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    • 专利摘要:
    extended motion vector predictor method and apparatus. a method and apparatus for determining a motion vector predictor (mvp) or an mvp candidate based on an mvp set are disclosed. in video encoding systems, spatial and temporal redundancy is exploited using spatial and temporal prediction to reduce the video data to be transmitted or stored. Motion vector prediction has been used to further conserve the bit rate associated with motion vector encoding. motion vector prediction technique being developed for current high efficiency video encoding (hevc) uses only a set of mvp candidates including spatial mvp candidates and a temporal candidate corresponding to the colocalized block. in the present disclosure, the set of spatial and temporal motion vector predictors is extended to include at least one neighbor block spatially associated with list 0 reference images and list 1 reference images, and colocalized block and its neighbor block associated with list 0 reference images and list 1 reference images.
    公开号:BR112013007057B1
    申请号:R112013007057-9
    申请日:2011-05-31
    公开日:2022-01-04
    发明作者:Jian-Liang Lin;Yu-Pao Tsai;Yu-Wen Huang;Shaw-Min Lei
    申请人:Hfi Innovation Inc;
    IPC主号:
    专利说明:

    TECHNICAL FIELD
    The present invention relates to video encoding. In particular, the present invention relates to coding techniques associated with motion vector prediction. BACKGROUND
    In video encoding systems, spatial and temporal redundancy is exploited using spatial and temporal prediction to reduce the information being transmitted to the underlying video data. Spatial and temporal prediction use decoded pixels of the same frame/image and reference images respectively to form prediction for actual pixels to be encoded. In order to effectively exploit temporal redundancy in video sequence, Motion Compensated Prediction (MCP) is widely used in the field. Motion Compensated Prediction can be used in a forward prediction mode, where a current image block is predicted using a decoded image or images that are before the current image in the display order. In addition to forward prediction, backward prediction can also be used to improve motion compensated prediction performance. Backward prediction uses a decoded image or images after the current image in the display order. The transmission of motion vectors can require a considerable part of the total bandwidth, particularly in low bitrate applications or in systems where motion vectors are associated with smaller blocks or higher motion accuracy. To reduce the bit rate associated with motion vector, a technique called motion vector prediction has been used in the video encoding field in recent years. When motion vector prediction is used, the difference between the current motion vector and the motion vector predictor is transmitted instead of the current motion vector. A well-designed motion vector prediction scheme can substantially improve compression efficiency by causing less motion residue, that is, smaller differences between current motion vectors and motion vector predictors.
    In the High Efficiency Video Coding (HEVC) standard being developed, a technique named Advanced Motion Vector Prediction (AMVP) is revealed. The AMVP technique uses explicit predictor signaling to indicate the selected motion vector predictor (MVP) candidate or set of MVP candidates. The MVP candidate pool includes spatial MVP candidates as well as temporal MVP candidates. Spatial MVP candidates according to AMVP are derived from motion vectors associated with neighboring blocks on the left side and top side of a current block. The temporal MVP candidate is derived based on the co-located block motion vector. It is very desirable to further improve motion vector prediction efficiency by extending the MVP set to cover more blocks. Furthermore, it is desirable to derive motion vector predictor based on information decoded on the decoder side so that additional side information does not have to be transmitted. Alternatively, side information can be transmitted explicitly in the bit stream to inform the decoder about the selected motion vector predictor. SUMMARY
    A method and apparatus for deriving motion vector predictor or motion vector predictor candidate for a current prediction unit (PU) in an image are disclosed. In an embodiment according to the present invention, the method and apparatus for deriving motion vector predictor or motion vector predictor candidate for a current PU in an image comprises steps of receiving motion vectors associated with at least one neighboring block. spatially from the current PU, at least one co-located block from the current PU, and at least one neighboring block from a co-located PU; and determining a motion vector predictor (MVP) or an MVP candidate based on an MVP set, wherein the MVP set comprises motion vector candidates derived from the motion vectors associated with the spatially neighboring block, the colocated block, and its neighboring block. Motion vectors associated with the spatially neighboring block, the colocated block and its neighboring block can be obtained from a previously encoded frame or image. Furthermore, each of the motion vectors associated with the spatially neighboring block, the colocated block and its neighboring block can be derived from one of multiple reference images and one of two lists with a scaling factor. The MVP set comprises a motion vector candidate derived as a first available motion vector or in an order from a candidate group, wherein the candidate group consists of at least two of the motion vectors associated with the blocks. spatially neighbors, the colocated blocks, or the neighboring blocks of the colocated PU. Information related to the MVP or MVP candidate may be derived from decoded video data, or alternatively incorporated into a sequence header, image header or slice header. BRIEF DESCRIPTION OF THE DRAWINGS
    Figure 1 illustrates configuration of neighboring blocks and co-located spatial and temporal motion vector prediction based on motion vectors of neighboring blocks and co-located block in the Advanced Motion Vector Prediction (AMVP) being considered for the HEVC standard.
