Andreas Bircher scite author profile

Within this paper a new path planning algorithm for autonomous robotic exploration and inspection is presented. The proposed method plans online in a receding horizon fashion by sampling possible future configurations in a geometric random tree. The choice of the objective function enables the planning for either the exploration of unknown volume or inspection of a given surface manifold in both known and unknown volume. Application to rotorcraft Micro Aerial Vehicles is presented, although planning for other types of robotic platforms is possible, even in the absence of a boundary value solver and subject to nonholonomic constraints. Furthermore, the method allows the integration of a wide variety of sensor models. The presented analysis of computational complexity and thorough simulations-based evaluation indicate good scaling properties with respect to the scenario complexity. Feasibility and practical applicability are demonstrated in real-life experimental test cases with full on-board computation. This is one of several papers published in Autonomous Robots comprising the Special Issue on Active Perception.

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Structural inspection path planning via iterative viewpoint resampling with application to aerial robotics

Bircher¹,

Alexis²,

Burri³

et al. 2015

199

113

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Abstract-Within this paper, a new fast algorithm that provides efficient solutions to the problem of inspection path planning for complex 3D structures is presented. The algorithm assumes a triangular mesh representation of the structure and employs an alternating two-step optimization paradigm to find good viewpoints that together provide full coverage and a connecting path that has low cost. In every iteration, the viewpoints are chosen such that the connection cost is reduced and, subsequently, the tour is optimized. Vehicle and sensor limitations are respected within both steps. Sample implementations are provided for rotorcraft and fixed-wing unmanned aerial systems. The resulting algorithm characteristics are evaluated using simulation studies as well as multiple realworld experimental test-cases with both vehicle types.

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Three-dimensional coverage path planning via viewpoint resampling and tour optimization for aerial robots

et al. 2015

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An incremental sampling-based approach to inspection planning: the rapidly exploring random tree of trees

Bircher¹,

Alexis

Schwesinger³

et al. 2016

Robotica

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SUMMARYA new algorithm, called rapidly exploring random tree of trees (RRTOT) is proposed, that aims to address the challenge of planning for autonomous structural inspection. Given a representation of a structure, a visibility model of an onboard sensor, an initial robot configuration and constraints, RRTOT computes inspection paths that provide full coverage. Sampling based techniques and a meta-tree structure consisting of multiple RRT* trees are employed to find admissible paths with decreasing cost. Using this approach, RRTOT does not suffer from the limitations of strategies that separate the inspection path planning problem into that of finding the minimum set of observation points and only afterwards compute the best possible path among them. Analysis is provided on the capability of RRTOT to find admissible solutions that, in the limit case, approach the optimal one. The algorithm is evaluated in both simulation and experimental studies. An unmanned rotorcraft equipped with a vision sensor was utilized as the experimental platform and validation of the achieved inspection properties was performed using3Dreconstruction techniques.

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Andreas Bircher

Receding Horizon "Next-Best-View" Planner for 3D Exploration

Receding horizon path planning for 3D exploration and surface inspection

Structural inspection path planning via iterative viewpoint resampling with application to aerial robotics

Three-dimensional coverage path planning via viewpoint resampling and tour optimization for aerial robots

An incremental sampling-based approach to inspection planning: the rapidly exploring random tree of trees

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