A Coarse-to-fine Disparity Energy Model with both Phase-shift and
Position-shift Receptive Field Mechanisms
Yuzhi Chen and Ning Qian, Neural Computation, 2004, 16:1545-1577.
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Abstract
Numerous studies suggest that the visual system uses both phase- and
position-shift receptive field (RF) mechanisms for the processing of
binocular disparity. Although the difference between these two
mechanisms has been analyzed before, previous work mainly focused on
disparity tuning curves instead of population responses. However,
tuning curve and population response can exhibit different
characteristics, and it is the latter that determines disparity
estimation. Here we demonstrate, in the framework of the disparity
energy model, that for relatively small disparities, the population
response generated by the phase-shift mechanism is more reliable than
that generated by the position-shift mechanism. This is true over a
wide range of parameters including the RF orientation. Since
the phase model has its own drawbacks of underestimating large
stimulus disparity and covering only a restricted range of disparity
at a given scale, we propose a coarse-to-fine algorithm for disparity
computation with a hybrid of phase-shift and position-shift
components. In this algorithm, disparity at each scale is always
estimated by the phase-shift mechanism to take advantage of its higher
reliability. Since the phase based estimation is most accurate at the
smallest scale when the disparity is correspondingly small, the
algorithm iteratively reduces the input disparity from coarse to fine
scales by introducing a {\em constant} position-shift component to all
cells for a given location in order to offset the stimulus disparity
at that location. The model also incorporates orientation pooling and
spatial pooling to further enhance reliability. We have tested the
algorithm on both synthetic and natural stereo images,
and found that it often performs better than a simple scale averaging
procedure.
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