    Figure 2 illustrates extended co-located and neighbor block configuration to derive spatial and temporal motion vector prediction based on motion vectors of neighboring blocks, co-located block, and co-located block neighbors.
    Figure 3 illustrates extending the co-located block to include neighboring blocks of the co-located block to derive motion vector prediction.
    Figure 4 illustrates an example of an extended motion vector predictor set in accordance with an embodiment of the present invention, where the extended motion vector predictor set includes Tm,n as the temporal MVP candidate.
    Figure 5 illustrates an example of an extended motion vector predictor set in accordance with an embodiment of the present invention, where the extended motion vector predictor set includes Ti,j as the temporal MVP candidate, where i^ü and j^ ü.
    Figure 6 illustrates an example of an extended motion vector predictor set according to an embodiment of the present invention, where the extended motion vector predictor set includes T' as the temporal MVP candidate, where T' is the first candidate. MVP available in group {Tü,ü, ..., Tm,n}.
    Figure 7 illustrates an example of an extended motion vector predictor set according to an embodiment of the present invention, where the extended motion vector predictor set includes the temporal MVP candidates (Tü,ü, Fü, and Gü).
    Figure 8 illustrates an example of an extended motion vector predictor set according to an embodiment of the present invention, where the extended motion vector predictor set includes the temporal MVP candidates (T', F' and G') corresponding to to the first available MVs of the groups {Tü,ü, ..., Tm,n}, {Fü, ..., Fm} and {Gü, ..., Gn} respectively.
    Figure 9 illustrates an example of an extended motion vector predictor set in accordance with an embodiment of the present invention, where the extended motion vector predictor set includes the temporal MVP candidates (T', F', G' and H). ), where (T', F and G') correspond to the first available MVs of the groups {Tü,ü, ..., Tm,n}, {Fü, ..., Fm} and {Gü, ..., Gn} respectively.
    Figure 10 illustrates an example of an extended motion vector predictor set according to an embodiment of the present invention, where the extended motion vector predictor set includes the temporal MVP candidates (T0,0, Tm,n, F0, G0 and H).
    Fig. 11 illustrates an example of an extended motion vector predictor set in accordance with an embodiment of the present invention, where the extended motion vector predictor set includes temporal MVP candidates (T0,0, F0, G0, and H).
    Fig. 12 illustrates an alternate extended motion vector predictor set in accordance with an embodiment of the present invention, wherein the extended motion vector predictor set includes the same temporal MVP candidates as those of Fig. 11 and the spatial MVP candidate c. ' is replaced by (c, d, e).
    Figure 13 illustrates an example of an extended motion vector predictor set according to an embodiment of the present invention, where the extended motion vector predictor set includes the temporal MVP candidates (Tm,n, F0, G0, and H) .
    Figure 14 illustrates an example of an extended motion vector predictor set in accordance with an embodiment of the present invention, where the extended motion vector predictor set includes the temporal MVP candidates (T0,0, T0,n, Tm, 0, Tm,n, F0, G0 and H). DETAILED DESCRIPTION
    In video encoding systems, spatial and temporal redundancy is exploited using spatial and temporal prediction to reduce the video bit stream to be transmitted or stored. Spatial prediction uses decoded pixels of the same image to form prediction for actual pixels to be encoded. Spatial prediction is often operated on a block-by-block basis, such as a 16x16 or 4x4 block for luminance signal in Intra H.264/AVC Encoding. In video sequences, neighboring images often have great similarities, and simply using image differences can effectively reduce the transmitted information associated with static background areas. Despite this, moving objects in the video sequence can result in substantial waste and will require a higher bitrate to encode the waste. Consequently, Motion Compensated Prediction (MCP) is often used to explore temporal correlation in video sequences.
