WO2004032521A1 - 画像符号化装置、画像復号化装置およびこれらの方法 - Google Patents
画像符号化装置、画像復号化装置およびこれらの方法 Download PDFInfo
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Definitions
- the present invention relates to an image encoding device, an image decoding device, and a method thereof.
- the present invention relates to a video encoding device and a video decoding device, and more particularly to a video encoding device, a video decoding device, and a method for performing motion prediction using a weighting coefficient.
- multimedia in which voices, images, and other contents are handled in a uniform manner, has entered the era of conventional information media, that is, information such as newspapers, magazines, televisions, radios, and telephones that can be obtained from a single terminal. It is becoming possible to communicate.
- multimedia refers to not only characters but also figures, sounds, and especially images, etc. associated with each other. It is essential that the information be represented in digital form.
- the amount of information per character is 1-2 bytes for characters, whereas the amount of information per character is 1-2 bytes for voice.
- Kbits (telephone quality) and video require more than 100 Mbits per second (current television reception quality)
- videophones have already been put into practical use by the Integrated Services Digital Network (ISDN), which has a transmission rate of 64 KMts / s to 1.5 Mbits / s. It is impossible to send it by ISDN as it is. Therefore, information compression technology is required.
- ISDN Integrated Services Digital Network
- H.261 and H.263 standardized internationally by ITU-T (International Telecommunication Union Telecommunication Standardization Sector). Standard video compression technology is used. Also, according to the information compression technology of the MPEG-1 standard, it is possible to put image information together with audio information on a normal music CD (Compact 'disk).
- MPEG Motion Picture Experts Group
- MPEG-1 is used to transfer video signals up to 1.5 Mbps, that is, about 100 bits of TV signal information. It is a standard that compresses to one-half.
- the transmission speed for the MP EG-1 standard is mainly limited to about 1.5 Mbps
- the MP EG-2 which has been standardized to meet the demand for even higher image quality, uses moving images.
- the signal is compressed to 2 to 15 Mbps.
- the working group (ISO / IEC JTC1 / SC29 / WG11), which has promoted the standardization of MP EG-1 and MP EG-2, has achieved compression ratios higher than MP EG-1 and MP EG_2.
- MP EG—4 which enables encoding-decoding operations on an object-by-object basis and realizes new functions required in the multimedia age, has been standardized (for example, MP EG_1, MP of ISO (International Organization for Standardization)) EG-2, MP EG-4 standard).
- MPEG-4 not only enables highly efficient coding at low bit rates, but also introduces powerful error resilience technology that can reduce image quality degradation even if a transmission line error occurs.
- ISO IEC and ITU are jointly promoting the standardization of MPEG-4 AVC / ITU II.264 as the next-generation image coding method.
- a picture is a term representing one screen, and means a frame in a progressive image and a frame or a field in an interlaced image.
- an interlaced image is an image in which one frame is composed of two fields with different times.
- FIG. 1 is a diagram illustrating an example of a picture type and a reference relationship.
- the hatched pictures represent pictures that are stored in the memory because they are referred to by other pictures.
- the arrow in FIG. 1 indicates the direction from the referenced picture to the reference picture.
- the arrangement of pictures is shown in display order.
- I 0 is an intra-picture coded picture (I picture) and is a picture that is coded independently of other pictures (that is, without referring to other pictures).
- P 4 (Picture 4) and P 7 (Picture 7) are forward predictive coded pictures (P pictures), which are predicted by referring to an I picture or another P picture located in the past in time. This is a picture to be transformed.
- B 1 to B 3 (Picture 1 to: Picture 3)
- B 5 Picture 5)
- B 6 are bidirectional predictive coded pictures (B pictures. This is a picture for which predictive coding is performed by referring to another picture located.
- FIG. 2 is a diagram illustrating another example of a picture type and a reference relationship.
- Fig. 2 differs from Fig. 1 in that the temporal position of the picture referenced by the B picture is The point is that the picture is not necessarily limited to the pictures located before and after in time. For example,
- any two pictures among I0 (Picture0), P3 (Picture3) and P6 (Picture6) can be referred to. That is, it is possible to refer to I 0 and P 3 located in the past in time.
- This type of reference has already been approved in the MPEG-4 AVC / H.264 standard draft as of September 2001. As a result, the range for selecting a more appropriate predicted image is expanded as compared with the related art, and it is possible to improve the compression ratio.
- FIG. 3 is a diagram illustrating an example of a stream structure of image data.
- the stream is composed of a common information area such as a header and a GOP (Group Of Picture) area.
- the GOP area includes a common information area such as a header and a plurality of picture areas.
- the picture area includes a common information area such as a header and a plurality of slice data areas.
- the slice data area includes a common information area such as a header and a plurality of macro block data areas.
- a weight coefficient for performing weighting prediction described later is described according to the reference picture.
- the header and the data other than the header are separated and transmitted separately. Is also good. In that case, the header part and the data part do not become one bit stream as shown in Fig. 3. However, in the case of a packet, even if the transmission order of the header part and the data part is not consecutive, only the header part corresponding to the corresponding data part is transmitted in another bucket, and one packet is transmitted. Even if it is not a stream, the concept is the same as for the bitstream described in Figure 3.
- FIG. 4 is a schematic diagram in a case where the weighting prediction process is performed on a frame basis.
- the pixel value Q of the predicted image corresponding to the current block to be encoded is the reference target in the i-th frame (Frame i) to be referenced.
- the pixel value of the block is P 0, it can be calculated by a weighted prediction formula as shown in the following formula (1).
- the pixel value Q of the predicted image is the reference target in the i-th and j-th frames (Frame i and Frame j) to be referenced.
- the pixel values of the block are PO and P1
- FIG. 5 is a schematic diagram in a case where the weighting prediction processing is performed on a field-by-field basis.
