MODELING THE APPARENT FREQUENCY-SPECIFIC SUPPRESSION IN SIMPLE CELL RESPONSES

Simple cells in cat striate cortex are selective for spatial frequency . It is widely believed that this selectivity arises simply because of the way in which the neurons sum inputs from the lateral geniculate n ucleus, Alternate models, however, advocate the need for frequency-spe cific inhibitory mechanisms to refine the spatial frequency selectivit y. Indeed, simple cell responses are often suppressed by superimposing stimuli with spatial frequencies that flank the neuron's preferred sp atial frequency, In this article, we compare two models of simple cell responses head-to-head. One of these models, the flanking-suppression model, includes an inhibitory mechanism that is specific to frequenci es that flank the neuron's preferred spatial frequency. The other mode l, the nonspecific-suppression model, includes a suppressive mechanism that is very broadly tuned for spatial frequency. Both models also in clude a rectification nonlinearity and both may include an additional accelerating (e.g., squaring) output nonlinearity. We demonstrate that both models can be consistent with the apparent flanking suppression. However, based on other experimental results, we argue that the nonsp ecific-suppression model is more plausible. We conclude that the suppr ession is probably broadly tuned for spatial frequency and that the ap parent flanking suppression is actually due to distortions introduced by an accelerating output nonlinearity. (C) 1997 Elsevier Science Ltd.