    Motion compensated prediction can be used in a progressive prediction mode, where a current image block is predicted using a decoded image or images that are before the current image in the display order. In addition to forward prediction, backward prediction can also be used to improve motion compensated prediction performance. Backward prediction uses a decoded image or images after the current image in the display order. Since the first version of H.264/AVC was finalized in 2003, forward prediction and backward prediction have been extended to list 0 prediction and list 1 prediction respectively, where either list 0 or list 1 can contain multiple reference images before or after the current image in the display order. For list 0, reference images before the current image have lower reference image indices than those of reference images after the current image. For list 1, reference images after the current image have lower reference image indices than those of reference images before the current image. The first reference image having index 0 is called a colocated image. When a block in a list-0 or list-1 co-located image has the same block location as the current block in the current image, it is called a list-0 or list-1 colocated block, or called a list-0 colocated block. or List 1. The unit used for motion estimation mode in earlier video standards such as MPEG-1, MPEG-2 and MPEG-4 is primarily macroblock based. For H.264/AVC, the 16x16 macroblock can be segmented into 16x16, 16x8, 8x16 and 8x8 blocks for motion estimation. Also, the 8x8 block can be segmented into 8x8, 8x4, 4x8 and 4x4 blocks for motion estimation. For the High Efficiency Video Coding (HEVC) standard under development, the unit for the motion estimation/compensation mode is called the Prediction Unit (PU), where the PU is hierarchically partitioned by a maximum block size. The MCP type is selected for each slice in the H.264/AVC standard. A slice where motion compensated prediction is constrained to list 0 prediction is called a P slice. For a B slice, motion compensated prediction also includes list 1 prediction and bidirectional prediction in addition to list 0 prediction .
    In video encoding systems, motion vectors and encoded residues along with other related information are transmitted to a decoder to reconstruct the video on the decoder side. Furthermore, in a system with a flexible reference image structure, the information associated with the selected reference images may also have to be transmitted. The transmission of motion vectors can require a considerable part of the total bandwidth, particularly in low bitrate applications or in systems where motion vectors are associated with smaller blocks or higher motion accuracy. To further reduce the bit rate associated with motion vector, a technique called Motion Vector Prediction (MVP) has been used in the video encoding field in recent years. In this disclosure, MVP can also refer to Motion Vector Predictor and the abbreviation is used when there is no ambiguity. The MVP technique exploits the statistical redundancy between spatially and temporally neighboring motion vectors. When MVP is used, a predictor for the current motion vector is chosen and the motion vector residue, that is, the difference between the motion vector and the predictor, is transmitted. The MVP scheme can be applied in a closed loop arrangement where the predictor is derived at the decoder based on decoded information and additional side information does not have to be transmitted. Alternatively, side information can be transmitted explicitly in the bit stream to inform the decoder about the selected motion vector predictor.
    In the H.264/AVC standard, there is also a SKIP mode in addition to conventional Intra and Inter modes for macroblocks in a P-slice. SKIP is a very effective method to achieve high compression since there is no quantized error signal, neither motion vector nor reference index parameter to be passed. The only information required for the 16x16 macroblock in JUMP mode is a signal to indicate the JUMP mode being used and therefore substantial bitrate reduction is achieved. The motion vector used to reconstruct the JUMP macroblock is similar to the motion vector predictor for a macroblock. A good MVP scheme can result in more zero motion vector residuals and zero quantified prediction errors. Consequently, a good MVP scheme can increase the number of blocks encoded per JUMP and improve encoding efficiency.
    In the H.264/AVC standard, four different types of interprediction are supported for B slices including list 0, list 1, bipredictive and DIRECT prediction, where list 0 and list 1 refer to prediction using image group 0 and image group 1. reference respectively. For bipredictive mode, the prediction signal is formed by a weighted average of list 0 and list 1 prediction signals of compensated motion. The DIRECT prediction mode is inferred from previously passed syntax elements and can be list 0 or list 1 prediction or bipredictive. Therefore, there is no need to transmit information to motion vector in DIRECT mode. In the case where quantized error signal is not transmitted, the DIRECT macroblock mode is referred to as SKIP B mode and the block can be coded efficiently. Again, a good MVP scheme can result in more zero motion vector residuals and less prediction errors. Consequently, a good MVP scheme can increase the number of DIRECT coded blocks and improve coding efficiency.