- Fig. 5 (a) when referring to one frame (that is, two fields), the pixel values Qa and Qb of the predicted image corresponding to the current block to be encoded are referred to. Assuming that the pixel values of the reference target block in each of the fields 2Xi + 1 and 2Xi constituting the i-th frame (Frame i) are POa and POb, the following equations (3) and (4) are obtained. It can be calculated by a weighted prediction formula as shown. Also, as shown in Fig. 5 (b), when referring to two frames, the pixel values Qa and Qb of the predicted image are determined by referring to the ith and jth frames (Frame i and Frame j).
- FIG. 6 is a block diagram showing a functional configuration of a conventional image encoding device 100.
- the image encoding apparatus 100 performs compression encoding (for example, variable length encoding) of an input image signal Vin, and performs image encoding signal Str which is a bit stream converted by the compression encoding.
- the image signal Vin is input to the subtraction unit Sub and the motion detection unit ME.
- the subtraction unit Sub calculates a difference value between the input image signal Vin and the predicted image and outputs the difference value to the orthogonal transform unit T.
- the orthogonal transform unit T converts the difference value into a frequency coefficient and outputs the frequency coefficient to the quantization unit Q.
- the quantization unit Q quantizes the input frequency coefficient and outputs a quantized value to the variable length coding unit VLC.
- the inverse quantization unit IQ inversely quantizes the quantized value to restore the frequency coefficient, and outputs the frequency coefficient to the inverse orthogonal transform unit IT.
- the inverse orthogonal transform unit IT performs inverse frequency transform from the frequency coefficient to the pixel difference value and outputs the result to the addition unit Add. Power.
- the addition unit Add adds the pixel difference value and the predicted image output from the motion compensation unit MC to form a decoded image.
- the switch SW is turned “ON” when the storage of the decoded image is instructed, and the decoded image is stored in the picture memory PicMeni.
- the motion detection unit ME in which the image signal Vin is input in units of macroblocks, searches for the decoded image stored in the picture memory PicMem, and detects the image area closest to the input image signal. Determines the motion vector MV indicating the position.
- the detection of a motion vector is performed in units of a project obtained by further dividing a macroblock.
- an identification number (picture number Index) for specifying the picture to be referenced is required for each block.
- the reference picture can be specified by associating the picture number Index with the picture number of each picture in the picture memory PicMem.
- the motion compensation unit MC extracts an image area necessary for generating a predicted image from the decoded image stored in the picture memory PicMem using the motion vector and the picture number Index detected by the above processing.
- the motion compensation unit MC performs a pixel value conversion process such as an interpolation process by weighted prediction using a weight coefficient associated with the picture number Index on the obtained pixel value of the image region to obtain a final predicted image.
- FIG. 7 is a block diagram schematically showing the functional configuration of the variable-length coding unit VLC in the conventional image coding apparatus 100 of FIG.
- Variable-length coding unit VLC consists of MV coding unit 101, quantization value coding unit 102, weight coefficient coding unit 103, index coding unit 104, AFF identification information coding It comprises a unit 105 and a multiplexing unit 106.
- the MV encoding unit 101 encodes the motion vector
- the quantized value encoding unit 102 encodes the quantized value Qcoef.
- the weight coefficient encoding unit 103 encodes the weight coefficient Weight
- the index encoding unit 104 encodes the picture number Index.
- the AFF identification information encoding unit 105 encodes the AFF identification signal AFF (the AFF identification signal AFF will be described later).
- the multiplexing unit 106 includes an MV encoding unit 101, a quantized value encoding unit 102, a weight coefficient encoding unit 103, an index encoding unit 104, and an AFF identification information encoding unit 1.
- the multiplexed signals output from 5 are multiplexed to output an image coded signal Str.
- FIG. 8 is a block diagram showing a functional configuration of a conventional image decoding apparatus 200.
- the image decoding device 200 is a device capable of decoding the image encoded signal Str encoded by the image encoding device 100, and includes a variable-length decoding unit VLD, a motion compensation unit MC, It has an addition unit Add, a picture memory PicMem, an inverse quantization unit IQ, and an inverse orthogonal transform unit IT.
- variable length decoding unit VLD When the coded image signal Str is input, the variable length decoding unit VLD generates a motion difference vector MV coded from the input coded image signal Str, an index indicating a picture number, and a weight coefficient Weight. Is separated and output to the motion compensation unit MC. Further, the variable decoding unit VLD decodes the coded quantization value Qcoef included in the input image coded signal Str and outputs it to the inverse quantization unit IQ.
- the motion compensation unit MC uses the motion vector output from the variable length decoding unit VLD and the picture number Index to calculate the image area necessary for generating a predicted image from the decoded image stored in the picture memory PicMem. Take out the area. Using the weighting factor Weight for the obtained image, A predicted image is generated by performing pixel value conversion processing such as interpolation processing based on weighted prediction.
- the inverse quantization unit IQ inversely quantizes the quantized value to restore the frequency coefficient, and outputs the frequency coefficient to the inverse orthogonal transform unit IT.
- the inverse orthogonal transform unit IT performs an inverse frequency transform from the frequency coefficient to the pixel difference value and outputs the result to the addition unit Add.
- the addition unit Add adds the pixel difference value and the predicted image output from the motion compensation unit MC to obtain a decoded image.
- This decoded image is stored in the picture memory PicMem when it is used for reference in subsequent inter prediction. This decoded image is output to the outside as a decoded image signal Vout.
- FIG. 9 is a block diagram schematically showing a functional configuration of a variable-length decoding unit VLD in the conventional image decoding apparatus 200 shown in FIG.
- variable-length decoding unit VLD consists of a demultiplexing unit 201, MV decoding unit 202, quantized value decoding unit 203, weight coefficient decoding unit 204, index decoding unit 205, and AF F identification.
- a signal decoding unit 206 is provided.
- the separation unit 201 separates the input coded image signal Str and converts the coded motion difference vector MV into the MV.
- the decoding unit 202 encodes the encoded quantized value Qcoef into the quantized value decoding unit 203, and encodes the encoded weight coefficient Weight into the weight coefficient decoding unit 204.
- the picture number Index is output to the index decoding unit 205, and the encoded AF F identification signal AFF (abbreviated as “AF F” in the following description) is output to the AFF identification signal decoding unit 206. I do.
