in the spatial direct mode, the storage can be omitted.

  Here, when encoding the motion vector of the encoding target block, the moving image encoding apparatus 100 processes the peripheral blocks in the vicinity thereof by intra-picture encoding instead of inter-picture predictive encoding as described above. If so, perform exceptional processing.

  For example, when there is one block encoded by intra-picture encoding among three neighboring blocks, the motion vector encoding unit 117 of the video encoding device 100 sets the motion vector of the block to 0. Process. When there are two peripheral blocks encoded by intra-picture encoding, the motion vector encoding unit 117 uses the motion vector of the remaining one peripheral block as a predicted value of the motion vector of the encoding target block. Used as Furthermore, when all the three neighboring blocks are encoded by intra-picture encoding, the motion vector encoding unit 117 sets the motion vector prediction value of the encoding target block to 0 and encodes the motion vector. Process.

  On the other hand, a prediction error image indicating a difference between a macroblock to be encoded of the picture B11 and a motion compensated image is encoded by the prediction error encoding unit 103 and the code string generation unit 104 and generated as encoded data. The information of the motion vector encoded as described above is added to the encoded data by the code string generation unit 104. However, for macroblocks encoded in the direct mode, motion vector information is not added to the encoded data.

  Thereafter, the encoding process is performed on the remaining macroblocks of the picture B11 by the same process. When all macroblocks in picture B11 are processed, the encoding process for picture B12 is performed next.

  As described above, in the motion vector encoding method of the present invention, when the motion vector of each block is encoded, a prediction value is derived from the motion vectors of the peripheral blocks that have already been encoded, and the prediction value and the encoding target are derived. The motion vector is encoded using the motion vector of the block. If the peripheral block is encoded using a motion vector obtained from the motion vector of another block, such as skip mode or direct mode, the above-mentioned information is encoded when the peripheral block is encoded. A prediction value is derived by using a motion vector obtained from the motion vector of another block as a motion vector of its neighboring blocks.

  Thereby, when the motion vector of the encoding target block is encoded using the prediction value derived from the motion vector of the peripheral block, the peripheral block is encoded using the motion vector of the other block. In this case, since the motion vector of the peripheral block is set to the motion vector obtained from the motion vector of the other block without setting it to 0 as in the conventional example, the prediction capability of the predicted value can be improved, As a result, the motion vector encoding efficiency can be improved.

  In this embodiment, the macroblock is a unit of horizontal 16 × vertical 16 pixels, the motion compensation is a block unit of horizontal 8 × vertical 8 pixels, and the encoding of the block prediction error image is horizontal 8 × vertical 8 pixels. However, these units may have different numbers of pixels.

  In the present embodiment, a case has been described in which the median obtained from the motion vectors of three encoded peripheral blocks is used as a predicted value in motion vector encoding. The number of peripheral blocks is 3 Other numbers may be used, and the prediction value determination method may be another method. For example, a method using the motion vector of the left adjacent block as a predicted value may be used, or a method using an average value instead of a median value may be used.

  In the present embodiment, the positions of the peripheral blocks in the motion vector encoding have been described with reference to FIGS. 20 and 21. However, other positions may be used.

  In the present embodiment, the skip mode and the temporal and spatial direct modes have been described as examples of the method of encoding the block to be encoded using the motion vectors of other blocks. Other methods may be used.

  In the present embodiment, the case where the motion vector is encoded by taking the difference between the motion vector of the encoding target block and the predicted value obtained from the motion vector of the surrounding block has been described. May encode the motion vector by a method other than the difference.

  In this embodiment, when a peripheral block is encoded in the spatial direct mode, a median value of motion vectors of three encoded blocks around the peripheral block is obtained, and the center Although the case where a value is handled as a motion vector of a peripheral block has been described, the number of blocks may be other than three, and the motion vector may be determined by another method. For example, a method using the motion vector of the block on the left side as the motion vector of the neighboring block may be used, or a method using an average value instead of the median value may be used.

  In this embodiment, when a B picture block is encoded in the spatial direct mode, two motion vectors in the front-rear direction are obtained for the block. These two motion vectors may be obtained. In this case, the B picture refers to two pictures in one direction forward or backward with respect to the picture.

  Further, in the present embodiment, in the encoding of the P picture, one predetermined picture is referred to (for example, in the encoding of the picture P13, refer to the picture P10), and in the encoding of the B picture, In the above description, reference is made to two predetermined pictures (for example, refer to pictures P10 and P13 in encoding of picture B11), and encoding has been described. The picture to be referred to may be selected and encoded. In such a case, a motion vector prediction value may be generated as shown in FIG.

  FIG. 8 is a flowchart showing an operation in which the motion vector encoding unit 117 derives a prediction value of a motion vector of an encoding target block and encodes the motion vector when a reference picture is selected for each block. is there.

  First, the motion vector encoding unit 117 identifies three peripheral blocks that have already been encoded around the encoding target block (step S300).

  Then, the motion vector encoding unit 117 encodes each of the identified peripheral blocks without using the peripheral block Ba encoded using the motion vector of the other block or the motion vector of the other block. It is determined whether it is a peripheral block Bb (step S302).

  Here, for the peripheral block Ba, the motion vector encoding unit 117 acquires the motion vector used in the encoding and information indicating which reference picture the peripheral block Ba refers to, The motion vector used in the encoding is handled as the motion vector of the peripheral block Ba, and for the peripheral block Bb, the motion vector of the peripheral block Bb and which reference picture the peripheral block Bb refers to are indicated. Information is acquired (step S304).

  Next, based on the information acquired in step S304, the motion vector encoding unit 117 specifies a neighboring block that refers to the same picture as the coding target block among the three neighboring blocks (step S306), and is identified. The number of neighboring blocks is determined (step S308).

