Optimizing anti-collision strategy for MASS: a safe reinforcement learning approach to improve maritime traffic safety
Optimizing anti-collision strategy for MASS: a safe reinforcement learning approach to improve maritime traffic safety
Maritime autonomous surface ships (MASS) promise enhanced efficiency, reduced human errors, and to improve maritime traffic safety. However, MASS navigation in complex maritime traffic presents challenges, especially in collision avoidance strategy optimization (CASO). This paper proposes a novel risk-based CASO approach based on safe reinforcement learning (SRL) with a reliability and risk hierarchical critic network (SRL-R2HCN) approach. Key steps in developing the approach start with the formulation of collision risk assessment. This is followed by the construction of a hierarchical network structure, supplemented by the supporting reward function, multi-objective function, and reliability measurement to realize the SRL-R2HCN. Finally, simulation experiments are conducted in mixed obstacle scenarios, and the results are compared with traditional algorithms to showcase the advancement and fidelity of the new SRL-R2HCN method. The results demonstrate that the proposed method can accurately assess collision risks in mixed obstacle scenarios and generate safe, efficient, and reliable collision avoidance strategies. The outcomes of this research provide a sound theoretical basis for the future development of MASS navigation safety and significant potential to improve the safe and efficient operations of MASS. Furthermore, the methodology could also benefit maritime transportation and shipping management.
Wang, Chengbo
08e72cc5-67a7-448b-ba20-46ae3ed588da
Zhang, Xinyu
f67f941c-6e25-4a19-ada0-a35a0061f838
Gao, Hongbo
9af7d842-ea39-4d80-8051-3bddf4131647
Bashir, Musa
03146b14-6871-4656-8318-d25655175374
Li, Huanhuan
5e806b21-10a7-465c-9db3-32e466ae42f1
Yang, Zaili
82d4eebc-4532-4343-8555-35169e79bb6d
29 April 2024
Wang, Chengbo
08e72cc5-67a7-448b-ba20-46ae3ed588da
Zhang, Xinyu
f67f941c-6e25-4a19-ada0-a35a0061f838
Gao, Hongbo
9af7d842-ea39-4d80-8051-3bddf4131647
Bashir, Musa
03146b14-6871-4656-8318-d25655175374
Li, Huanhuan
5e806b21-10a7-465c-9db3-32e466ae42f1
Yang, Zaili
82d4eebc-4532-4343-8555-35169e79bb6d
Wang, Chengbo, Zhang, Xinyu, Gao, Hongbo, Bashir, Musa, Li, Huanhuan and Yang, Zaili
(2024)
Optimizing anti-collision strategy for MASS: a safe reinforcement learning approach to improve maritime traffic safety.
Ocean & Coastal Management, 253, [107161].
(doi:10.1016/j.ocecoaman.2024.107161).
Abstract
Maritime autonomous surface ships (MASS) promise enhanced efficiency, reduced human errors, and to improve maritime traffic safety. However, MASS navigation in complex maritime traffic presents challenges, especially in collision avoidance strategy optimization (CASO). This paper proposes a novel risk-based CASO approach based on safe reinforcement learning (SRL) with a reliability and risk hierarchical critic network (SRL-R2HCN) approach. Key steps in developing the approach start with the formulation of collision risk assessment. This is followed by the construction of a hierarchical network structure, supplemented by the supporting reward function, multi-objective function, and reliability measurement to realize the SRL-R2HCN. Finally, simulation experiments are conducted in mixed obstacle scenarios, and the results are compared with traditional algorithms to showcase the advancement and fidelity of the new SRL-R2HCN method. The results demonstrate that the proposed method can accurately assess collision risks in mixed obstacle scenarios and generate safe, efficient, and reliable collision avoidance strategies. The outcomes of this research provide a sound theoretical basis for the future development of MASS navigation safety and significant potential to improve the safe and efficient operations of MASS. Furthermore, the methodology could also benefit maritime transportation and shipping management.
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Accepted/In Press date: 14 April 2024
e-pub ahead of print date: 29 April 2024
Published date: 29 April 2024
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Local EPrints ID: 503693
URI: http://eprints.soton.ac.uk/id/eprint/503693
ISSN: 0964-5691
PURE UUID: 7e261fa4-400f-4fa0-aa3d-58071369a964
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Date deposited: 11 Aug 2025 16:31
Last modified: 22 Aug 2025 02:49
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Contributors
Author:
Chengbo Wang
Author:
Xinyu Zhang
Author:
Hongbo Gao
Author:
Musa Bashir
Author:
Huanhuan Li
Author:
Zaili Yang
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