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Active vision shapes and coordinates flight motor responses in flies

Benjamin Cellini, Jean-Michel Mongeau

2020Proceedings of the National Academy of Sciences50 citationsDOIOpen Access PDF

Abstract

). By shaping visual inputs, head movements increased the gain of wing steering responses and coordination between stimulus and wings, pointing to a tight coupling between head and wing movements. Head movements followed the visual stimulus in as little as 10 ms-a delay similar to the human vestibulo-ocular reflex-whereas wing steering responses lagged by more than 40 ms. This timing difference suggests a temporal order in the flow of visual information such that the head filters visual information eliciting downstream wing steering responses. Head fixation significantly decreased the mechanical power generated by the flight motor by reducing wingbeat frequency and overall thrust. By simulating an elementary motion detector array, we show that head movements shift the effective visual input dynamic range onto the sensitivity optimum of the motion vision pathway. Taken together, our results reveal a transformative influence of active vision on flight motor responses in flies. Our work provides a framework for understanding how to coordinate moving sensors on a moving body.

Topics & Concepts

GazeSensory systemStimulus (psychology)WingEye movementComputer visionReflexSmooth pursuitComputer scienceCommunicationPsychologyArtificial intelligenceNeuroscienceEngineeringCognitive psychologyAerospace engineeringNeurobiology and Insect Physiology ResearchBiomimetic flight and propulsion mechanismsVisual perception and processing mechanisms
Active vision shapes and coordinates flight motor responses in flies | Litcius