  Then, if the number of peripheral blocks determined in step S308 is 1, the motion vector encoding unit 117 calculates the motion vector of the one peripheral block referring to the same picture as the motion of the encoding target block. A predicted value of the vector MV is set (step S310).

  On the other hand, if the number of peripheral blocks determined in step S308 is other than one, the motion vector encoding unit 117 moves the peripheral blocks referring to a picture different from the encoding target block among the three peripheral blocks. The vector is set to 0 (step S312), and the median value of the motion vectors of the three neighboring blocks is set as the predicted value of the motion vector MV of the encoding target block (step S314).

  The motion vector encoding unit 117 uses the prediction value derived in step S310 or step S314 as described above, obtains a difference value between the prediction value and the motion vector MV of the encoding target block, and encodes the difference value. (Step S316).

  In addition, as in the present embodiment, when encoding a motion vector using a motion vector of a spatially adjacent block as a predicted value, the motion vector is stored in the motion vector storage unit 116 for encoding the motion vector. When the motion vector actually used for motion compensation in the skip mode or direct mode is stored in the motion vector storage unit 116 in the motion vector storage unit 116, the amount of motion vector is 1 macroblock line (height is 1 macroblock). It suffices to hold the motion vectors of blocks corresponding to the area whose width is equal to the width of the screen. This is a case where the motion vector actually used for motion compensation in the skip mode or the direct mode is stored in the motion vector storage unit 116, and the peripheral as described with reference to FIGS. 20 and 21 in the present embodiment. This is because when a block is used, a block that is referred to as a peripheral block at the time of coding a motion vector is the past one macroblock slice starting from the current macroblock.

(Embodiment 2)
Hereinafter, a moving picture decoding apparatus 700 according to the second embodiment of the present invention will be described with reference to the drawings.

  FIG. 9 is a block diagram of a moving picture decoding apparatus 700 according to the second embodiment of the present invention.

  The moving picture decoding apparatus 700 shown in FIG. 9 decodes the moving picture encoded by the moving picture encoding apparatus 100 of Embodiment 1, and includes a code string analysis unit 701, prediction error decoding, and the like. 702, a mode decoding unit 703, a motion compensation decoding unit 705, a motion vector storage unit 706, a frame memory 707, an addition operation unit 708, switches 709 and 710, and a motion vector decoding unit 711.

  The code string analysis unit 701 extracts various data from the input code string. The various types of data referred to here include information on coding modes and information on motion vectors. The extracted encoding mode information is output to the mode decoding unit 703. The extracted motion vector information is output to the motion vector decoding unit 711. Further, the extracted prediction error encoded data is output to the prediction error decoding unit 702. The prediction error decoding unit 702 decodes the input prediction error encoded data to generate a prediction error image. The generated prediction error image is output to the switch 709. When the switch 709 is connected to the terminal b, the prediction error image is output to the addition operation unit 708.

  The mode decoding unit 703 controls the switch 709 and the switch 710 with reference to the encoding mode information extracted from the code string. When the coding mode is intra-picture coding, control is performed so that the switch 709 is connected to the terminal a and the switch 710 is connected to the terminal c, and when the coding mode is inter-picture coding. The switch 709 is connected to the terminal b, and the switch 710 is controlled to be connected to the terminal d. Further, the mode decoding unit 703 outputs the encoding mode information to the motion vector decoding unit 711.

  The motion vector decoding unit 711 performs a decoding process on the motion vector information output from the code string analysis unit 701.

  That is, when the coding mode information indicates inter-picture predictive coding using a motion vector, the motion vector decoding unit 711 performs the decoding target block as described with reference to FIGS. On the other hand, a prediction value is derived using motion vectors of peripheral blocks that have already been decoded. For example, as illustrated in FIG. 20, the motion vector decoding unit 711 determines, from the decoding target block A, the motion vector MVb of the peripheral block B, the motion vector MVc of the peripheral block C, and the motion vector MVd of the peripheral block D. Deriving the predicted value. Here, the predicted value is obtained by taking the median obtained for each of the horizontal and vertical components of the three decoded motion vectors MVb, MVc, and MVd. Then, the motion vector decoding unit 711 determines the motion vector MV of the decoding target block A by adding the prediction value to the difference value that is the information on the motion vector output from the code string analysis unit 701.

  In addition, when the encoding mode information is, for example, the skip mode or the temporal or spatial direct mode described above, the motion vector decoding unit 711 extracts only the motion vectors of the peripheral blocks that have already been decoded. To determine the motion vector.

  FIG. 10 is a flowchart showing a general operation of the motion vector decoding unit 711 in the present embodiment. First, the motion vector encoding unit 711 identifies three peripheral blocks that have already been decoded around the decoding target block (step S200).

  Then, the motion vector decoding unit 711 determines whether each of the identified peripheral blocks is a peripheral block Ba that has been encoded using another motion vector or a peripheral block that has been encoded without using another motion vector. It is determined whether it is a block Bb (step S202).

  As a result, the motion vector decoding unit 711 determines whether or not the peripheral block Ba is included in the three specified peripheral blocks (step S204).

  When it is determined in step S204 that the peripheral block Ba is included (Y in step S204), the motion vector decoding unit 711 is obtained from the motion vectors of other blocks in order to decode the peripheral block Ba. The motion vector is treated as the motion vector of the surrounding block Bb, and the prediction value is derived from the motion vectors of the three surrounding blocks as described above (step S206).

  On the other hand, when it is determined in step S206 that the neighboring block Ba is not included (N in step S204), the motion vector decoding unit 711 determines the predicted value from the motion vector based on the detection results of the three neighboring blocks Bb. Is derived (step S208).

