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Intelligent Service Robotics
Erschienen in: Intelligent Service Robotics 1/2018

03.08.2017 | Original Research Paper

Optimal path planning in cluttered environment using RRT*-AB

verfasst von: Iram Noreen, Amna Khan, Hyejeong Ryu, Nakju Lett Doh, Zulfiqar Habib

Erschienen in: Intelligent Service Robotics | Ausgabe 1/2018

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Abstract

Rapidly exploring Random Tree Star (RRT*) has gained popularity due to its support for complex and high-dimensional problems. Its numerous applications in path planning have made it an active area of research. Although it ensures probabilistic completeness and asymptotic optimality, its slow convergence rate and large dense sampling space are proven problems. In this paper, an off-line planning algorithm based on RRT* named RRT*-adjustable bounds (RRT*-AB) is proposed to resolve these issues. The proposed approach rapidly targets the goal region with improved computational efficiency. Desired objectives are achieved through three novel strategies, i.e., connectivity region, goal-biased bounded sampling, and path optimization. Goal-biased bounded sampling is performed within boundary of connectivity region to find the initial path. Connectivity region is flexible enough to grow for complex environment. Once path is found, it is optimized gradually using node rejection and concentrated bounded sampling. Final path is further improved using global pruning to erode extra nodes. Robustness and efficiency of proposed algorithm is tested through experiments in different structured and unstructured environments cluttered with obstacles including narrow and complex maze cases. The proposed approach converges to shorter path with reduced time and memory requirements than conventional RRT* methods.
Vorheriger Artikel Routing-based navigation of dense mobile robots
Nächster Artikel Informed RRT* with improved converging rate by adopting wrapping procedure

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Metadaten
Titel
Optimal path planning in cluttered environment using RRT*-AB
verfasst von
Iram Noreen
Amna Khan
Hyejeong Ryu
Nakju Lett Doh
Zulfiqar Habib
Publikationsdatum
03.08.2017
Verlag
Springer Berlin Heidelberg
Erschienen in
Intelligent Service Robotics / Ausgabe 1/2018
Print ISSN: 1861-2776
Elektronische ISSN: 1861-2784
DOI
https://doi.org/10.1007/s11370-017-0236-7

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