Title of article
DCT-based motion estimation
Author/Authors
Koc، نويسنده , , U.-V.، نويسنده , , Liu، نويسنده , , K.J.R.، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 1998
Pages
18
From page
948
To page
965
Abstract
We propose novel discrete cosine transform (DCT)
pseudophase techniques to estimate shift/delay between two onedimensional
(1-D) signals directly from their DCT coefficients by
computing the pseudophase shift hidden in DCT and then employing
the sinusoidal orthogonal principles, applicable to signal
delay estimation remote sensing. Under the two-dimensional (2-D)
translational motion model, we further extend the pseudophase
techniques to the DCT-based motion estimation (DXT-ME) algorithm
for 2-D signals/images. The DXT-ME algorithm has
certain advantages over the commonly used full search blockmatching
approach (BKM-ME) for application to video coding
despite certain limitations. In addition to its robustness in a noisy
environment and low computational complexity, O(M2) for an
M M search range in comparison to the O(N2
M2) complexity
of BKM-ME for an N N block, its ability to estimate motion
completely in DCT domain makes possible the fully DCT-based
motion-compensated video coder structure, which has only one
major component in the feedback loop instead of three as in
the conventional hybrid video coder design, and thus results
in a higher system throughput. Furthermore, combination of
the DCT and motion estimation units can provide space for
further optimization of the overall coder. In addition, the DXTME
algorithm has solely highly parallel local operations and this
property makes feasible parallel implementation suitable for very
large scale integration (VLSI) design. Simulation on a number of
video sequences is presented with comparison to BKM-ME and
other fast block search algorithms for video coding applications
even though DXT-ME is completely different from any block
search algorithms.
Keywords
video coding. , Discrete cosine transform , Motion estimation , shift measurement , time delay estimation
Journal title
IEEE TRANSACTIONS ON IMAGE PROCESSING
Serial Year
1998
Journal title
IEEE TRANSACTIONS ON IMAGE PROCESSING
Record number
396054
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