  Then, the motion vector decoding unit 711 adds the prediction value derived in steps S206 and S208 to the difference value, which is the motion vector information output from the code string analysis unit 701, so that the code of the decoding target block is encoded. The converted motion vector is decoded (step S210). In addition, the motion vector decoding unit 711 outputs the motion vector thus decoded to the motion compensation decoding unit 705.

  The motion vector storage unit 706 stores the motion vector decoded by the motion vector decoding unit 711 and the encoding mode obtained by the mode decoding unit 703. The motion compensation decoding unit 705 acquires a motion compensated image for each macroblock from the frame memory 707 based on the motion vector decoded by the motion vector decoding unit 711. Then, the motion compensation decoding unit 705 outputs the motion compensated image to the addition operation unit 708. The addition operation unit 708 adds the input prediction error image and the motion compensated image, generates a decoded image, and outputs the generated decoded image to the frame memory 707. The frame memory 707 holds the decoded image generated by the addition operation unit 708 for each frame. The operation of the moving picture decoding apparatus 700 will be described from a general outline operation.

  FIG. 11 is an explanatory diagram for explaining the input / output relationship of the moving picture decoding apparatus 700.

  As shown in FIG. 11A, the moving picture decoding apparatus 700 acquires the code sequences output from the moving picture encoding apparatus 100 according to the first embodiment in the order of output, and includes them in the code strings. The included pictures are sequentially decoded. Then, the moving picture decoding apparatus 700 rearranges the decoded pictures in the display order and outputs them, as shown in (b) of FIG.

  Here, the decoding process of the moving picture decoding apparatus 700 as described above will be specifically described by taking the decoding of the picture P13 and the picture B11 shown in FIG. 11 as an example.

<Decoding process of picture P13>
First, the code string analysis unit 701 of the video decoding device 700 acquires the code string of the picture P13, and extracts mode selection information, motion vector information, and prediction error encoded data from the code string.

  The mode decoding unit 703 refers to the mode selection information extracted from the code sequence of the picture P13 and controls the switches 709 and 710.

  Hereinafter, a case where the mode selection information indicates inter picture predictive coding will be described.

  Based on the mode selection information indicating inter-picture predictive coding from the mode decoding unit 703, the motion vector decoding unit 711 performs the motion vector information extracted from the code sequence of the picture P13 as described above for each block. Performs proper decryption processing.

  Here, when the motion vector decoding unit 711 decodes the motion vector of the block to be decoded of the picture P13, the motion vector decoding unit 711 identifies three peripheral blocks that have already been decoded around the block to be decoded, As a result of determining whether or not these peripheral blocks have been encoded using the motion vectors of other blocks, any of the peripheral blocks have been encoded using other motion vectors, that is, in skip mode. In the case of an encoded block, similar to the motion vector encoding unit 117 of the first embodiment, the motion vector obtained from the motion vector of another block for decoding the peripheral block is used as the peripheral block. As a motion vector. That is, the motion vector decoding unit 711 obtains a median value from the motion vectors of three blocks already decoded around the peripheral block, and treats this as a motion vector of the peripheral block.

  The motion vector storage unit 706 stores the mode selection information from the mode decoding unit 703. Based on the mode selection information stored in the motion vector storage unit 706, the motion vector decoding unit 711 It is determined whether or not each block is a block encoded using the motion vector of another block. Furthermore, the motion vector storage unit 706 stores motion vectors of other blocks used for decoding neighboring blocks. That is, the motion vector storage unit 706 stores the motion vectors of the three blocks around the peripheral block encoded in the skip mode, and the motion vector decoding unit 711 stores the decoding target block. When a motion vector is decoded, a median value is obtained from the motion vectors of the three blocks stored in the motion vector storage unit 706 for the peripheral blocks. The motion vector storage unit 706 previously stores a motion vector obtained by taking a median value for decoding a block that has been encoded using a motion vector of another block. You can keep it. In this case, when the motion vector decoding unit 711 decodes the motion vector of the block to be decoded, there is no need to obtain a motion vector for the peripheral block encoded in the skip mode, and the motion vector storage unit The motion vector stored in 706 can be used as it is as the motion vector of the surrounding blocks.

  On the other hand, the prediction error encoded data for the decoding target macroblock of the picture P13 is decoded by the prediction error decoding unit 702 and generated as a prediction error image, and the switches 709 and 710 are connected to the addition operation unit 708. Therefore, the motion compensated image generated based on the motion vector decoded by the motion vector decoding unit 711 is added to the prediction error image and output to the frame memory 707.

  In addition, when the motion vector decoding unit 711 decodes a motion vector for a P picture, the motion vector and the encoding mode obtained from the mode decoding unit 703 are used to decode a subsequent picture or block. Is stored in the motion vector storage unit 706.

  Thereafter, the remaining macroblocks of the picture P13 are sequentially decoded by the same process. When all the macroblocks of the picture P13 are decoded, the picture B11 is decoded.

<Decoding process of picture B11>
First, the code sequence analysis unit 701 of the video decoding device 700 acquires the code sequence of the picture B11, and extracts mode selection information, motion vector information, and prediction error encoded data from the code sequence.

  The mode decoding unit 703 refers to the mode selection information extracted from the code string of the picture B11 and controls the switches 709 and 710.

  Hereinafter, a case where the mode selection information indicates inter picture predictive coding will be described.

  Based on the mode selection information indicating inter-picture predictive coding from the mode decoding unit 703, the motion vector decoding unit 711 performs the motion vector information extracted from the code string of the picture B11 as described above for each block. Performs proper decryption processing.