- the MV decoding unit 202 decodes the encoded difference vector and outputs a motion vector MV.
- the quantization value decoding unit 203 converts the quantization value into the weight coefficient decoding unit 2 04 decodes the weight coefficient Weight
- the index decoding unit 205 decodes the picture number Index
- the AFF identification signal decoding unit 206 decodes and outputs the AFF.
- the present invention has been made in view of the above problems, and has an image encoding method and an image encoding method capable of appropriately associating weight coefficients even when switching between a field and a frame in block units. It is intended to provide a decoding method. Disclosure of the invention
- an image encoding device is an image encoding device that encodes an interlaced image in units of blocks, wherein a picture, which is a frame or a field that has been decoded after encoding, is encoded.
- a storage means for storing the reference picture as a reference picture; and a frame weighting coefficient for reading out the reference picture from the storage means and coding it for each frame or a field weighting coefficient for coding it for each field.
- a predictive picture generating means for generating a predictive picture from a pixel value of the picture; and a picture which is input in either a frame unit or a field unit.
- a signal encoding unit that encodes a difference value from a predicted picture generated by the predicted picture generation unit in units of a block, and the signal encoding unit adaptively switches between a frame unit and a field unit in a block unit.
- a weighting factor encoding unit that encodes only a frame weighting factor among the frame weighting factor and the field weighting factor, and a difference value encoded by the signal encoding unit and the weighting factor.
- a multiplexing unit that multiplexes the frame weighting factor encoded by the encoding unit and outputs the multiplexed signal as an encoded signal.
- the image coding apparatus can omit the field weighting factor and only the frame weighting factor when performing weighted prediction of a moving image, regardless of whether to switch the frame Z field in units of blocks. Is encoded and transmitted to the image decoding apparatus, so that transmission efficiency can be improved.
- an image decoding device is an image decoding device that decodes an encoded signal related to a picture that is one frame or one field in units of blocks, A signal decoding unit that decodes the encoded signal in a frame unit or a field unit when the encoded signal is encoded while being adaptively switched to one of a frame unit and a field unit; and A storage unit for storing a decoded picture; and a frame weight for decoding in a frame unit when the coded signal is encoded while being adaptively switched to a frame unit or a field unit.
- a coefficient is extracted from the coded signal, and a field weight coefficient for decoding in field units is set to the frame weight ⁇ And et generated, the extracted predictive picture generating hand to generate a predictive picture from the pixel values of the decoded picture stored in the storage means by using the frame weighting factor and the raw form said field weighting coefficients And a step of adding a picture obtained by decoding by the signal decoding means and a predicted picture generated by the predicted picture generating means, outputting the added picture as a decoded picture, and storing the decoded picture in the storage means. And addition means for performing the addition.
- the image decoding apparatus generates a field weighting factor from a frame weighting factor even when frame / field switching is performed in block units and a field weighting factor is not received. Therefore, it is possible to adaptively switch the frame / field and to improve the transmission efficiency.
- an image encoding method is an image encoding method for encoding an interlaced input image with reference to a decoded image.
- a predicted image is generated using a weighted prediction equation with a weight coefficient, and a difference image between the interlaced input image and the predicted image is adaptively encoded in a frame unit or a field unit to generate a first encoded signal.
- the encoded signal is decoded and added to the difference image to generate a decoded image, and the difference image between the interlaced input image and the prediction image is adaptively encoded in frame units or field units.
- a second encoded signal is generated by encoding the case where the predetermined weighting factor is encoded in units of fields and the case where encoding is performed in units of frames.
- the weight coefficient in the field unit may be a weight coefficient of both the first field and the second field.
- an image encoding method is an image encoding method for encoding an interlaced input image with reference to a decoded image.
- a predicted image is generated using a weighted prediction equation with a weight coefficient, and the interlaced input image and the predicted image are generated.
- Adaptively encoding the difference image on a frame or field basis to generate a first encoded signal decoding the encoded signal and adding the decoded image to the difference image to generate a decoded image;
- Ability to encode both coefficients when coding coefficients on a field basis and when coding on a frame basis Encoding the predetermined weighting coefficient either on a field basis or on a frame basis
- an image decoding method is an image decoding method for decoding an encoded signal obtained by encoding an interlaced input image with reference to a decoded image
- the encoded signal is decoded to obtain weight factors in field units and frame units, and the decoded image is referred to.
- a prediction image is generated using a prediction formula weighted by the weighting factor
- a coded signal is decoded in frame units or field units to generate a difference image
- the prediction image and the difference image are added.
- the weight coefficient in the field unit may be a weight coefficient of both the first field and the second field.
- an image decoding method is an image decoding method for decoding a coded signal obtained by coding an interlaced input image with reference to a decoded image,
- the difference image between the interlaced input image and the predicted image is adaptively encoded in frame units or field units
- Decoding is performed both when decoding, or when the weighting factor is decoded in units of fields
- Acquisition of identification information on whether to decode only one of the cases where decoding is performed in units, and decoding in both cases where the obtained information is used to decode the weighting coefficient in units of fields and when decoding in units of frames If it indicates that the weighting factor is to be obtained, both weighting factors are obtained by decoding the coded signal, and the obtained information decodes the weighting factor on a field basis or on the other hand while decoding on a frame basis.
- one of the encoded weighting factors is derived from the weighting factor obtained by decoding the other weighting factor from the encoded signal, and weighting is performed with the weighting factor with reference to the decoded image.
- a predicted image is generated using a prediction formula, a coded signal is decoded in units of frames or fields, a difference image is generated, and a decoded image is generated by adding the predicted image and the difference image. .
- an image encoding method is an image encoding device that encodes an interlaced input image with reference to a decoded image.
- an image encoding method is an image encoding device that encodes an interlaced input image with reference to a decoded image.
- an image decoding method is an image decoding device for decoding an encoded signal obtained by encoding an interlaced input image with reference to a decoded image, Means for decoding the encoded signal when the interlaced input image is adaptively encoded in frame units or field units to obtain a weight coefficient in field units or frame units; and refer to the decoded image. Means for generating a predicted image using a prediction expression weighted by the weighting coefficient, and decoding the encoded signal in frame units or field units to generate a difference image, and Means for generating a decoded image by adding the difference image.
