Binocular mirror–symmetric microsaccadic sampling enables Drosophila hyperacute 3D vision

Joni  Kemppainen; Ben Scales; Keivan  Razban Haghighi; Jouni  Takalo; Neveen Mansour; James McManus; Gabor Leko; Paulus Saari; James Hurcomb; Andra Antohi

doi:10.1073/pnas.2109717119

Binocular mirror–symmetric microsaccadic sampling enables Drosophila hyperacute 3D vision

Joni Kemppainen, Ben Scales, Keivan Razban Haghighi, Jouni Takalo, Neveen Mansour, James McManus, Gabor Leko, Paulus Saari, James Hurcomb, Andra Antohi

School of Applied Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Neural mechanisms behind stereopsis, which requires simultaneous disparity inputs from two eyes, have remained mysterious. Here we show how ultrafast mirror-symmetric photomechanical contractions in the frontal forward-facing left and right eye photoreceptors give Drosophila superresolution three-dimensional (3D) vision. By interlinking multiscale in vivo assays with multiscale simulations, we reveal how these photoreceptor microsaccades—by verging, diverging, and narrowing the eyes’ overlapping receptive fields—channel depth information, as phasic binocular image motion disparity signals in time. We further show how peripherally, outside stereopsis, microsaccadic sampling tracks a flying fly’s optic flow field to better resolve the world in motion. These results change our understanding of how insect compound eyes work and suggest a general dynamic stereo-information sampling strategy for animals, robots, and sensors.

Original language	English
Journal	Proceedings of the National Academy of Sciences
Volume	119
Issue number	12
DOIs	https://doi.org/10.1073/pnas.2109717119
Publication status	Published - 17 Mar 2022

Keywords

compound eyes
stereovision
active sampling
adaptive optics

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10.1073/pnas.2109717119

kemppainen-et-al-2022-binocular-mirror-symmetric-microsaccadic-sampling-enables-drosophila-hyperacute-3d-visionFinal published version, 3.65 MBLicence: CC BY

Cite this

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title = "Binocular mirror–symmetric microsaccadic sampling enables Drosophila hyperacute 3D vision",

abstract = "Neural mechanisms behind stereopsis, which requires simultaneous disparity inputs from two eyes, have remained mysterious. Here we show how ultrafast mirror-symmetric photomechanical contractions in the frontal forward-facing left and right eye photoreceptors give Drosophila superresolution three-dimensional (3D) vision. By interlinking multiscale in vivo assays with multiscale simulations, we reveal how these photoreceptor microsaccades—by verging, diverging, and narrowing the eyes{\textquoteright} overlapping receptive fields—channel depth information, as phasic binocular image motion disparity signals in time. We further show how peripherally, outside stereopsis, microsaccadic sampling tracks a flying fly{\textquoteright}s optic flow field to better resolve the world in motion. These results change our understanding of how insect compound eyes work and suggest a general dynamic stereo-information sampling strategy for animals, robots, and sensors.",

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AU - Kemppainen, Joni

AU - Scales, Ben

AU - Razban Haghighi, Keivan

AU - Takalo, Jouni

AU - Mansour, Neveen

AU - McManus, James

AU - Leko, Gabor

AU - Saari, Paulus

AU - Hurcomb, James

AU - Antohi, Andra

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KW - active sampling

KW - adaptive optics

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Binocular mirror–symmetric microsaccadic sampling enables Drosophila hyperacute 3D vision

Abstract

Keywords

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