  Here, when the motion vector decoding unit 711 decodes the motion vector of the decoding target block of the picture B11, the motion vector decoding unit 711 identifies three peripheral blocks that have already been decoded around the decoding target block, As a result of determining whether or not these peripheral blocks were encoded using the motion vectors of other blocks, a block in which any of the peripheral blocks was encoded using the motion vectors of other blocks, that is, time In the case of a block that has been encoded in a direct or spatial direct mode, the motion vectors of other blocks are used to decode the neighboring blocks as in the motion vector encoding unit 117 of the first embodiment. The motion vector obtained in this way is treated as the motion vector of the surrounding block.

  Specifically, when the peripheral block is encoded in the temporal direct mode, the motion vector decoding unit 711 receives, from the motion vector storage unit 706, the reference picture (picture P13) decoded immediately before. The motion vector of the block located at the same position as the peripheral block encoded in the direct mode is read out. For example, as illustrated in FIG. 6, if the peripheral block C is encoded in the temporal direct mode, the motion vector decoding unit 711 performs the motion after decoding the block X of the picture P13 from the motion vector storage unit 706. Read a vector. Then, using (Equation 1) and (Equation 2), a forward motion vector MVFc and a backward motion vector MVBc used to encode the peripheral block C are obtained, and these motion vectors MVFc and MVBc are obtained as motion vectors of the peripheral block C. Used as

  In the above-described case, the motion vector decoding unit 711 reads the motion vector MVp of the block X at the same position as the peripheral block C encoded in the direct mode in the picture P13 from the motion vector storage unit 706. However, the motion vector storage unit 706 uses the motion vector obtained from the motion vector of the other block to decode the block encoded using the motion vector of the other block. It may be stored in advance. In this case, since the motion vector storage unit 706 stores the motion vectors MVFc and MVBc in advance, the motion vector decoding unit 711 stores the motion vector of the encoding target block A in the peripheral block C. On the other hand, it is not necessary to read the motion vector MVp of the block X and obtain the motion vectors MVFc and MVBc using (Equation 1) and (Equation 2). It can be used as a motion vector of the peripheral block C.

  On the other hand, when the peripheral block is encoded in the spatial direct mode, the motion vector decoding unit 711 calculates the motion vector obtained using the motion vectors of other blocks around the peripheral block. Treat as motion vector of surrounding blocks. For example, in the situation shown in FIG. 7, the motion vector decoding unit 711 performs, on the peripheral block C that has been encoded in the spatial direct mode, three previously decoded blocks E in the vicinity thereof. , F, and G, the median is obtained, and the forward motion vector MVFc and the backward motion vector MVBc indicated by the median are handled as motion vectors of the peripheral block C.

  In addition, since the motion vector storage unit 706 stores the motion vector used for decoding a block that has been encoded without using the motion vector of another block, FIG. In the situation as shown, the motion vectors of the three blocks E, F, G around the peripheral block C encoded in the spatial direct mode are stored, and the motion vector decoding unit 711 When the motion vector of the block A to be decoded is decoded, the motion vectors MVFc and MVBc are calculated from the motion vectors of the three blocks E, F, and G stored in the motion vector storage unit 706 for the peripheral block C. Ask for.

  The motion vector storage unit 706 previously stores a motion vector obtained by taking a median value for decoding a block that has been encoded using a motion vector of another block. You can keep it. In this case, in the situation as shown in FIG. 7, the motion vector storage unit 706 stores the motion vectors MVFc and MVBc in advance, and the motion vector decoding unit 711 stores the motion vector of the block A to be decoded. When decoding a motion vector MVFc and MVBc stored in the motion vector storage unit 706 as they are, it is not necessary to obtain a motion vector for the peripheral block C encoded in the spatial direct mode. It can be used as a C motion vector.

  Here, when the video decoding apparatus 700 decodes the motion vector of the decoding target block, the already decoded peripheral blocks in the vicinity thereof are not inter-picture predictive encoding as described above. If it is processed by inner coding, an exceptional process is performed.

  For example, when there is one peripheral block that has been encoded by intra-picture encoding among three peripheral blocks, the motion vector decoding unit 711 of the video decoding device 700 performs the motion vector of the peripheral block. The process is performed with 0 as 0. When there are two peripheral blocks encoded by intra-picture encoding, the motion vector decoding unit 711 uses the motion vector of the remaining one peripheral block as a predicted value of the motion vector of the decoding target block. Used as Further, when all the three neighboring blocks are encoded by intra-picture encoding, the motion vector decoding unit 711 sets the motion vector prediction value of the decoding target block to 0 and decodes the motion vector. Process.

  On the other hand, the prediction error encoded data for the decoding target macroblock of the picture B11 is decoded by the prediction error decoding unit 702 and generated as a prediction error image, and the switches 709 and 710 are connected to the addition operation unit 708. Therefore, the motion compensated image generated based on the motion vector decoded by the motion vector decoding unit 711 is added to the prediction error image and output to the frame memory 707.

  Thereafter, the remaining macroblocks of the picture B11 are sequentially decoded by the same process. When all the macroblocks of the picture B11 are decoded, the picture B12 is decoded.

  As described above, when the motion vector decoding method of the present invention decodes the motion vector of each block, the prediction value is derived from the motion vectors of the peripheral blocks that have already been decoded, and the prediction value and the difference value are calculated. Is used to decode a motion vector. If the neighboring block is coded using the motion vector of another block, such as skip mode or direct mode, the motion vector of the other block is used for decoding the neighboring block. The predicted value is derived using the obtained motion vector as the motion vector of the surrounding block.

  As a result, the motion vector encoded by the method as in the first embodiment can be correctly decoded.