- an image encoding method is an image decoding device for decoding an encoded signal obtained by encoding an interlaced input image with reference to a decoded image,
- the interlaced input image is adaptively coded in frame units or field units
- the coded signal is decoded and the weighting factor is decoded in field units and in both frame and frame decoding.
- the image processing apparatus includes means for decoding a field unit to generate a difference image, and means for adding the prediction image and the difference image to generate a decoded image.
- the present invention can be realized as an image encoding method or an image decoding method using the characteristic constituent means of each of the above devices as steps, or all steps of those methods can be implemented. It can also be implemented as a program that includes The program can be stored not only in a ROM or the like provided in a device capable of realizing the above method, but also distributed via a recording medium such as a CD-ROM or a transmission medium such as a communication network. .
- FIG. 1 is a diagram illustrating an example of a picture type and a reference relationship.
- FIG. 2 is a diagram illustrating another example of a picture type and a reference relationship.
- FIG. 3 is a diagram illustrating an example of a stream structure of image data.
- FIG. 4 (a) is a schematic diagram in the case of performing weighted prediction processing with reference to one frame.
- FIG. 4 (b) is a schematic diagram in the case where the weighting prediction process is performed with reference to two frames.
- FIG. 5 (a) is a schematic diagram in the case where weighting prediction processing is performed with reference to the first or second field corresponding to each.
- FIG. 5 (b) is a schematic diagram in the case where weighting prediction processing is performed by referring to two corresponding first or second fields.
- FIG. 6 is a block diagram showing a functional configuration of a conventional image encoding device.
- FIG. 7 is a block diagram schematically showing a functional configuration of a variable-length coding unit in a conventional image coding device.
- FIG. 8 is a block diagram showing a functional configuration of a conventional image decoding apparatus.
- FIG. 9 is a block diagram schematically showing a functional configuration of a variable-length decoding unit in a conventional image decoding device.
- FIG. 10 is a block diagram showing an outline of a functional configuration of the variable-length coding unit according to the first embodiment.
- FIG. 11 is a block diagram showing an outline of a functional configuration of the variable-length decoding unit according to the first embodiment.
- FIG. 12 (a) is an example of a detailed data structure of “header” in the common information area of the picture area in the first embodiment.
- FIG. 12 (b) shows an example in which there is no “AF F” and only the “field weight coefficient” is transmitted as the “picture weight coefficient”.
- Fig. 12 (c) shows an example of a case where it is not possible to switch between fields and frames in block units because the "picture frame coding information" power S "1" and the “AF F” power S "0" .
- FIG. 13 shows a flow of an encoding process related to a weight coefficient in the variable length decoding unit in Embodiment 1 where “picture frame encoding information” is “1” and a picture is encoded in frame units. It is a flowchart shown.
- FIG. 14 (a) shows a common picture area in the modification of the first embodiment. This is an example of a detailed data structure of “header” in the information area.
- FIG. 14 (c) shows an example of a case where it is not possible to switch between a finolade and a frame in units of a block because “AFF” and “0” are used in “picture frame coding information” and “1”.
- FIG. 15 is a diagram illustrating a weighting factor coding in the variable length decoding unit when a picture is coded in frame units with “picture frame coding information” power S “1” in the modification of the first embodiment. It is a flowchart which shows the flow of a process.
- FIG. 16 shows the flow of the decoding process for the weighting factor when "picture frame coding information" is "1" in the variable length decoding unit of Fig. 11 and the picture is coded in frame units. It is a flow chart.
- FIG. 17 (a) is an example of a detailed data structure of “header” in the common information area of the picture area in Embodiment 2, in which “1” is set in “AF F” and “Field coefficient” is set. This is an example in which “1” is set in “presence information”.
- FIG. 17 (b) is a diagram similar to (a), and shows an example in which “1” is set in “AFF” and “0” is set in “Field coefficient presence / absence information”.
- Fig. 17 (c) is an example in which "AFF" is set to "0", so that switching between fields and frames is not performed in units of blocks.
- FIG. 18 is a flowchart illustrating a flow of an encoding process regarding a weight coefficient in the variable-length encoding unit according to the second embodiment.
- FIG. 19 is a flowchart showing a flow of a decoding process regarding a weight coefficient in the variable-length decoding unit according to the second embodiment.
- FIG. 20 (a) shows an example of the data structure of the picture area in the third embodiment.
- FIG. 5 is an example in which “AFF” is set to “1” and “Frame coefficient presence / absence information” is set to “1”.
- FIG. 20 (b) is a diagram similar to (a), in which “AFF” is set to “1” and “Frame coefficient presence / absence information” is set to “0”.
- FIG. 20 (c) shows an example in which “0” is set in “AFF”, so that switching between the finale and the frame is not performed in block units.
- FIG. 21 is a flowchart showing a flow of an encoding process relating to a weight coefficient in the variable-length encoding unit according to the third embodiment.
- FIG. 22 is a flowchart showing a flow of a decoding process regarding a weight coefficient in the variable length decoding unit according to the third embodiment.
- FIG. 23 shows a case where the image encoding method and the image decoding method of the first, second, and third embodiments are implemented by a computer system using a program recorded on a recording medium such as a flexible disk.
- (a) is an explanatory diagram showing an example of a physical format of a flexible disk as a recording medium body.
- (b) is an explanatory diagram showing the appearance, cross-sectional structure, and flexible disk as viewed from the front of the flexible disk.
- (c) is an explanatory diagram showing a configuration for recording and reproducing the program on a flexible disk FD.
- FIG. 24 is a block diagram showing the overall configuration of a content supply system that realizes a content distribution service.
- FIG. 25 is a diagram illustrating an example of a mobile phone.
- FIG. 26 is a block diagram showing the internal configuration of the mobile phone.
