Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied Environments

Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied Environments

Hovering flies are able to stay still in place when hovering above flowers and burst into movement towards a new object of interest (a target). This suggests that sensorimotor control loops implemented onboard could be usefully mimicked for controlling Unmanned Aerial Vehicles (UAVs). In this study,...

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Bibliographic Details
Main Authors: Augustin Manecy, Nicolas Marchand, Stéphane Viollet
Format: Article
Language:English
Published: SAGE Publishing 2014-04-01
Series:International Journal of Advanced Robotic Systems
Online Access:https://doi.org/10.5772/58429
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spelling doaj-ab10c2efc0cf4ed4b65531a8ab73d0332020-11-25T03:20:54ZengSAGE PublishingInternational Journal of Advanced Robotic Systems1729-88142014-04-011110.5772/5842910.5772_58429Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied EnvironmentsAugustin Manecy0Nicolas Marchand1Stéphane Viollet2 CNRS, France CNRS, France CNRS, FranceHovering flies are able to stay still in place when hovering above flowers and burst into movement towards a new object of interest (a target). This suggests that sensorimotor control loops implemented onboard could be usefully mimicked for controlling Unmanned Aerial Vehicles (UAVs). In this study, the fundamental head-body movements occurring in free-flying insects was simulated in a sighted twin-engine robot with a mechanical decoupling inserted between its eye (or gaze) and its body. The robot based on this gaze control system achieved robust and accurate hovering performances, without an accelerometer, over a ground target despite a narrow eye field of view (±5°). The gaze stabilization strategy validated under Processor-In-the-Loop (PIL) and inspired by three biological Oculomotor Reflexes (ORs) enables the aerial robot to lock its gaze onto a fixed target regardless of its roll angle. In addition, the gaze control mechanism allows the robot to perform short range target to target navigation by triggering an automatic fast “target jump” behaviour based on a saccadic eye movement.https://doi.org/10.5772/58429
collection DOAJ
language English
format Article
sources DOAJ
author Augustin Manecy
Nicolas Marchand
Stéphane Viollet
spellingShingle Augustin Manecy
Nicolas Marchand
Stéphane Viollet
Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied Environments
International Journal of Advanced Robotic Systems
author_facet Augustin Manecy
Nicolas Marchand
Stéphane Viollet
author_sort Augustin Manecy
title Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied Environments
title_short Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied Environments
title_full Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied Environments
title_fullStr Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied Environments
title_full_unstemmed Hovering by Gazing: A Novel Strategy for Implementing Saccadic Flight-Based Navigation in GPS-Denied Environments
title_sort hovering by gazing: a novel strategy for implementing saccadic flight-based navigation in gps-denied environments
publisher SAGE Publishing
series International Journal of Advanced Robotic Systems
issn 1729-8814
publishDate 2014-04-01
description Hovering flies are able to stay still in place when hovering above flowers and burst into movement towards a new object of interest (a target). This suggests that sensorimotor control loops implemented onboard could be usefully mimicked for controlling Unmanned Aerial Vehicles (UAVs). In this study, the fundamental head-body movements occurring in free-flying insects was simulated in a sighted twin-engine robot with a mechanical decoupling inserted between its eye (or gaze) and its body. The robot based on this gaze control system achieved robust and accurate hovering performances, without an accelerometer, over a ground target despite a narrow eye field of view (±5°). The gaze stabilization strategy validated under Processor-In-the-Loop (PIL) and inspired by three biological Oculomotor Reflexes (ORs) enables the aerial robot to lock its gaze onto a fixed target regardless of its roll angle. In addition, the gaze control mechanism allows the robot to perform short range target to target navigation by triggering an automatic fast “target jump” behaviour based on a saccadic eye movement.
url https://doi.org/10.5772/58429
work_keys_str_mv AT augustinmanecy hoveringbygazinganovelstrategyforimplementingsaccadicflightbasednavigationingpsdeniedenvironments
AT nicolasmarchand hoveringbygazinganovelstrategyforimplementingsaccadicflightbasednavigationingpsdeniedenvironments
AT stephaneviollet hoveringbygazinganovelstrategyforimplementingsaccadicflightbasednavigationingpsdeniedenvironments
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