  In the present embodiment, a case has been described where the median obtained from the motion vectors of three peripheral blocks that have been decoded is used as a predicted value in motion vector decoding. Other numbers other than three may be used, and the prediction value determination method may be another method. For example, a method using a motion vector of the block on the left side as a predicted value may be used, or a method using an average value instead of a median value may be used.

  In the present embodiment, the positions of the peripheral blocks in the motion vector decoding have been described with reference to FIGS. 20 and 21. However, other positions may be used.

  In this embodiment, the skip mode, the time method, and the spatial direct mode have been described as examples of the method of coding a block using the motion vector of another block. It may be the method.

  In the present embodiment, the case where the motion vector is decoded by adding the prediction value obtained from the motion vector of the peripheral block and the difference value indicated by the code string has been described. The motion vector may be decoded by a method other than addition.

  Further, in the present embodiment, when the peripheral block is encoded in the spatial direct mode, the median of motion vectors of three decoded blocks around the peripheral block is obtained, Although the case where the median is treated as the motion vector of the peripheral block has been described, the number of blocks may be other than three, and the motion vector may be determined by another method. For example, a method using the motion vector of the block on the left side as the motion vector of the neighboring block may be used, or a method using an average value instead of the median value may be used.

  In this embodiment, when there are peripheral blocks that have been encoded in the spatial direct mode, two motion vectors in the front-rear direction are obtained for the peripheral blocks. Two motion vectors in one direction may be obtained. In this case, the B picture to be decoded refers to two pictures in one direction forward or backward with respect to the picture.

  Further, in the present embodiment, in the decoding of the P picture, one predetermined picture is referred to (for example, in the decoding of the picture P13, refer to the picture P10), and in the decoding of the B picture, In the above description, a case where decoding is performed with reference to two predetermined pictures (for example, refer to pictures P10 and P13 in decoding of picture B11) has been described. The picture to be referred to may be selected and decoded. In such a case, a motion vector prediction value may be generated as shown in FIG.

  FIG. 12 is a flowchart showing an operation in which, when a reference picture is selected for each block, the motion vector decoding unit 711 derives a prediction value of the motion vector of the decoding target block, and decodes using the prediction value. FIG.

  First, the motion vector decoding unit 711 identifies three peripheral blocks that have already been decoded around the decoding target block (step S400).

  Then, the motion vector decoding unit 711 encodes each of the identified peripheral blocks without using the peripheral block Ba encoded using the motion vector of the other block or the motion vector of the other block. It is determined whether the peripheral block Bb has been set (step S402).

  Here, for the peripheral block Ba, the motion vector decoding unit 711 acquires the motion vector used in the decoding and information indicating which reference picture the peripheral block Ba refers to, The motion vector used in the decoding is handled as the motion vector of the peripheral block Ba, and for the peripheral block Bb, the motion vector of the peripheral block Bb and which reference picture the peripheral block Bb refers to are indicated. Information is acquired (step S404).

  Next, based on the information acquired in step S404, the motion vector decoding unit 711 specifies a neighboring block that refers to the same picture as the decoding target block among the three neighboring blocks (step S406). The number of neighboring blocks is determined (step S408).

  If the number of peripheral blocks determined in step S408 is one, the motion vector decoding unit 711 determines the motion vector of the one peripheral block referring to the same picture as the motion of the decoding target block. The predicted value of the vector is set (step S410).

  On the other hand, if the number of peripheral blocks determined in step S408 is other than one, the motion vector decoding unit 711 performs motion of peripheral blocks that refer to a picture different from the decoding target block among the three peripheral blocks. The vector is set to 0 (step S412), and the median value of the motion vectors of the three neighboring blocks is set as the predicted value of the motion vector of the decoding target block (step S414).

  Thus, using the prediction value derived | led-out by step S410 or step S414, a difference value is added to the prediction value, and this is decoded into the motion vector of a decoding object block (step S416).

  Further, as in the present embodiment, when the motion vector is decoded using a motion vector of a spatially adjacent block as a predicted value, the motion vector is stored in the motion vector storage unit 706 for decoding the motion vector. When the motion vector actually used for motion compensation in the skip mode or the direct mode is held in the motion vector storage unit 706, the amount of motion vectors to be stored is one macroblock line (the height is one macroblock). It suffices to hold the motion vectors of blocks corresponding to the area whose width is equal to the width of the screen. This is a case where a motion vector actually used for motion compensation is stored in the motion vector storage unit 706 in the skip mode or the direct mode, and the peripheral as described with reference to FIGS. 20 and 21 in the present embodiment. This is because when a block is used, a block that is referred to as a peripheral block in decoding of a motion vector is the past one macroblock slice starting from the current macroblock.

(Embodiment 3)
Further, by recording a program for realizing the motion vector encoding method or motion vector decoding method shown in each of the above embodiments on a storage medium such as a flexible disk, The illustrated processing can be easily performed in an independent computer system. FIG. 13 is a program for realizing the motion vector encoding method and the motion vector decoding method executed by the moving image encoding apparatus 100 and the moving image decoding apparatus 200 according to the first and second embodiments by a computer system. It is explanatory drawing about the storage medium which stores.

  (B) in FIG. 13 shows the appearance, cross-sectional structure, and disk main body FD1 as seen from the front of the flexible disk FD, and (a) in FIG. 13 shows the physical format of the disk main body FD1, which is the main body of the recording medium. An example is shown. The disk main body FD1 is built in the case F, and a plurality of tracks Tr are formed concentrically on the surface of the disk main body FD1 from the outer periphery toward the inner periphery, and each track is divided into 16 sectors Se in the angular direction. Has been. Therefore, in the flexible disk FD storing the program, a motion vector encoding method and a motion vector decoding method as the program are recorded in an area allocated on the disk main body FD1. Further, (c) in FIG. 13 shows a configuration for recording and reproducing the program on the flexible disk FD.

