Inter frame

About: Inter frame is a research topic. Over the lifetime, 4154 publications have been published within this topic receiving 63549 citations.

Object tracking using momentum and acceleration vectors in a motion estimation system

Abstract: There is provided a method and apparatus for motion estimation in a sequence of video images. The method comprises a) subdividing each field or frame of a sequence of video images into a plurality of blocks, b) assigning to each block in each video field or frame a respective set of candidate motion vectors, c) determining for each block in a current video field or frame, which of its respective candidate motion vectors produces a best match to a block in a previous video field or frame, d) forming a motion vector field for the current video field or frame using the thus determined best match vectors for each block, and e) forming a further motion vector field by storing a candidate motion vector derived from the best match vector at a block location offset by a distance derived from the candidate motion vector. Finally, steps a) to e) are repeated for a video field or frame following the current video field or frame. The set of candidate motion vectors assigned at step b) to a block in the following video field or frame includes the candidates stored at that block location at step e) during the current video field or frame The method enables a block or tile based motion estimator to improve its accuracy by introducing true motion vector candidates derived from the physical behaviour of real world objects.

3D, 3-band, 3-tap temporal lifting for scalable video coding

Abstract: Recently, a new generation of video compression techniques gained the interest of the research engineering community, by proposing state-of-the-art compression performance in addition to temporal/spatial/SNR scalability features. They exploit interframe redundancy through a temporal wavelet transform in the motion direction. While classical two-band decompositions offer dyadic factors of scalability, in this paper we present a three-band temporal lifting structure providing a factor 3 of scalability in a motion-compensated subband video coding scheme. More flexibility is thus available in order to adapt the bitstream to the bandwidth variations in heterogeneous networks. We also show improved compression performance compared with a dyadic Haar MCTF analysis.

Fast multi-frame motion estimation with adaptive search strategies

Abstract: A method includes examining a statistical distribution of motion vectors employed for motion compensation in a first frame of image data. The examining is to produce a distribution model of the motion vectors in the first frame. The method further includes selecting, based at least in part on the distribution model, a block-matching search pattern for use with respect to a second frame of image data. The second frame follows the first frame in a sequence of frames of image data.

Hierarchical motion estimation for interlaced video

Abstract: A system and method for performing motion estimation. Interlaced frames are reduced in resolution using field based scaling, and a first search is performed on the reduced resolution frames. This first search is performed by computing motion errors between the fields of a current frame and the fields of a reference frame to obtain vectors that approximately describe inter-field motion. These same motion errors are used to compute frame errors, which are used to obtain vectors that approximately describe inter-frame motion. The approximate field and frame vectors are then refined to get more precise vectors.

Video coding/decoding method and apparatus

Abstract: A video encoder/decoder and method. The video coding method includes estimating a virtual frame, electing a reference frame from candidate frames including the virtual frame to remove temporal redundancy using the elected reference frame, coding a motion vector and predetermined information obtained in removing the temporal redundancy, and obtaining transform coefficients from the frames free from the temporal redundancy and quantizing the obtained transform coefficients to generate a bit-stream. The video decoding method includes receiving a bit-stream and parsing the received bit-stream to extract information on coded frames, inversely quantizing the information on the coded frames to obtain the transform coefficients, and performing inverse spatial transform of the obtained transform coefficients and inverse temporal transform by use of a reference frame including a virtual frame in inverse order to an order in which redundancy of the coded frames is removed and restoring the coded frames. As a result, it is possible to code the video at a higher compression rate.