A contribution to vision-based autonomous helicopter flight in urban environments

Muratet, Laurent; Doncieux, Stéphane; Brière, Yves; Meyer, Jean-Arcady

doi:10.1016/j.robot.2004.09.017

Cited by 100 publications

(68 citation statements)

References 26 publications

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“…They are exceptionally critical when operating in urban environment and during inspection tasks. In such applications robot is required not only to avoid obstacles (even when flying on high altitude) but also to position itself precisely to execute given tasks [10], [19], [20] The scenario presented in section V require utilization of precise navigation as well. To support UAV with necessary capabilities the following methods were provided: 1) Calculating position of Points Of Interest (later referred to as POI) in the area photographed from high altitude.…”

Section: Navigation Methodsmentioning

confidence: 99%

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Visual simulator for MavLink-protocol-based UAV, applied for search and analyze task

Śmigielski

Raczynski

Gosek

2017

Proceedings of the 2017 Federated Conference on Computer Science and Information Systems

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Abstract-In this paper the authors present the results of research to develop the visual system for autonomous flying agent. The core elements of the vision system which were designed and implemented in the earlier stage of the project are brought together. The second aim is to show capabilities of a simulation environment designed and developed by the authors in order to enable testing of the vision systems (dedicated for Unmanned Aerial Vehicles) in the artificial environment. The first section of the paper introduces the testing (simulation) environment for MavLink-protocol-based autonomous flying robots. Next, the core elements of a vision system, designed for Unmanned Aerial Vehicle (UAV), are discussed. This includes pre-processing and vectorization algorithms, object recognition methods and fast three-dimensional model construction. The third part introduces a set of algorithms for robot navigation, solely based on vision and altitude sensor and compass. The paper concludes with the description of the tests and presentation of results where designed simulator was applied to show mentioned vision system elements operating together to execute complex task.

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Section: Navigation Methodsmentioning

confidence: 99%

“…1177-1185 DOI: 10.15439/2017F184 ISSN 2300-5963 ACSIS, Vol. 11 IEEE Catalog Number: CFP1785N-ART c 2017, PTIrobotics and can contribute to the solution of more complex tasks, such as scene understanding and robot localization [9], [10].…”

Section: Introductionmentioning

confidence: 99%

Visual simulator for MavLink-protocol-based UAV, applied for search and analyze task

Śmigielski

Raczynski

Gosek

2017

Proceedings of the 2017 Federated Conference on Computer Science and Information Systems

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“…These behaviors originated in research on insect flight are appropriate for implementation in a biomimetic autopilot for small UAVs and robotics in general [17,18,19]. Potential applications of optical flow for small aerial vehicles include altitude control and terrain following [20,21], autonomous landing [20,22,23] and obstacles avoidance [24,25,26].…”

Section: Bio-inspired Vision-based Aerial Navigationmentioning

confidence: 99%

Optic Flow‐Based Vision System for Autonomous 3D Localization and Control of Small Aerial Vehicles

Kendoul

Fantoni²,

Nonami

2013

Unmanned Aerial Vehicles

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“…This technique is inspired by the strategy of flying insects, which use it to center themselves when flying in a narrow environment. The insects naturally take advantage of their pair of lateral sensors, however, the technique has been used with success on an autonomous helicopter using a wide field single camera [23].…”

Section: Visual Obstacle Avoidance Algorithmsmentioning

confidence: 99%

Evolution of visual controllers for obstacle avoidance in mobile robotics

Barate

Manzanera

2009

Evol. Intel.

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The purpose of this work is to automatically design vision algorithms for a mobile robot, adapted to its current visual context. In this paper we address the particular task of obstacle avoidance using monocular vision. Starting from a set of primitives composed of the different techniques found in the literature, we propose a generic structure to represent the algorithms, using standard resolution video sequences as an input, and velocity commands to control a wheel robot as an output. Grammar rules are then used to construct correct instances of algorithms, that are then evaluated using different protocols: evaluation of trajectories performed in a goal reaching task, or imitation of a hand-guided trajectory. A genetic program is applied to evolve populations of algorithms in order to optimize the performances of the controllers. The first results obtained in a simulated environment show that the evolution produces algorithms that can be easily interpreted and which are clearly adapted to the visual context. However, the resulting trajectories are often erratic, and the generalization capacities are poor. To improve the results, we propose to use a two-phase evolution combining imitation and goal reaching evaluations, and to add some constraints in the grammar rules to enforce a more generic behavior. The results obtained in simulation show that the evolved algorithms are more efficient and more generic. Finally, we apply the imitation based evolution on real sequences and test the evolved algorithms on a real robot. Though simplified by dropping the goal reaching constraint, the resulting algorithms behave well in a corridor centering task, and show certain generalization capacities.

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A contribution to vision-based autonomous helicopter flight in urban environments

Cited by 100 publications

References 26 publications

Visual simulator for MavLink-protocol-based UAV, applied for search and analyze task

Visual simulator for MavLink-protocol-based UAV, applied for search and analyze task

Optic Flow‐Based Vision System for Autonomous 3D Localization and Control of Small Aerial Vehicles

Evolution of visual controllers for obstacle avoidance in mobile robotics

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