  When the program is recorded on the flexible disk FD, the computer system Cs writes the motion vector encoding method or the motion vector decoding method as the program via the flexible disk drive FDD. When the motion vector encoding method or motion vector decoding method is constructed in the computer system Cs by a program in the flexible disk FD, the program is read from the flexible disk FD by the flexible disk drive FDD, and the computer system Cs. Forwarded to

  In the above description, the flexible disk FD is used as the recording medium, but the same can be done using an optical disk. Further, the recording medium is not limited to this, and any recording medium such as an IC card or a ROM cassette capable of recording a program can be similarly implemented.

(Embodiment 4)
Further, application examples of the motion vector encoding method and motion vector decoding method shown in the above embodiment and a system using the application example will be described.

  FIG. 14 is a block diagram showing an overall configuration of a content supply system ex100 that implements a content distribution service. The communication service providing area is divided into desired sizes, and base stations ex107 to ex110, which are fixed radio stations, are installed in each cell.

The content supply system ex100 includes, for example, a computer ex111, a PDA (personal) via the Internet ex101, the Internet service provider ex102, the telephone network ex104, and the base stations ex107 to ex110.
Digital assistant) ex112, camera ex113, mobile phone ex114, camera-equipped mobile phone ex115, and other devices are connected.

  However, the content supply system ex100 is not limited to the combination as shown in FIG. 14, and any of the combinations may be connected. Further, each device may be directly connected to the telephone network ex104 without going through the base stations ex107 to ex110 which are fixed wireless stations.

  The camera ex113 is a device capable of shooting a moving image such as a digital video camera. The mobile phone is a PDC (Personal Digital Communications), CDMA (Code Division Multiple Access), W-CDMA (Wideband-Code Division Multiple Access), or GSM (Global System for Mobile Communications) mobile phone, Alternatively, PHS (Personal Handyphone System) or the like may be used.

  In addition, the streaming server ex103 is connected from the camera ex113 through the base station ex109 and the telephone network ex104, and live distribution or the like based on the encoded data transmitted by the user using the camera ex113 becomes possible. The encoded processing of the captured data may be performed by the camera ex113 or may be performed by a server or the like that performs data transmission processing. Further, the moving image data shot by the camera 116 may be transmitted to the streaming server ex103 via the computer ex111. The camera ex116 is a device that can shoot still images and moving images, such as a digital camera.

  In this case, the encoding of the moving image data may be performed by the camera ex116 or the computer ex111. The encoding process is performed in the LSI ex117 included in the computer ex111 and the camera ex116. Note that image encoding / decoding software may be incorporated in some storage medium (CD-ROM, flexible disk, hard disk, etc.) that is a recording medium readable by the computer ex111 or the like. Furthermore, you may transmit moving image data with the mobile telephone ex115 with a camera. The moving image data at this time is data encoded by the LSI included in the mobile phone ex115.

  In this content supply system ex100, the content (for example, video shot of music live) captured by the user with the camera ex113, camera ex116, etc. is encoded and transmitted to the streaming server ex103 as in the above embodiment. On the other hand, the streaming server ex103 distributes the content data to the requested client. Examples of the client include a computer ex111, a PDA ex112, a camera ex113, a mobile phone ex114, and the like that can decode the encoded data. In this way, the content supply system ex100 can receive and reproduce the encoded data at the client, and also realize personal broadcasting by receiving, decoding, and reproducing in real time at the client. It is a system that becomes possible.

  For the encoding and decoding of each device constituting this system, the moving image encoding device or the moving image decoding device described in the above embodiments may be used.

  A mobile phone will be described as an example.

  FIG. 15 is a diagram illustrating the mobile phone ex115 using the motion vector encoding method and the motion vector decoding method described in the above embodiment. The cellular phone ex115 includes an antenna ex201 for transmitting and receiving radio waves to and from the base station ex110, a camera such as a CCD camera, a camera unit ex203 capable of taking a still image, a video shot by the camera unit ex203, and an antenna ex201. A display unit ex202 such as a liquid crystal display that displays data obtained by decoding received video and the like, a main body unit composed of a group of operation keys ex204, an audio output unit ex208 such as a speaker for audio output, and audio input To store encoded data or decoded data such as a voice input unit ex205 such as a microphone, captured video or still image data, received mail data, video data or still image data, etc. Recording medium ex207, and slot portion ex20 for enabling recording medium ex207 to be attached to mobile phone ex115 The has. The recording medium ex207 stores a flash memory element, which is a kind of EEPROM (Electrically Erasable and Programmable Read Only Memory), which is a nonvolatile memory that can be electrically rewritten and erased, in a plastic case such as an SD card.

  Further, the cellular phone ex115 will be described with reference to FIG. The cellular phone ex115 controls the power supply circuit ex310, the operation input control unit ex304, and the image coding for the main control unit ex311 which is configured to control the respective units of the main body unit including the display unit ex202 and the operation key ex204. Unit ex312, camera interface unit ex303, LCD (Liquid Crystal Display) control unit ex302, image decoding unit ex309, demultiplexing unit ex308, recording / reproducing unit ex307, modulation / demodulation circuit unit ex306, and audio processing unit ex305 via a synchronization bus ex313 Are connected to each other.

  When the end of call and the power key are turned on by the user's operation, the power supply circuit unit ex310 starts up the camera-equipped digital cellular phone ex115 in an operable state by supplying power from the battery pack to each unit. .

