Abstract
As of yet, it is unclear how we determine relative perceived timing. One controversial suggestion is that timing perception might be related to when analyses are completed in the cortex of the brain. An alternate proposal suggests that perceived timing is instead related to the point in time at which cortical analyses commence. Accordingly, timing illusions should not occur owing to cortical analyses, but they could occur if there were differential delays between signals reaching cortex. Resolution of this controversy therefore requires that the contributions of cortical processing be isolated from the influence of subcortical activity. Here, we have done this by using binocular disparity changes, which are known to be detected via analyses that originate in cortex. We find that observers require longer stimulus exposures to detect small, relative to larger, disparity changes; observers are slower to react to smaller disparity changes and observers misperceive smaller disparity changes as being perceptually delayed. Interestingly, disparity magnitude influenced perceived timing more dramatically than it did stimulus change detection. Our data therefore suggest that perceived timing is both influenced by cortical processing and is shaped by sensory analyses subsequent to those that are minimally necessary for stimulus change perception.
Highlights
A single physical event can induce activity that is widely distributed both in time and across different, specialized, sensory regions of cortex (Zeki 1978; Bullier 2001)
We have done this by using binocular disparity changes, which are known to be detected via analyses that originate in cortex
We have shown that large binocular disparity signals can be detected more rapidly, be responded to sooner and can seem to occur at earlier epochs relative to smaller disparity signals
Summary
One controversial suggestion is that timing perception might be related to when analyses are completed in the cortex of the brain. Timing illusions should not occur owing to cortical analyses, but they could occur if there were differential delays between signals reaching cortex. Resolution of this controversy requires that the contributions of cortical processing be isolated from the influence of subcortical activity. Disparity magnitude influenced perceived timing more dramatically than it did stimulus change detection. Our data suggest that perceived timing is both influenced by cortical processing and is shaped by sensory analyses subsequent to those that are minimally necessary for stimulus change perception
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