Title :
A VLSI architecture for variable block size video motion estimation
Author :
Yap, Swee Yeow ; McCanny, John V.
Author_Institution :
Sch. of Electr. & Electron. Eng., Queen´´s Univ. of Belfast, UK
fDate :
7/1/2004 12:00:00 AM
Abstract :
With the advent of new video standards such as MPEG-4 part-10 and H.264/H.26L, demands for advanced video coding, particularly in the area of variable block size video motion estimation (VBSME), are increasing. In this paper, we propose a new one-dimensional (1-D) very large-scale integration architecture for full-search VBSME (FSVBSME). The VBS sum of absolute differences (SAD) computation is performed by re-using the results of smaller sub-block computations. These are distributed and combined by incorporating a shuffling mechanism within each processing element. Whereas a conventional 1-D architecture can process only one motion vector (MV), this new architecture can process up to 41 MV sub-blocks (within a macroblock) in the same number of clock cycles.
Keywords :
VLSI; integrated circuit design; motion estimation; standards; video coding; VLSI architecture; advanced video coding; clock cycles; full-search VBSME; motion vector; shuffling mechanism; sub-block computations; sum of absolute differences; variable block size video motion estimation; very large-scale integration; video standards; Automatic voltage control; Clocks; Computer architecture; Hardware; Large scale integration; MPEG 4 Standard; Motion estimation; Very large scale integration; Video coding; Video compression; AVC; Advanced video coding; SAD; VBSME; VLSI; architecture; sum of absolute difference; variable block size motion estimation; very large-scale integration;
Journal_Title :
Circuits and Systems II: Express Briefs, IEEE Transactions on
DOI :
10.1109/TCSII.2004.829555