  The mobile phone ex115 converts the voice signal collected by the voice input unit ex205 in the voice call mode into digital voice data by the voice processing unit ex305 based on the control of the main control unit ex311 including a CPU, a ROM, a RAM, and the like. The modulation / demodulation circuit unit ex306 performs spread spectrum processing, the transmission / reception circuit unit ex301 performs digital analog conversion processing and frequency conversion processing, and then transmits the result via the antenna ex201. In addition, the cellular phone ex115 amplifies the received signal received by the antenna ex201 in the voice call mode, performs frequency conversion processing and analog-digital conversion processing, performs spectrum despreading processing by the modulation / demodulation circuit unit ex306, and analog audio by the voice processing unit ex305. After conversion into a signal, this is output via the audio output unit ex208.

  Further, when an e-mail is transmitted in the data communication mode, text data of the e-mail input by operating the operation key ex204 of the main body is sent to the main control unit ex311 via the operation input control unit ex304. The main control unit ex311 performs spread spectrum processing on the text data in the modulation / demodulation circuit unit ex306, performs digital analog conversion processing and frequency conversion processing in the transmission / reception circuit unit ex301, and then transmits the text data to the base station ex110 via the antenna ex201.

  When transmitting image data in the data communication mode, the image data captured by the camera unit ex203 is supplied to the image encoding unit ex312 via the camera interface unit ex303. When image data is not transmitted, the image data captured by the camera unit ex203 can be directly displayed on the display unit ex202 via the camera interface unit ex303 and the LCD control unit ex302.

  The image encoding unit ex312 has a configuration including the image encoding device described in the present invention, and an encoding method using the image data supplied from the camera unit ex203 in the image encoding device described in the above embodiment. The encoded image data is converted into encoded image data by compression encoding and is sent to the demultiplexing unit ex308. At the same time, the cellular phone ex115 sends the sound collected by the audio input unit ex205 during imaging by the camera unit ex203 to the demultiplexing unit ex308 as digital audio data via the audio processing unit ex305.

  The demultiplexing unit ex308 multiplexes the encoded image data supplied from the image encoding unit ex312 and the audio data supplied from the audio processing unit ex305 by a predetermined method, and the multiplexed data obtained as a result is a modulation / demodulation circuit unit A spectrum spread process is performed at ex306, a digital-analog conversion process and a frequency conversion process are performed at the transmission / reception circuit unit ex301, and then transmitted through the antenna ex201.

  When receiving data of a moving image file linked to a home page or the like in the data communication mode, the received signal received from the base station ex110 via the antenna ex201 is subjected to spectrum despreading processing by the modulation / demodulation circuit unit ex306, and the resulting multiplexing is obtained. Is sent to the demultiplexing unit ex308.

  In addition, in order to decode the multiplexed data received via the antenna ex201, the demultiplexing unit ex308 separates the multiplexed data to generate an encoded bit stream of image data and an encoded bit stream of audio data. The encoded image data is supplied to the image decoding unit ex309 via the synchronization bus ex313 and the audio data is supplied to the audio processing unit ex305.

  Next, the image decoding unit ex309 is configured to include the image decoding device described in the present invention, and a decoding method corresponding to the encoding method described in the above embodiment for an encoded bit stream of image data. To generate playback moving image data, which is supplied to the display unit ex202 via the LCD control unit ex302, thereby displaying, for example, moving image data included in the moving image file linked to the homepage . At the same time, the audio processing unit ex305 converts the audio data into an analog audio signal, and then supplies the analog audio signal to the audio output unit ex208. Thus, for example, the audio data included in the moving image file linked to the home page is reproduced. The

  Note that the present invention is not limited to the above-described system, and recently, digital broadcasting by satellite and terrestrial has become a hot topic, and as shown in FIG. Any of the decoding devices can be incorporated. Specifically, in the broadcasting station ex409, the encoded bit stream of the video information is transmitted to the communication or broadcasting satellite ex410 via radio waves. Receiving this, the broadcasting satellite ex410 transmits a radio wave for broadcasting, and receives the radio wave with a home antenna ex406 having a satellite broadcasting receiving facility, such as a television (receiver) ex401 or a set top box (STB) ex407. The device decodes the encoded bit stream and reproduces it.

  In addition, the image decoding apparatus described in the above embodiment can also be implemented in a playback apparatus ex403 that reads and decodes an encoded bitstream recorded on a storage medium ex402 such as a CD or DVD that is a recording medium. is there. In this case, the reproduced video signal is displayed on the monitor ex404. Further, a configuration in which an image decoding device is mounted in a set-top box ex407 connected to a cable ex405 for cable television or an antenna ex406 for satellite / terrestrial broadcasting, and this is reproduced on a monitor ex408 of the television is also conceivable. At this time, the image decoding apparatus may be incorporated in the television instead of the set top box. It is also possible to receive a signal from the satellite ex410 or the base station ex107 by the car ex412 having the antenna ex411 and reproduce a moving image on a display device such as the car navigation ex413 that the car ex412 has.

  Further, the image signal can be encoded by the image encoding device shown in the above embodiment and recorded on a recording medium. As a specific example, there is a recorder ex420 such as a DVD recorder that records an image signal on a DVD disk ex421 or a disk recorder that records on a hard disk. Further, it can be recorded on the SD card ex422. If the recorder ex420 includes the image decoding device described in the above embodiment, the image signal recorded on the DVD disc ex421 or the SD card ex422 can be reproduced and displayed on the monitor ex408.

  For example, the configuration of the car navigation ex413 may be a configuration excluding the camera unit ex203, the camera interface unit ex303, and the image encoding unit ex312 in the configuration illustrated in FIG. 16, and the same applies to the computer ex111 and the television (receiver). ) Ex401 can also be considered.