- FIG. 27 is a block diagram showing the overall configuration of the digital broadcasting system. BEST MODE FOR CARRYING OUT THE INVENTION
- the functional configuration of an image encoding device that implements the image encoding method according to the present embodiment is the same as the above-described conventional image encoding device 100 except for the variable-length encoding unit VLC. Also, the functional configuration of the image decoding device that realizes the image decoding method according to the present embodiment is the same as the above-described conventional image decoding device 200 except for the variable-length decoding unit VLD. .
- variable-length coding unit VLC and the variable-length decoding unit VLD, which are different from conventional ones.
- FIG. 10 is a block diagram showing an outline of a functional configuration of variable-length coding unit VLC in the present embodiment.
- the variable-length coding unit VLC includes an MV coding unit 101, a quantized value coding unit 102, a field weight coefficient coding unit 11 and a frame weight coefficient coding unit. 12, an index encoding unit 104, a weight coefficient mode determining unit 13, an AFF identification information encoding unit 105, switches 14 and 15, and a multiplexing unit 106.
- the same reference numerals are given to the same functional components as those of the conventional variable-length coding unit VLC, and the description thereof will be omitted.
- the switches 14 and 15 determine whether the destination of the input weight coefficient Weight is the field weight coefficient coding section 11 or the frame weight coefficient code based on the determination result of the weight coefficient mode determination section 13. ON / OFF control is performed as to whether or not to use the conversion unit 12.
- the field weight coefficient coding unit 11 codes the input weight coefficient Weight as a field weight coefficient.
- the frame weight coefficient coding unit 12 codes the input weight coefficient Weight as a frame weight coefficient.
- the weight coefficient mode determination unit 13 determines the field frame based on the value of the AFF and the value of the weight coefficient Weight, and notifies the switches 14 and 15 and the multiplexing unit 106 of the determination result. I do.
- FIG. 11 is a block diagram showing an outline of a functional configuration of variable-length decoding unit VLD in the present embodiment.
- the variable-length decoding unit VLD includes a demultiplexing unit 21, an MV decoding unit 202, a quantized value decoding unit 203, a field weight coefficient decoding unit 22, It comprises a frame weighting coefficient decoding unit 23, a weighting coefficient generation unit 24, an index decoding unit 205, an AFF identification information decoding unit 206, and switches 26 to 28.
- the same reference numerals are given to the same functional components as those of the above-mentioned conventional variable-length decoding unit VLD, and description thereof will be omitted.
- the separation unit 21 separates the input image coded signal Str, converts the coded motion vector MV to the MV decoding unit 202, and converts the coded quantized value Qcoef
- the quantized value decoding unit 203 encodes the encoded weight coefficient Weight into the field weight coefficient decoding unit 22 or the frame weight coefficient decoding unit 23, and the weight coefficient generating unit 24.
- the output picture number Index is output to the index decoding unit 205, and the encoded AFF is output to the AFF identification information decoding unit 206.
- the field weight coefficient decoding unit 22 decodes the input weight coefficient Weight as a field weight coefficient.
- the frame weight coefficient decoding unit 23 decodes the input weight coefficient Weight as a frame weight coefficient.
- the weight coefficient generation unit 24 generates a field weight coefficient from the frame weight coefficient as needed. For example, there is a case where frame / field switching is performed in units of blocks, and it is necessary to generate a field weighting factor from the frame weighting factor because the field weighting factor is not encoded.
- FIG. 12 is a diagram illustrating an example of a data structure of a picture area according to the present embodiment.
- FIG. 12 (a) shows an example of the detailed data structure of rheaderj in the common information area in the picture area. In the example of FIG.
- “header” has “picture frame coding information” indicating whether a picture is a frame unit or a field unit.
- picture frame encoding information” power S “1” it further has a flag “AF F” indicating whether to switch between fields and frames in block units.
- AF F indicating whether to switch between fields and frames in block units.
- “AF F” or “1” indicates that the field and frame are switched in block units.
- Fig. 3 (a) in the case of "AFF" power S "1”, all of "field weighting factor” and “frame weighting factor” are transmitted.
- the “field weight coefficient” includes the “first field weight coefficient” and the “second field weight coefficient”.
- FIG. 12 (b) shows the case where the “picture frame coding information” power S "1" and the “AF F” power S "0”, and it is not possible to switch between fields and frames in block units. Therefore, only the “frame weighting factor” is transmitted as the “picture weighting factor”.
- FIG. 13 is a diagram illustrating an example of a coding process related to a weight coefficient in the variable-length decoding unit VLD in a case where “picture frame coding information” is “1” and pictures are coded in frame units according to the present embodiment. This is a flow chart showing the flow.
- FIG. 14 is a diagram illustrating an example of a data structure of a picture area in a modification of the present embodiment.
- Fig. 14 (a) shows an example of the detailed data structure of "header” in the common information area in the picture area.
- “header” has “picture frame coding information” indicating whether a picture is a frame unit or a field unit. For example, if “picture frame coding information” is S “1” (ie, the picture is in frame units), then “AF F” is used to determine whether to switch between fields and frames in block units. Is provided. For example, “AF F” power S “1” indicates that the field and frame are switched in block units.
- the "AF F” force S is "1"
- the "frame weighting factor” is transmitted, and the "field weighting factor” is changed to the "frame weighting factor”. It will be diverted.
- FIG. 15 shows codes related to weighting factors in variable length coding unit VLC when “picture frame coding information” is “1” and pictures are coded in frame units according to a modification of the present embodiment. This is a flowchart showing the flow of the conversion process.
- “AF” indicating “no switching in block units” Encode the value ⁇ 0 '' of ⁇ F '' (S 1 1) and match either the ⁇ field weighting factor '' or the ⁇ frame weighting factor '' with the coding unit of the block based on the picture frame coding information Is encoded as a “picture weighting factor” (S12).
- FIG. 16 shows the decoding process for the weighting factor when the "picture frame coding information" in the variable length decoding VLD in Fig. 11 is "1" and the picture is coded in frame units. This is a flowchart showing the flow of the flow.
- FIG. 16 is a flowchart of a decoding process corresponding to the encoding process of FIG. 15 described above.