    In US patent application, Serial Number 13/047,600 entitled “Method and Apparatus of Spatial Motion Vector Prediction”, filed March 14, 2011 by the same inventors, a method for deriving motion vector predictor candidate for a block current based on motion vectors of a spatially neighboring block is revealed. In US patent application, Serial Number 13/047,600, the motion vector for a current block is predicted through motion vectors of neighboring blocks spatially associated with list 0 reference images and list 1 reference images. Furthermore, the motion vectors are considered as predictor candidates for the current block and the candidates are arranged in a priority order. In US patent application, Serial Number 13/039,555 entitled “Method and Apparatus of Temporal Motion Vector Prediction”, filed March 3, 2011 by the same inventors, a system and method for deriving motion vector predictor based on motion vectors associated with a temporally colocated block are revealed. In US patent application, Serial Number 13/039,555, the motion vector for a current block is predicted by means of the motion vectors of temporal blocks in past and/or future reference images effectively. In addition, the temporal motion vectors are considered as predictor candidates for the current block and the candidates are arranged in a priority order. In the current disclosure, the set of spatial and temporal motion vector predictors is extended to include neighboring blocks spatially associated with list 0 reference images and list 1 reference images, and temporally colocated block and its neighboring blocks associated with list 1 images. list 0 reference and list 1 reference images.
    Under HEVC development, a technique named Advanced Motion Vector Prediction (AMVP) is proposed by McCann and others, in “Samsung's Response to the Call for Proposals on Video Compression Technology”, Document JCTVC-A124, Joint Collaborative Team on Video Compression Video (JCT-VC) of ITU-T SG16 WP3 and ISO/IEC JTC1/SC29/WG1, First Meeting: Dresden, Germany, April 15-23, 2010. The AMVP technique uses explicit predictor signaling to indicate the MVP candidate selected from the MVP candidate pool. The set of MVP candidates includes spatial MVP candidates as well as temporal candidates, where the spatial MVP candidates include the three candidates a', b' and c' as shown in Figure 1. Candidate a' is the first available motion vector of the group of blocks {a0, a1, ..., ana} on the top side of the current block as shown in figure 1, where na is the number of blocks in this group. Candidate b' is the first available motion vector of the group of blocks {b0, b1, ..., bnb} on the left side of the current block as shown in figure 1, where nb is the number of blocks in this group. Candidate c' is the first available motion vector of the group of blocks {c, d, e} in neighboring corners of the current PU as shown in figure 1. The set of MVP candidates proposed by McCann and others is defined as {median (a', b', c'), a', b', c', temporal MVP candidate}. The AMVP technique by McCann and others only considers the motion vector as a spatial MVP candidate available only if the motion vector is associated with the same reference list and the same reference image index as the current block. For spatial MVP candidate, if the MV with the same reference list and the same reference image index is not available from the neighboring block, the AMVP technique looks for available motion vector of the next neighboring block in the group. The candidate temporal MVP according to McCann et al is the colocalized MV T as shown in figure 1. The temporal motion predictor is given by the nearest frame of reference and can be scaled according to a temporal distance. The scaling factor is based on the ratio of the temporal distance between the current image and the given reference image for the current block to the temporal distance between the closest reference image and the reference image associated with the MV of the colocated block. The reference image associated with the co-located block's MV may not belong to the current block's reference image list. In this case, the temporal MVP candidate is not available for the current block according to McCann et al. Although the scheme disclosed in U.S. Patent Applications Serial No. 13/039,555 and Serial No. 13/047,600 provides several examples for improving the availability of the MVP candidate associated with the colocated block and neighboring block, it is very desirable to extend the MVP set to cover more temporal blocks and/or more neighboring blocks spatially associated with list 0 reference images and list 1 reference images. The scheme disclosed in US patent application, Serial Number 13/039,555 can be applied to each block of the MVP set to improve the availability of the MVP candidate associated with temporal blocks.
    In this way, an extended motion vector (MVP) predictor set is revealed where the MVP set includes both spatial MVP candidates and temporal MVP candidates as shown in Figure 2. Figure 2 illustrates an example MVP set including spatial MVP candidates and temporal MVP candidates, where the spatial MVP candidates are associated with the spatially neighboring block of Figure 1 and the temporal MVP candidates are associated with the blocks {T0,0, ..., Tm,n} of the colocated PU 210 as well as with their neighboring blocks {F0, ..., Fm}, {G0, ..., Gn), and H of the PU 210. For convenience, neither are used in figure 2 to replace na and nb respectively of figure 1. Although a column and a row of blocks extending to the right side and bottom side of the PU 210 are illustrated in Figure 2 as an example, more blocks on the right side and bottom area of the PU 210 can also be used. In a conventional approach, only the block placed in the upper left corner of the PU 210 is considered for temporal MVP candidate. In this example in Figure 2, the temporal MVP candidates are derived from at least one co-located block and neighboring blocks of the co-located blocks. The motion vectors of the co-located block and its neighboring blocks are obtained from a previously encoded frame or image. The motion vector of each spatial or temporal candidate can be derived from one of multiple reference images and one of two lists with a scaling factor. The motion vector predictor selection can be signaled explicitly to a decoder or alternatively it can be derived implicitly from the decoded image/frame. US Patent Applications 13/039,555 and 13/047,600 disclose a method of deriving the motion vector of each spatial or temporal candidate from one of multiple reference images and one of two lists with a scaling factor.
