Smooth motion target displacements during eye blinks
This study investigates the relationship between the motion of a visual target and the perceived position of the target after eye blinks. Eye blinks disturb the visual feedback, and this will reduce the information received to process in the brain. This lapse of visual input is not noticed during...
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| Main Author: | |
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2019
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/77154 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This study investigates the relationship between the motion of a visual target and the perceived
position of the target after eye blinks. Eye blinks disturb the visual feedback, and this will reduce
the information received to process in the brain. This lapse of visual input is not noticed during
spontaneous blinks. However, when blinks occur during the perceiving of a motion, it is unclear
if participants would realise the errors when the continuity of the target’s motion is
compromised. This study investigates the prediction of motion during the blink by analysing the
perception of the participants when there is a target displacement in a target with a smooth
motion trajectory. It considered whether the direction across a horizontal plane and velocity
would affect the prediction of motion. Looking at the literature, it is hypothesised firstly that
there would be an undershoot of the perception of motion when blinks occur. Secondly, this
perception would be unaffected by horizontal directional difference. Lastly, there would be a
difference in the perception of motion at different velocities during the blinks. A behavioural
responses task was conducted using a smooth motion target stimulus. This study found that while
there is no significant difference in the perception of the smooth motion stimulus when it travels
in different directions, there is a significant difference in the perception of the smooth motion
stimulus at different velocities. This has implications for the perception of time during blinks and
opens up avenues to explore how the brain compensates for errors caused by blinks. |
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