Flies are capable of stabilizing their body during free flight by using visual motion information to estimate self-rotation. We have built a hardware model of this optomotor control system in a standard CMOS VLSI process. The result is a small, low-power chip that receives input directly from the real world through on-board photoreceptors and generates motor commands in real time. The chip was tested under closed-loop conditions typically used for insect studies. The silicon system exhibited stable control sufficiently analogous to the biological system to allow for quantitative comparisons

Harrison, Reid R.

Koch, Christof

English

Caltech Authors - Main

A silicon implementation of the fly's optomotor control system

Journal ArticleFlies are capable of stabilizing their body during free flight by using visual motion information to estimate self-rotation. We have built a hardware model of this optomotor control system in a standard CMOS VLSI  process. The result is a small, low-power chip that receives input directly from the real world through on-board photoreceptors and generates motor  commands in real time. The chip was tested under closed-loop conditions typically used for insect studies. The silicon system exhibited stable control sufficiently analogous to the biological system to allow for  quantitative comparisons

Koch, C.

The University of Utah: J. Willard Marriott Digital Library

Silicon implementation of the fly's optomotor control system

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A silicon implementation of the fly's optomotor control system

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The University of Utah: J. Willard Marriott Digital Library