    Although Figure 2 shows that the temporal candidate is associated with blocks corresponding to a colocated PU and surrounding blocks, more blocks around the colocated PU can be included. Figure 3 illustrates an example of further extending temporal candidates to include neighboring blocks on the left and up side of the colocated PU to derive motion vector predictor, where extended temporal blocks include {T-1,-1, . .., T-1,n}, {T0,-1, ..., Tm,-1}, G-1 and F-1 on the left and top side of the PU 210. Although a column and a line of blocks extending to the left side and top side of the PU 210 are illustrated in Figure 3 as an example, more blocks on the top and/or left side of the PU 210 can be used equally. Again, the motion vector of each temporal candidate can be derived from one of multiple reference images and one of two lists with a scaling factor.
    Figure 2 and Figure 3 illustrate examples of an extended MVP set. Elements or combinations of elements from the MVP set can be selected to form the MVP candidate set. The extended MVP set covers more temporal blocks and/or spatially neighboring blocks. Therefore, the extended MVP set is able to form a better MVP candidate set resulting in less motion vector residues for more efficient compression. In the following paragraphs, various examples of MVP candidate training are illustrated in accordance with the present invention. Figure 4 illustrates an example of the set of MVP candidates {median(a', b', c'), a', b', c', temporal MVP candidate (Tm,n)}. Candidate a' is the first available motion vector from the group of blocks {a0, a1, ..., an) on the upside of the current block as shown in Figure 4, where n is the number of blocks in this group. Candidate b' is the first available motion vector of the group of blocks {b0, b1, ..., bm) on the left side of the current block as shown in figure 4, where m is the number of blocks in this group. Candidate c' is the first available motion vector of the group of blocks (c, d, e) in neighboring corners of the current PU as shown in figure 4. Only one temporal MV, Tm,n, within the PU 210 is used. as the temporal MVP candidate. As mentioned earlier, the motion vector of each spatial or temporal candidate can be derived from one of multiple reference images and one of two lists with a scaling factor. Also, the selected MV predictor can be explicitly signaled to a decoder or alternatively it can be derived implicitly from the decoded picture/frame. Although the MV Tm,n in the lower right corner of the PU 210 is used as the temporal MVP candidate in the example of Figure 4, any MV Ti,j, where i^0 and j/0, within the PU 210 can be used as the candidate Temporal MVP as shown in Figure 5. For example, the MV Ti,j, where i=(m-1)/2 and j=(n-1)/2 (that is, the temporal motion vector derived from the vector of movement associated with a colocated block corresponding to an upper left block of a midpoint of the current PU) is used as the temporal MVP candidate. In another example, the candidate temporal motion vector is derived from the motion vector associated with a colocated block corresponding to a lower right block of the current PU midpoint. Also in another example, the candidate temporal motion vector can be derived from the motion vector associated with a co-located block corresponding to an upper-left block of a lower-right neighbor block of the current PU.
    In another example, the first available MVP candidate T' in the group {T0,0, ..., Tm,n} can be used as the temporal MVP candidate as shown in Figure 6. The group {T0,0, . .., Tm,n} can be arranged in a zigzag order from T0,0 to Tm,n. Other orderings such as row by row or column by column can also be used.
    Although a single co-located block is being used as the temporal MVP candidate, multiple blocks can also be used as the MVP candidates. For example, the extended motion vector predictor set includes the temporal MVP candidates (T0,0, F0, and G0) as shown in Figure 7. In another example shown in Figure 8, the motion vector predictor set extended includes the temporal MVP candidates (T', F' and G') corresponding to the first available VMs from the groups {T0,0, ..., Tm,n}, {F0, ..., Fm} and {G0, ..., Gn) respectively. Again, the group {T0,0, ..., Tm,n} can be arranged in a zigzag order, row by row, or column by column from T0,0 to Tm,n. Also in another example shown in Figure 9, the set of extended motion vector predictors includes the temporal MVP candidates(T', F', G' and H), where (T', F' and G') correspond to the first available VMs from the groups {T0,0, ..., Tm,n}, {F0, ..., Fm) and {G0, ..., Gn} respectively.