  In addition to the transmission / reception type terminal having both the encoder and the decoder, the terminal such as the mobile phone ex114 has three mounting formats: a transmitting terminal having only an encoder and a receiving terminal having only a decoder. Can be considered.

  As described above, the motion vector encoding method or the motion vector decoding method described in the above embodiment can be used in any of the above-described devices / systems, and as described in the above embodiment, An effect can be obtained.

  The motion vector encoding method and the motion vector decoding method of the present invention have the effect that the encoding efficiency can be improved by increasing the prediction capability of the prediction value of the motion vector. For example, the image encoding device and the image decoding The present invention can be applied to a conversion device.

It is a block diagram which shows the structure of the moving image encoder in the 1st Embodiment of this invention. It is a picture display figure which shows the input-output relationship of the picture in a frame memory same as the above. It is a flowchart which shows operation | movement of a motion vector encoding part same as the above. It is explanatory drawing for demonstrating a mode that the surrounding block same as the above is encoded in skip mode. It is explanatory drawing for demonstrating the inter picture prediction encoding by a bidirectional | two-way motion vector same as the above. It is explanatory drawing for demonstrating a mode that the surrounding block same as the above is encoded in temporal direct mode. It is explanatory drawing for demonstrating a mode that the surrounding block same as the above is encoded in the spatial direct mode. It is a flowchart which shows other operation | movement of a motion vector encoding part same as the above. It is a block diagram which shows the structure of the moving image decoding apparatus in the 2nd Embodiment of this invention. It is a flowchart which shows operation | movement of the motion vector decoding part same as the above. It is explanatory drawing for demonstrating the input-output relationship of a moving image decoding apparatus same as the above. It is a flowchart which shows other operation | movement of a motion vector decoding part same as the above. It is explanatory drawing about the recording medium in the 3rd Embodiment of this invention. It is a block diagram which shows the whole structure of the content supply system in the 4th Embodiment of this invention. It is a front view of a mobile phone same as the above. It is a block diagram of a mobile phone same as the above. It is a block diagram which shows the whole structure of the system for digital broadcasting same as the above. It is a relationship display figure which shows the prediction relationship of each picture in a moving image encoding system. It is explanatory drawing for demonstrating the inter-frame prediction method in direct mode. It is explanatory drawing for demonstrating the encoding method of the motion vector of the encoding object block in MPEG-4. H. It is explanatory drawing for demonstrating the encoding method of the motion vector of the encoding object block in 26L. It is a flowchart which shows an encoding procedure same as the above.

Explanation of symbols

101, 107 Frame memory 102 Difference calculation unit 103 Prediction error encoding unit 104 Code string generation unit 105 Prediction error decoding unit 106 Addition calculation unit 108 Motion vector detection unit 109 Mode selection unit 116 Motion vector storage unit 117 Motion vector encoding unit Cs Computer system FD Flexible disk FDD Flexible disk drive

Claims (4)

A motion vector decoding method for decoding an encoded motion vector of a block constituting a moving picture,
A peripheral block specifying step of specifying a peripheral block that has already been decoded and is around the block to be decoded;
A prediction motion vector deriving step for deriving a prediction motion vector of the block to be decoded using the motion vectors of the peripheral blocks;
A motion vector decoding step of decoding the motion vector of the block to be decoded using the predicted motion vector,
Here, if the neighboring block is predictive decoding using motion vectors of other blocks, a motion vector obtained using the motion vectors of the other blocks, predicting the neighboring blocks A motion vector decoding method, wherein a motion vector used for decoding is used as a motion vector of the peripheral block in the predicted motion vector derivation step. A motion vector decoding device for decoding an encoded motion vector of a block constituting a moving picture,
Peripheral block specifying means for specifying a peripheral block that has already been decoded and is around the block to be decoded;
Predicted motion vector deriving means for deriving a predicted motion vector of the block to be decoded using the motion vectors of the peripheral blocks;
Motion vector decoding means for decoding the motion vector of the block to be decoded using the predicted motion vector,
Here, if the neighboring block is predictive decoding using motion vectors of other blocks, a motion vector obtained using the motion vectors of the other blocks, predicting the neighboring blocks A motion vector decoding apparatus characterized in that a motion vector used for decoding is used as a motion vector of the peripheral block in the predicted motion vector deriving means. A motion vector decoding program for decoding an encoded motion vector of a block constituting a moving picture,
A peripheral block specifying step of specifying a peripheral block that has already been decoded and is around the block to be decoded;
A prediction motion vector deriving step for deriving a prediction motion vector of the block to be decoded using the motion vectors of the peripheral blocks;
A motion vector decoding step of decoding a motion vector of the block to be decoded using the predicted motion vector;
Here, when the peripheral block is predictively decoded using the motion vector of the other block, the motion vector obtained using the motion vector of the other block is used to predict the peripheral block. A motion vector used in decoding is used as a motion vector of the surrounding block in the prediction motion vector derivation step.
A motion vector decoding program characterized by the above . A storage medium for storing a motion vector decoding program for decoding an encoded motion vector of a block constituting a moving picture,
The motion vector decoding program includes:
A peripheral block specifying step of specifying a peripheral block that has already been decoded and is around the block to be decoded;
A prediction motion vector deriving step for deriving a prediction motion vector of the block to be decoded using the motion vectors of the peripheral blocks;
A motion vector decoding step of decoding a motion vector of the block to be decoded using the predicted motion vector;
Here, when the peripheral block is predictively decoded using the motion vector of another block, the motion vector obtained using the motion vector of the other block is used to predict the peripheral block. A motion vector used in decoding is used as a motion vector of the surrounding block in the prediction motion vector derivation step.
A storage medium characterized by that .

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