Bi-directional information fusion-driven deep network for ship trajectory prediction in intelligent transportation systems
Bi-directional information fusion-driven deep network for ship trajectory prediction in intelligent transportation systems
Accurate ship trajectory prediction (STP) is crucial to realise the early warning of ship collision and ensure maritime safety. Driven by advancements in artificial intelligence technology, deep learning-based STP has become a predominant approach in the research field of ship collision avoidance. This paper, based on a state-of-the-art survey of the existing STP research progress, aims to develop a new bi-directional information fusion-driven prediction model that enables the achievement of more accurate STP results by addressing the drawbacks of the classical methods in the field. In this context, a cascading network model is developed by combining two bi-directional networks in a specific order. It incorporates the Bi-directional Long Short-Term Memory (BiLSTM) and the Bi-directional Gated Recurrent Unit (BiGRU) neural network into a single three-layer, information-enhanced network. It takes advantage of both networks to realise more accurate prediction of ship trajectories. Furthermore, the performance of the proposed model is comprehensively evaluated using Automatic Identification System (AIS) data from three water areas representing traffic scenarios of different safety concerns. The superiority of the proposed model is verified through comparative analysis with twenty other methods, including the state-of-the-art STP in the literature. The finding reveals that the new model is better than all the benchmarked ones, and thus, the new STP solution in this paper makes new contributions to improving autonomous navigation and maritime safety.
Li, Huanhuan
5e806b21-10a7-465c-9db3-32e466ae42f1
Xing, Wenbin
af8672b7-7b06-46e1-873b-b5b27159e9fe
Jiao, Hang
af70e929-ff8d-4020-92a5-34c55f6aba7c
Yuen, Kum Fai
5acba8bd-2837-4913-8ec8-5b9b98cb04b9
Gao, Ruobin
0ccb66e0-4b50-442c-8619-620469b4974b
Li, Yan
94bcb2e0-bfff-4a20-ba97-d32b5cbb0b2e
Matthews, Christian
b381b23a-9002-49d7-8a74-d81abdea27dc
Yang, Zaili
82d4eebc-4532-4343-8555-35169e79bb6d
20 September 2024
Li, Huanhuan
5e806b21-10a7-465c-9db3-32e466ae42f1
Xing, Wenbin
af8672b7-7b06-46e1-873b-b5b27159e9fe
Jiao, Hang
af70e929-ff8d-4020-92a5-34c55f6aba7c
Yuen, Kum Fai
5acba8bd-2837-4913-8ec8-5b9b98cb04b9
Gao, Ruobin
0ccb66e0-4b50-442c-8619-620469b4974b
Li, Yan
94bcb2e0-bfff-4a20-ba97-d32b5cbb0b2e
Matthews, Christian
b381b23a-9002-49d7-8a74-d81abdea27dc
Yang, Zaili
82d4eebc-4532-4343-8555-35169e79bb6d
Li, Huanhuan, Xing, Wenbin, Jiao, Hang, Yuen, Kum Fai, Gao, Ruobin, Li, Yan, Matthews, Christian and Yang, Zaili
(2024)
Bi-directional information fusion-driven deep network for ship trajectory prediction in intelligent transportation systems.
Transportation Research Part E: Logistics and Transportation Review, 192, [103770].
(doi:10.1016/j.tre.2024.103770).
Abstract
Accurate ship trajectory prediction (STP) is crucial to realise the early warning of ship collision and ensure maritime safety. Driven by advancements in artificial intelligence technology, deep learning-based STP has become a predominant approach in the research field of ship collision avoidance. This paper, based on a state-of-the-art survey of the existing STP research progress, aims to develop a new bi-directional information fusion-driven prediction model that enables the achievement of more accurate STP results by addressing the drawbacks of the classical methods in the field. In this context, a cascading network model is developed by combining two bi-directional networks in a specific order. It incorporates the Bi-directional Long Short-Term Memory (BiLSTM) and the Bi-directional Gated Recurrent Unit (BiGRU) neural network into a single three-layer, information-enhanced network. It takes advantage of both networks to realise more accurate prediction of ship trajectories. Furthermore, the performance of the proposed model is comprehensively evaluated using Automatic Identification System (AIS) data from three water areas representing traffic scenarios of different safety concerns. The superiority of the proposed model is verified through comparative analysis with twenty other methods, including the state-of-the-art STP in the literature. The finding reveals that the new model is better than all the benchmarked ones, and thus, the new STP solution in this paper makes new contributions to improving autonomous navigation and maritime safety.
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Accepted/In Press date: 5 September 2024
e-pub ahead of print date: 20 September 2024
Published date: 20 September 2024
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Local EPrints ID: 503698
URI: http://eprints.soton.ac.uk/id/eprint/503698
ISSN: 1366-5545
PURE UUID: dc954957-1e2a-41d2-9140-705ac7314945
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Date deposited: 11 Aug 2025 16:34
Last modified: 22 Aug 2025 02:49
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Author:
Huanhuan Li
Author:
Wenbin Xing
Author:
Hang Jiao
Author:
Kum Fai Yuen
Author:
Ruobin Gao
Author:
Yan Li
Author:
Christian Matthews
Author:
Zaili Yang
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