Title :
Motion-compensating long-term memory prediction
Author :
Wiegand, Thomas ; Zhang, Xiaozheng ; Girod, Bernd
Author_Institution :
Telecommun. Inst., Erlangen-Nurnberg Univ., Germany
Abstract :
Motion-compensating long-term memory prediction extends the spatial displacement utilized in block-based hybrid video coding by a variable time delay permitting the use of more frames than the previously decoded one for motion compensation. The long-term memory covers the decoded frames of some seconds at encoder and decoder. We investigate the influence of memory size in our motion compensation scheme and analyze the trade-off between the bit-rates spent for motion compensated prediction and residual coding. Simulation results are obtained by integrating long-term memory prediction into an H.263 codec. PSNR improvements up to 2 dB for the Foreman sequence and 1.5 dB for the Mother-Daughter sequence are demonstrated in comparison to the TMN-2.0 H.263 coder
Keywords :
arithmetic codes; buffer storage; decoding; delays; image sequences; motion compensation; prediction theory; video coding; 1.5 dB; 2 dB; Foreman sequence; H.263 codec; Mother-Daughter sequence; PSNR improvements; bit-rates; block-based hybrid video coding; decoded frames; frames; memory size; motion-compensating long-term memory prediction; residual coding; spatial displacement; variable time delay; Bit rate; Codecs; Decoding; Delay effects; Image reconstruction; Image sequences; Motion analysis; Motion compensation; PSNR; Predictive models; Video codecs; Video coding;
Conference_Titel :
Image Processing, 1997. Proceedings., International Conference on
Conference_Location :
Santa Barbara, CA
Print_ISBN :
0-8186-8183-7
DOI :
10.1109/ICIP.1997.638671