- variable length decoding unit VLD decodes "AF F" (S20). As a result, if the value of “AF F” is “1”, indicating that frame / field switching is being performed in block units (S 21: Yes), the frame weighting factor is decoded (S 21 2 3) Based on the frame weighting factor (for example, by diverting the frame weighting factor), Generate (S24).
- the image encoding method and the image decoding method according to the present embodiment switching of field frames is realized in units of blocks, prediction efficiency is improved, and finally the compression ratio is improved. It is possible to make it. Furthermore, even when the “field weighting factor” is not coded, the “field weighting factor” is generated from the “frame weighting factor” in the variable-length decoding unit VLD, Field / frame switching can be performed.
- FIG. 17 is a diagram illustrating an example of a data structure of a picture area according to the present embodiment.
- FIG. 17 is a diagram showing a detailed data structure of rheaderj in the common information area in the picture area.
- the picture is coded in frame units with the “picture frame coding information” power s “1”, and “header” in the case where the field weighting coefficient can be omitted.
- An example of the structure will be described.
- “header” has “Field coefficient presence / absence information” in addition to “AFF”.
- This “: Field coefficient presence / absence information” is a flag indicating whether or not there is a field weight coefficient. For example, if there is a field weighting factor, set it to “1”; if you omit the field weighting factor, set it to “0”.
- Fig. 17 (a) is an example in which "1" is set in “AF F” and "1" is set in the "Field coefficient presence / absence information", and the field weight coefficient is also transmitted. Show the case. Note that the “field weight coefficient” includes the “first field weight coefficient” and the “second field weight coefficient” as in the first embodiment.
- FIG. 17B shows an example in which “1” is set in “AF F” and “0” is set in “Field coefficient presence / absence information”.
- Fig. 17 (c) is an example in which "0" is set in "AF F", so that switching between fields and frames is not performed in block units.
- FIG. 18 is a flowchart illustrating a flow of an encoding process regarding a weight coefficient in the variable-length encoding unit VLC according to the present embodiment.
- the field weighting factor it is determined whether or not the field weighting factor can be generated from the frame weighting factor (S32). If possible, the information indicating that the field weighting factor is generated and the frame weighting factor are encoded (S32). 6, S3 7). If the field weighting factor is not generated from the frame weighting factor, the information indicating whether there is a field weighting factor, and the frame weighting factor and the field weighting factor are encoded (S33 to S35). .
- FIG. 19 is a flowchart showing the flow of a decoding process relating to the weighting factor in the variable length decoding unit VLD of FIG. 11 described above.
- Figure 1
- FIG. 9 is a flowchart relating to a decoding process corresponding to the encoding process in FIG. It is.
- variable-length decryption unit VLD decrypts “AF F” (S 20), and when the value of “AF F” is “1”, the frame / field is switched in block units. If this is the case (S21: Yes), the information indicating the presence or absence of the field weight coefficient is decoded (S41).
- S42 it is determined whether or not there is a field weighting factor (S42). If there is no field weighting factor, the frame weighting factor is decrypted (S45), and the field weighting factor is calculated from the frame weighting factor. Generate coefficients (S46). If there is a field weighting factor, the frame weighting factor and the field weighting factor are decoded (S43, S44).
- Embodiment 1 an example in which the data structure of a picture area in Embodiment 1 is different will be described.
- FIG. 20 is a diagram illustrating an example of a data structure of a picture area according to the present embodiment.
- FIG. 20 shows the common information area in the picture area.
- FIG. 9 is a diagram illustrating a detailed data structure of “header” in a case where a picture is encoded in frame units with “picture frame encoding information” power S “1”.
- “header” has “: Frame coefficient presence / absence information” in addition to “AFF”.
- This “: Frame coefficient presence / absence information” is a flag indicating whether or not there is a frame weight coefficient. For example, it is set to “1” when there is a frame weight coefficient, and to “0” when the frame weight coefficient is omitted.
- FIG. 20 (a) shows an example in which “1” is set in “AF F” and “1” is set in the “Frame coefficient presence / absence information”, and the case where the frame weight coefficient is also transmitted is shown. Show.
- FIG. 20 (b) shows an example in which “1” is set in “AF F” and “0” is set in the above (“Frame coefficient presence / absence information”.
- FIG. 20 (c) shows an example in which “AF Since "0" is set in "F", this is an example of not switching between the finale and the frame in block units.
- FIG. 21 is a flowchart showing a flow of an encoding process regarding a weight coefficient in the variable-length encoding unit VLC according to the present embodiment.
- FIG. 22 shows the weighting factor in the variable-length decoding unit VLD in Fig. 11 above. It is a flowchart which shows the flow of the decoding process regarding a number.
- FIG. 22 is a flowchart related to a decoding process corresponding to the flow of the encoding process in FIG. 21 described above.
- variable length decoding unit VLD decodes “AFF” (S 20), and when the value of “AFF” is “1”, indicating that the frame field switching is being performed in block units. (S21: Yes), decode the information indicating the presence or absence of the frame weighting coefficient (S61).
- the switching of the field frame in units of blocks is realized. Furthermore, even when the frame weighting factor is omitted, it is possible to generate the frame weighting factor from the field weighting factor.
- FIG. 23 illustrates the image encoding method and the image decoding method of each of the above embodiments
- FIG. 11 is an explanatory diagram of a case where the present invention is implemented by a computer system using a program recorded on a recording medium such as a flexible disk.
- Fig. 23 (b) shows the appearance, cross-sectional structure, and flexible disk viewed from the front of the flexible disk
- Fig. 23 (a) shows an example of the physical format of the flexible disk that is the recording medium body.
- the flexible disk FD is built in the case F, and a plurality of tracks Tr are formed concentrically from the outer circumference toward the inner circumference on the surface of the disk, and each track has 16 sectors in the angular direction. Se has been split. Therefore, in the flexible disk storing the program, the program is recorded in an area allocated on the flexible disk FD.
- FIG. 23 (c) shows a configuration for recording and reproducing the above program on the flexible disk FD.
- the program is written from the computer system Cs via the flexible disk drive.