    The temporal MVP candidates may include blocks within the PU 210 as well as blocks outside the PU 210. For example, the extended motion vector predictor set may include the temporal MVP candidates (T0,0, Tm,n, F0, G0 and H) as shown in Figure 10 or the temporal MVP candidates (T0,0, F0, G0 and H) as shown in Figure 11. All the examples illustrated above used (median(a', b', c'), a', b', c') as the spatial MVP candidates. Despite this, other neighboring blocks or combinations of neighboring blocks can be used equally. For example, the spatial MVP candidates of figure 11 can be replaced by (median(a', b', c'), a', b', c, d, e) as shown in figure 12. In another example of temporal MVP candidate formation, the extended motion vector predictor set includes the temporal MVP candidates (Tm,n, F0, G0 and H) as shown in Figure 13. When desired, more blocks can be included as candidates Temporal MVPs. For example, the extended motion vector predictor set includes the temporal MVP candidates (T0,0, T0,n, Tm,0, Tm,n, F0, G0, and H) as shown in Figure 14.
    Several examples of selecting motion vector predictor candidates to form an MVP candidate set have been illustrated earlier. These examples are used to illustrate selection of spatial/temporal MVP candidates from a set of extended motion vector predictors. Although extensive examples have been illustrated, these examples by no means represent an exhaustive illustration of possible combinations of motion vector predictor candidates. A person skilled in the field can choose different blocks for motion vector predictor candidates to practice the present invention. Furthermore, when implicit/explicit MV predictor signaling is used, the motion vector prediction order among candidates can be determined according to a predefined priority order. However, the priority order of candidates can also be performed according to an adaptive scheme. The adaptive priority ordering scheme can be based on the statistics of motion vectors reconstructed from previous blocks, current block partition type, correlation of motion vectors, motion vector directions, and distance of motion vectors. Also, the adaptive scheme can also be based on a combination of two or more of the aforementioned factors.
    It is noted that the present invention can be applied not only to INTER mode, but also to JUMP, DIRECT and JOIN modes. In INTER mode, given a current list, a motion vector predictor is used to predict the motion vector of a PU, and a motion vector residue is transmitted. The present invention can be applied to derive the motion vector predictor when the motion vector competition scheme is not used or to derive the motion vector predictor candidate when the motion vector competition scheme is used. As for the JUMP, DIRECT and UNION modes, they can be considered as special cases of the INTER mode where the motion vector residue is not transmitted and always inferred as zero. In these cases, the present invention can be applied to derive the motion vector when the motion vector competition scheme is not used or to derive the motion vector candidate when the motion vector competition scheme is used.
    Motion vector prediction embodiment according to the present invention as described above may be implemented in various hardware, software, or a combination of both. For example, an embodiment of the present invention may be an integrated circuit on a video compression chip or program codes integrated into video compression software to perform the processing described herein. An embodiment of the present invention may also be program codes to be executed in a Digital Signal Processor (DSP) to perform the processing described herein. The invention may also involve various functions to be performed by a computer processor, a digital signal processor, a microprocessor, or field programmable gate array (FPGA). These processors may be configured to perform particular tasks in accordance with the invention, by executing machine readable software code or firmware code that defines the particular methods embodied by the invention. Software code or firmware code can be developed in different programming languages and different formats or styles. Software code can also be compiled for different target platform. However, code formats, different software code styles and languages and other code configuration devices to perform the tasks in accordance with the invention will not deviate from the spirit and scope of the invention.
    The invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The examples described are to be considered in all respects only as illustrative and not restrictive. The scope of the invention, therefore, is indicated by the appended claims rather than the foregoing description. All changes that occur within the meaning and range of equivalence of the claims are intended to fall within their scope.
    权利要求:
    Claims (24)
    [0001]
    1. Method of deriving motion vector predictor or motion vector predictor candidate for encoding or decoding a motion vector of a current PU (prediction unit) in an image, the method characterized in that it comprises: receiving a current motion vector or a difference from the current motion vector of the current PU; receive motion vectors associated with at least one spatially neighboring block of the current PU and at least one neighboring block of a co-located PU of the current PU, wherein said at least one neighbor block of the colocated PU is selected from a group consisting of one or more right-neighbor blocks, {F0, ..., Fm} immediately adjacent to a right-hand side of the colocated PU, one or more neighboring blocks below, {G0, ..., Gn} immediately below the colocated PU, and a neighboring block below the right, H opposite the lower right corner of the colocated PU, mn are integers; additionally receive the motion vector associated with at least one co-located block Ti,j in the co-located PU when there is no motion vector available in said at least one neighboring block of the co-located PU, wherein the co-located block Ti,j is selected from a group of colocalized blocks consisting of {T0,0, ..., Tm,n}, mn are integers, 0<i<m, 0<j<n, Ti,j ± T0,0, and the vector of motion associated with said at least one neighbor block of the colocated PU is replaced by the motion vector associated with said at least one colocated block Ti,j in the colocated PU; determine an MVP (motion vector predictor) or an MVP candidate with based on an MVP set, wherein the MVP set comprises motion vector candidates derived from motion vectors associated with said at least one spatially neighboring block, and said at least one neighboring block of the co-located PU; and apply predictive encoding or decoding to the current PU based on the MVP or MVP candidate.
