Abstract
As the neural representation of visual information is initially coded in retinotopic coordinates, eye movements (saccades) pose a major problem for visual stability. If no visual information were maintained across saccades, retinotopic representations would have to be rebuilt after each saccade. It is currently strongly debated what kind of information (if any at all) is accumulated across saccades, and when this information becomes available after a saccade. Here, we use a motion illusion to examine the accumulation of visual information across saccades. In this illusion, an annulus with a random texture slowly rotates, and is then replaced with a second texture (motion transient). With increasing rotation durations, observers consistently perceive the transient as large rotational jumps in the direction opposite to rotation direction (backward jumps). We first show that accumulated motion information is updated spatiotopically across saccades. Then, we show that this accumulated information is readily available after a saccade, immediately biasing postsaccadic perception. The current findings suggest that presaccadic information is used to facilitate postsaccadic perception and are in support of a forward model of transsaccadic perception, aiming at anticipating the consequences of eye movements and operating within the narrow perisaccadic time window.
Highlights
When inspecting the world, visual information travels from the retina to the visual cortex in a retinotopic reference frame
High Phi illusion make it an ideal tool to investigate the rapid building of a perceptual representation
We investigated whether and when presaccadic visual information is integrated with postsaccadic information
Summary
Visual information travels from the retina to the visual cortex in a retinotopic reference frame. We address the issue of spatiotopic visual stability by taking advantage of a recently described motion illusion – High Phi27 – to measure the rapid induction of a motion percept Using this illusion, the current experiments address whether and when presaccadic visual features influences postsaccadic perception. The data of two experiments are compellingly in favour of rapid spatiotopic interpretations of visual information after eye movement offset This supports the hypothesis of a perceptual system where object representations can be updated spatiotopically across saccades, taking into account both object features and position. Thereby, this system enables fast spatiotopic interpretations of visual information immediately after saccade offset
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