- the program is stored in a flexible disk drive by using a flexible disk drive. And transfer it to the computer system.
- the description has been made using a flexible disk as a recording medium.
- the same description can be made using an optical disk.
- the recording medium is not limited to this, and any other recording medium, such as an IC card, a ROM cassette, or the like, which can record a program, can be used. .
- FIG. 24 is a block diagram showing an overall configuration of a content supply system eX100 realizing a content distribution service.
- the communication service provision area is divided into desired sizes, and base stations exl07 to exl10, which are fixed radio stations, are installed in each cell.
- the content supply system eX100 is connected to the Internet eX101 via, for example, the Internet service provider eX102 and the telephone network eX104, and the base stations exl07 to exllO.
- Each device such as a combi-user exlll, a PDA (personal digital assistant) ex112, a camera exl '13, a mobile phone ex114, and a camera-equipped mobile phone ex115 is connected.
- the content supply system eX100 is not limited to the combination as shown in FIG. 24, and may be connected in any combination. Moreover, not through the base station e X 1 0 7 ⁇ exll O is a fixed radio station, each device may be connected directly to the telephone network e X 1 04.
- the camera exl l3 is a device capable of shooting moving images, such as a digital video camera.
- mobile phones are PDC (Personal Digital Communications), CDMA (Code Division Multiple Access), W-CDMA (Wideband-Code Division Multiple Access), or GSM (Global System for Mobile Communications) mobile phones. Or PHS (Personal Handyphone System), etc., and either may be used.
- the streaming server exl 03 is connected to the camera exll 3 via the base station eX109 and the telephone network eX104, and the code transmitted by the user using the camera eX113. Live distribution, etc., based on the data that has been processed can be performed. Encoding of captured data is performed by camera e X The processing may be performed in 113 or may be performed in a server or the like that performs data transmission processing. Also, moving image data captured by the camera 116 may be transmitted to the streaming server eX103 via the computer eX111.
- the camera eX116 is a device such as a digital camera that can shoot still images and moving images. In this case, the coding 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 combination exlll or the camera eX116.
- the image encoding / decoding software may be incorporated in any storage medium (CD-ROM, flexible disk, hard disk, etc.) that is a recording medium readable by a computer eX111 or the like.
- video data may be transmitted by a camera-equipped mobile phone eX115. The moving image data at this time is data that has been encoded by the LSI included in the mobile phone eX115.
- the content (for example, a video image of a music live) shot by the user with the camera eX113, camera exll6, or the like is encoded in the same manner as in the above embodiment.
- the streaming server eX103 transmits the content data to the requesting client, while transmitting the content data to the streaming server eX103.
- the client include a computer exl1, a PDAex11, a camera exl13, a mobile phone exl14, and the like, which can decode the encoded data.
- the content supply system eX1000 can receive and reproduce the encoded data at the client, and further, receive and decode the encoded data at the client in real time, and reproduce the data. This is a system that enables personal broadcasting.
- the encoding and decoding of each device that composes this system The image encoding device or the image decoding device shown in the above embodiment may be used.
- a mobile phone will be described as an example.
- FIG. 25 is a diagram illustrating the mobile phone ex 115 using the image encoding method and the image decoding method described in the above embodiment.
- the mobile phone ex 1 15 has an antenna ex 210 for transmitting and receiving radio waves to and from the base station e X 110, a camera unit e X capable of taking images and still images from a CCD camera, etc.
- the telephone ex1 15 has a slot eX206 to allow the storage media ex207 to be attached.
- the storage medium eX207 is a type of EEPROM memory (Electrically Erasable and Programmable Read Only Memory) that is electrically rewritable and erasable in a plastic case such as an SD card. It is stored.
- the mobile phone eX115 will be described with reference to FIG.
- the mobile phone eX115 is provided with a main control unit eX311, which controls the respective parts of the main unit including the display unit eX202 and the operation keys ex204 in a comprehensive manner.
- the separation unit ex308, the recording / reproducing unit eX307, the modulation / demodulation circuit unit ex306, and the audio processing unit ex305 are connected to each other via a synchronization bus ex310.
- the power supply circuit unit eX310 supplies the camera-equipped digital mobile phone eX10 by supplying power from the battery pack to each unit when the call end and the power key are turned on by a user operation. 1 Start 5 in an operable state.
- the mobile phone ex115 based on the control of the main control unit eX311, comprising a CPU, ROM, RAM, etc., transmits the audio signal collected by the audio input unit eX205 in the voice call mode.
- the voice processing unit eX305 converts the data into digital voice data, which is subjected to spread spectrum processing in the modulation / demodulation circuit unit eX306, and digital / analog conversion processing in the transmission / reception circuit unit eX301. ⁇ After performing the frequency conversion processing, transmit via the antenna eX201.
- the mobile phone e X 1 1 5 performs frequency transform and analog-to-digital conversion process to amplify the received signal received by the antenna e X 2 0 1 in voice communication mode, the modem circuit unit e X 3 0 6 After performing a spectrum despreading process in the and converting it into an analog voice signal by a voice processing unit eX305, this is output via a voice output unit eX208.
- text data of the e-mail input by operating the operation key eX204 of the main unit is mainly transmitted through the operation input control unit eX304. Transmitted to the control unit eX311.
- the main control unit eX311 performs the spread spectrum processing of the text data in the modulation / demodulation circuit unit eX306, and performs the digital analog conversion processing and the frequency conversion processing in the transmission / reception circuit unit eX301. Then, it transmits to the base station eX110 via the antenna eX201.
- the camera unit ex 20 When transmitting image data in data communication mode, the camera unit ex 20 The image data captured in 3 is supplied to the image encoding unit eX312 via the camera interface unit eX303. When the image data is not transmitted, the image data captured by the camera unit eX203 is displayed via the camera interface unit eX303 and the LCD control unit ex302. It is also possible to display directly on 202.
- the image encoding unit eX312 has a configuration including the image encoding device described in the present invention, and converts the image data supplied from the camera unit eX203 into the image code described in the above embodiment.