    [0002]
    2. Method according to claim 1, characterized by the fact that the motion vectors associated with the spatially neighboring block and the neighboring block of the co-located PU are obtained from a previously encoded frame or image.
    [0003]
    3. Method according to claim 1, characterized in that each of the motion vectors associated with the spatially neighboring block and the neighboring block of the colocated PU is derived from one of multiple reference images and one of two lists with a scaling factor.
    [0004]
    4. Method according to claim 1, characterized in that the MVP set additionally comprises a temporal motion vector candidate derived from the motion vector associated with a colocated block corresponding to an upper left block of a central point of the PU colocalized.
    [0005]
    5. Method according to claim 1, characterized in that the MVP set additionally comprises a temporal motion vector candidate derived from the motion vector associated with a colocated block corresponding to a lower right block of a central point of the PU colocalized.
    [0006]
    6. Method according to claim 1, characterized in that the MVP set additionally comprises a temporal motion vector candidate derived from the motion vector associated with a colocated block corresponding to a lower right block of the colocated PU.
    [0007]
    7. Method according to claim 1, characterized in that the MVP set additionally comprises a candidate temporal motion vector derived from the motion vector associated with a colocated block corresponding to an upper left block of a neighboring block below the right of the colocated PU.
    [0008]
    8. Method according to claim 1, characterized in that the candidate motion vector in the MVP set is derived as a first available motion vector from a group of candidates, wherein the candidate group consists of at least two of the motion vectors associated with at least one co-located block of the current PU and said at least one neighboring block of the co-located PU.
    [0009]
    9. Method according to claim 1, characterized in that the motion vector candidate in the MVP set is derived according to an order of a candidate group, wherein the candidate group consists of at least two of the motion vectors associated with at least one co-located block of the current PU and said at least one neighboring block of the co-located PU.
    [0010]
    10. Method according to claim 1, characterized in that the information related to the MVP or to the MVP candidate is incorporated in a sequence header, image header or slice header.
    [0011]
    11. Method according to claim 1, characterized in that information related to the MVP or the MVP candidate is derived from decoded video data.
    [0012]
    12. Apparatus for deriving motion vector predictor or motion vector predictor candidate for encoding or decoding a motion vector of a current PU (prediction unit) in an image, the apparatus characterized in that it comprises: a or more electronic circuits, wherein said one or more circuits are configured to receive a current motion vector or a current motion vector difference from the current PU; receive motion vectors associated with at least one spatially neighboring block of the current PU and at least least one neighbor block of a co-located PU of the current PU, wherein said at least one co-located PU neighbor block is selected from a group consisting of one or more right-neighbor blocks immediately adjacent to a right side of the colocated PU, one or more neighboring blocks below, immediately below the co-located PU, and one neighboring block below right, immediately opposite a lower right corner of colocalized PU; additionally receive the motion vector associated with at least one co-located block Ti,j in the co-located PU when there is no motion vector available in said at least one neighboring block of the co-located PU, wherein the co-located block Ti,j is selected from a group of colocalized blocks consisting of {T0,0, ..., Tm,n}, mn are integers, 0<i<m, 0<j<n, Ti,j ± To,o, and the vector of motion associated with said at least one neighbor block of the colocated PU is replaced by the motion vector associated with said at least one colocated block Ti,j in the colocated PU; determine an MVP (motion vector predictor) or an MVP candidate with based on an MVP set, wherein the MVP set comprises motion vector candidates derived from motion vectors associated with said at least one spatially neighboring block of the current PU, and said at least one neighboring block of the co-located PU; and apply predictive encoding or decoding to the current PU based on the MVP or MVP candidate.
    [0013]
    13. Device according to claim 12, characterized in that the motion vectors associated with the spatially neighboring block and the neighboring block of the colocalized PU are obtained from a previously encoded frame or image.
