Abstract
The power law provides an efficient description of amplitude spectra of natural scenes. Psychophysical studies have shown that the forms of the amplitude spectra are clearly related to human visual performance, indicating that the statistical parameters in natural scenes are represented in the nervous system. However, the underlying neuronal computation that accounts for the perception of the natural image statistics has not been thoroughly studied. We propose a theoretical framework for neuronal encoding and decoding of the image statistics, hypothesizing the elicited population activities of spatial-frequency selective neurons observed in the early visual cortex. The model predicts that frequency-tuned neurons have asymmetric tuning curves as functions of the amplitude spectra falloffs. To investigate the ability of this neural population to encode the statistical parameters of the input images, we analyze the Fisher information of the stochastic population code, relating it to the psychophysically measured human ability to discriminate natural image statistics. The nature of discrimination thresholds suggested by the computational model is consistent with experimental data from previous studies. Of particular interest, a reported qualitative disparity between performance in fovea and parafovea can be explained based on the distributional difference over preferred frequencies of neurons in the current model. The threshold shows a peak at a small falloff parameter when the neuronal preferred spatial frequencies are narrowly distributed, whereas the threshold peak vanishes for a neural population with a more broadly distributed frequency preference. These results demonstrate that the distributional property of neuronal stimulus preference can play a crucial role in linking microscopic neurophysiological phenomena and macroscopic human behaviors.
Highlights
Understanding how the human visual system recognizes complex natural images is a most important but challenging problem in vision science
We presume that the spatial-frequency selective neurons, which are observed in the early visual cortex, are the main neural substrate for representing the image statistics
Human performance at discriminating the amplitude spectrum falloff parameter a has been a topic of debate in visual psychophysics [8,10,11,12] since the first investigation conducted by Knill et al [10]
Summary
Understanding how the human visual system recognizes complex natural images is a most important but challenging problem in vision science. Recent studies suggest that the shape of the amplitude spectra falloff can characterize a whole class of natural image and its subclasses, which can be determined by image properties such as texture [8] or blurriness [9]. Those careful observations with the modeling and the analysis of natural images suggest that determining the exact a values is not a trivial issue; we can find functional meanings in the values of a in natural image recognition. This study is motivated by the desire to fill this gap between the stimulus features and resulting human performance
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