- the image data is converted into encoded image data by performing compression encoding by the encoding method used in the encoding device, and is transmitted to the demultiplexing unit eX308.
- the mobile phone eX115 transmits the sound collected by the audio input unit ex205 during imaging by the camera unit eX203 via the sound processing unit eX305. And sends it as digital voice data to the demultiplexing unit eX308.
- 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 in a predetermined manner.
- the resulting multiplexed data is subjected to spread spectrum processing in the modulation and demodulation circuit section eX306, and is subjected to digital analog conversion processing and frequency conversion processing in the transmission and reception circuit section eX301, followed by an antenna. Transmit via eX201.
- the received signal received from the base station eX110 via the antenna eX201 is modulated and demodulated by the modem circuit eX306. Then, the spectrum despreading process is performed, and the resulting multiplexed data is sent to the demultiplexing unit eX308.
- the demultiplexer ex308 demultiplexes the multiplexed data.
- Coded image data and audio data supplies the coded image data to the image decoding unit eX309 via the synchronization bus eX313, and also converts the audio data to the audio processing unit ex Supply 3 ⁇ 5
- the image decoding unit eX309 has a configuration provided with the image decoding device described in the present invention, and decodes encoded image data corresponding to the encoding method shown in the above embodiment.
- the playback video data is generated by decoding by the encoding method, and is supplied to the display unit ex202 via the LCD control unit eX302, whereby, for example, the video linked to the homepage is generated.
- the video data included in the file is displayed.
- 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 so that, for example, a video linked to a homepage
- the audio data included in the image file is reproduced.
- the device or the image decoding device can be incorporated.
- the coded bitstream of the video information is communicated via radio waves or transmitted to the broadcasting satellite eX410.
- the broadcasting satellite eX410 receiving this transmits a radio wave for broadcasting, and receives this radio wave with the antenna eX406 of the home having the satellite broadcasting receiving equipment, and the television (receiver) ex4
- a device such as 01 or set top pox (STB) ex 407 decodes the encoded bit stream and reproduces it.
- the image decoding device described in the above embodiment is also used as a reproducing device eX403 that reads and decodes an encoded bitstream recorded on a storage medium eX402, which is a recording medium. It is possible to implement. In this case, the reproduced video signal is displayed on the monitor ex404. Also, cable eX40 for cable TV 5 or satellite Z An image decoding device is installed in the set-top box eX407 connected to the terrestrial broadcasting antenna eX406, and this configuration can be played back on the TV monitor ex408. Conceivable. At this time, the image coding device may be incorporated in the television instead of the set-top box.
- the car ex 4 12 having the antenna e X 4 11 receives a signal from the satellite ex 4 10 force or the base station e X 10 7, etc., and the car e X 4 12 has it is also possible to play the video on a display device such as a car navigation e X 4 1 3.
- an image signal can be encoded by the image encoding device described in the above embodiment and recorded on a recording medium.
- a recorder eX420 such as a DVD recorder for recording an image signal on a DVD disk eX421 or a disk recorder for recording on a hard disk.
- it can be recorded in SD power eX422. If the recorder eX420 is equipped with the image decoding device shown in the above embodiment, the image signal recorded on the DVD disc eX421 or the SD card ex422 is reproduced, and the monitor e is used. It can be displayed as X408.
- the configuration of the car navigation eX413 may be, for example, a configuration excluding the camera unit ex203 and the camera interface unit eX303 from the configuration shown in Fig. 26. There is also considered a computer e X 1 1 1 Yate Levi (receiver) e X 4 0 1 and the like.
- the above-mentioned terminals such as the mobile phone eX114 include transmission / reception terminals having both an encoder and a decoder, as well as a transmission terminal having only an encoder and a reception terminal having only a decoder.
- transmission terminals having both an encoder and a decoder
- transmission terminal having only an encoder and a reception terminal having only a decoder.
- the image encoding method and the image decoding method described in the above embodiment can be used in any of the above-described device systems, and by doing so, the effects described in the above embodiment can be obtained. Can be obtained. Further, the present invention is not limited to the above-described embodiment, and various changes or modifications can be made without departing from the scope of the present invention. As described above, according to the image encoding method and the image decoding method according to the present invention, it is possible to realize field / frame switching in block units, improve prediction efficiency, and improve a compression ratio. Become.
- the field weighting factor is generated from the frame weighting factor, it is possible to perform transmission while omitting the field weighting factor, thereby improving transmission efficiency. Can be. Therefore, its practical value is high. Industrial applicability
- the present invention is applicable to an image encoding device, an image decoding device, and a method thereof for performing motion prediction by switching a frame Z field in units of blocks. This is useful for coding devices.
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Abstract
Description
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Priority Applications (9)
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BR0306560A BR0306560A (pt) | 2002-10-01 | 2003-09-22 | Aparelho de codificação de imagem, aparelho de decodificação de imagem e métodos |
KR1020087022232A KR100984610B1 (ko) | 2002-10-01 | 2003-09-22 | 화상 복호화 장치 및 그 방법 |
CA2468770A CA2468770C (en) | 2002-10-01 | 2003-09-22 | Picture decoding apparatus and picture decoding method |
US10/491,174 US7864838B2 (en) | 2002-10-01 | 2003-09-22 | Picture encoding device, image decoding device and their methods |
AU2003264543A AU2003264543C1 (en) | 2002-10-01 | 2003-09-22 | Image encoding device, image decoding device and their methods |
EP03799117A EP1549077A4 (en) | 2002-10-01 | 2003-09-22 | BILDCODING DEVICE, IMAGE DECODING DEVICE AND ITS METHODS |
US12/071,475 US7933330B2 (en) | 2002-10-01 | 2008-02-21 | Picture coding apparatus, picture decoding apparatus and the methods |
US13/043,715 US8194738B2 (en) | 2002-10-01 | 2011-03-09 | Picture coding apparatus, picture decoding apparatus and the methods |
US13/043,730 US8265150B2 (en) | 2002-10-01 | 2011-03-09 | Picture coding apparatus, picture decoding apparatus and the methods |
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