    [0014]
    14. Apparatus according to claim 12, characterized in that each of the motion vectors associated with the spatially neighboring block and the neighboring block of the colocated PU is derived from one of multiple reference images and one of two lists with a scaling factor.
    [0015]
    15. Apparatus according to claim 12, characterized in that the MVP set additionally comprises a temporal motion vector candidate derived from the motion vector associated with a colocated block corresponding to an upper left block of a central point of the PU colocalized.
    [0016]
    16. Apparatus according to claim 12, characterized in that the MVP set additionally comprises a temporal motion vector candidate derived from the motion vector associated with a co-located block corresponding to a lower right block of a central point of the PU colocalized.
    [0017]
    17. Apparatus according to claim 12, characterized in that the MVP set additionally comprises a temporal motion vector candidate derived from the motion vector associated with a colocated block corresponding to a lower right block of the colocated PU.
    [0018]
    18. Apparatus according to claim 12, characterized in that the MVP set additionally comprises a temporal motion vector candidate derived from the motion vector associated with a colocated block corresponding to an upper left block of a neighboring block below right of the colocated PU.
    [0019]
    19. Apparatus according to claim 12, characterized in that the motion vector candidate in the MVP set is derived as a first available motion vector from a candidate group, wherein the candidate group consists of at least two of the motion vectors associated with at least one co-located block of the current PU and said at least one neighboring block of the co-located PU.
    [0020]
    20. Apparatus according to claim 12, characterized in that the motion vector candidate in the MVP set is derived according to an order of a candidate group, wherein the candidate group consists of at least two of the motion vectors associated with at least one co-located block of the current PU and said at least one neighboring block of the co-located PU.
    [0021]
    21. Apparatus according to claim 12, characterized in that the information related to the MVP or to the MVP candidate is incorporated in a sequence header, image header or slice header.
    [0022]
    22. Device according to claim 12, characterized in that information related to the MVP or MVP candidate is derived from decoded video data.
    [0023]
    23. Method of deriving motion vector predictor or motion vector predictor candidate for encoding or decoding a motion vector of a current prediction unit (PU) in an image, the method characterized in that it comprises: receiving a current motion vector or an encoding motion vector of the current PU; receive motion vectors associated with at least one block spatially neighboring the current PU and at least one co-located block Ti,j in a co-located PU of the current PU, where the colocalized block Ti,j is selected from a group of colocated blocks consisting of {T0,0, ..., Tm,n}, mn are integers, 0<i<m, 0<j<n;determine a motion vector predictor (MVP) or an MVP candidate based on an MVP set, wherein the MVP set comprises motion vector candidates derived from motion vectors associated with the said at least one spatially neighboring block and the 5 referenced by the least one colocated block T i,j, wherein said at least one co-located block Ti,j excludes T0,0; and apply predictive encoding or decoding to the current PU based on the MVP or MVP candidate.
    [0024]
    24. Method according to claim 23, 10 characterized in that the MVP set comprises a temporal motion vector derived from the motion vector associated with a colocated block corresponding to a lower right block of a central point of the colocated PU.
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    同族专利:
    公开号 | 公开日
    IN2013MN00595A|2015-06-05|
    CN106131568A|2016-11-16|
    EP2599317B1|2019-03-06|
    BR112013007057A2|2016-06-14|
    EP2599317A4|2014-08-27|
    WO2012071871A1|2012-06-07|
    EP3059965B1|2019-07-10|
    CN103238319B|2016-08-17|
    US8711940B2|2014-04-29|
    CN103238319A|2013-08-07|
    EP2599317A1|2013-06-05|
    US20120134415A1|2012-05-31|
    CN106131568B|2019-07-12|
    PL2599317T3|2019-10-31|
    EP3059965A1|2016-08-24|
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    法律状态:
    2017-07-11| B25A| Requested transfer of rights approved|Owner name: HFI INNOVATION INC. (CN) |
    2018-03-27| B15K| Others concerning applications: alteration of classification|Ipc: H04N 19/52 (2014.01) |
    2018-12-26| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2020-04-07| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2021-07-13| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|
    2021-11-09| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2022-01-04| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 31/05/2011, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF, QUE DETERMINA A ALTERACAO DO PRAZO DE CONCESSAO. |
    优先权:
    申请号 | 申请日 | 专利标题
    US41779810P| true| 2010-11-29|2010-11-29|
    US61/417,798|2010-11-29|
    US201161431454P| true| 2011-01-11|2011-01-11|
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