Abstract
How are the image statistics of global image contrast computed? We answered this by using a
contrast-matching task for checkerboard configurations of ‘battenberg’ micro-patterns where the
contrasts and spatial spreads of interdigitated pairs of micro-patterns were adjusted independently.
Test stimuli were 20 × 20 arrays with various sized cluster widths, matched to standard patterns of
uniform contrast. When one of the test patterns contained a pattern with much higher contrast than
the other, that determined global pattern contrast, as in a max() operation. Crucially, however, the
full matching functions had a curious intermediate region where low contrast additions for one
pattern to intermediate contrasts of the other caused a paradoxical reduction in perceived global
contrast. None of the following models predicted this: RMS, energy, linear sum, max, Legge
and Foley. However, a gain control model incorporating wide-field integration and suppression
of nonlinear contrast responses predicted the results with no free parameters. This model was
derived from experiments on summation of contrast at threshold, and masking and summation
effects in dipper functions. Those experiments were also inconsistent with the failed models above.
Thus, we conclude that our contrast gain control model (Meese & Summers, 2007) describes a
fundamental operation in human contrast vision.
Original language | English |
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Article number | O3A-7 |
Pages (from-to) | 245 |
Number of pages | 1 |
Journal | i-Perception |
Volume | 5 |
Issue number | 4 |
DOIs | |
Publication status | Published - 1 Jun 2014 |
Event | 10th Asia-Pacific Conference on Vision - Takamatsu, Japan Duration: 19 Jul 2014 → 22 Jul 2014 |