Incorporation of adaptive compression into a GPU parallel computing framework for analyzing large-scale vessel trajectories
Incorporation of adaptive compression into a GPU parallel computing framework for analyzing large-scale vessel trajectories
Automatic Identification System (AIS) offers a wealth of vessel navigation data, which underpins research in maritime data mining, situational awareness, and knowledge discovery within the realm of intelligent transportation systems. The flourishing marine industry has prompted AIS satellites and base stations to generate massive amounts of vessel trajectory data, escalating both data storage and calculation costs. The conventional Douglas-Peucker (DP) algorithm used for trajectory compression sets a uniform threshold, which hampers effective compression. Additionally, compressing and accelerating the computation of large datasets poses a significant challenge in real-world applications. To address these limitations, this paper aims to develop a new Graphics Processing Unit (GPU) parallel computing and compression framework that enables the acceleration of the optimal threshold calculation for each trajectory automatically in maritime big data mining. It achieves this by incorporating a new Adaptive DP with Speed and Course (ADPSC) algorithm, which utilizes the dynamic navigation characteristics of different vessels. It can effectively solve the associated computational time cost concern when using the ADPSC algorithm to compress vast trajectory datasets in the real world. Additionally, this paper proposes a novel evaluation metric for assessing compression efficacy based on the Dynamic Time Warping (DTW) method. Comprehensive experiments encompass vessel trajectory datasets from three representative research areas: Tianjin Port, Chengshan Jiao Promontory, and Caofeidian Port. The experimental results demonstrate that 1) the newly developed ADPSC method outperforms in terms of compression, and 2) the designed GPU parallel computing framework can significantly shorten the compression time for extensive datasets. The GPU-accelerated compression methodology not only minimizes storage and transmission costs for data from both manned and unmanned vessels but also enhances data processing speed, supporting real-time decision-making. From a theoretical perspective, it provides the key to the puzzle of realizing the real-time anti-collision of manned and unmanned ships, particularly in complex waters. It hence makes significant contributions to maritime safety in the autonomous shipping era.
Li, Yan
7163d69e-e9f6-46b9-844d-c029731b868b
Li, Huanhuan
5e806b21-10a7-465c-9db3-32e466ae42f1
Zhang, Chao
71be8f4c-9fd7-4dc6-96ba-a01f5d47e2f8
Zhao, Yunfeng
f1db7538-6b13-4d50-8b34-ad39038fb598
Yang, Zaili
82d4eebc-4532-4343-8555-35169e79bb6d
9 May 2024
Li, Yan
7163d69e-e9f6-46b9-844d-c029731b868b
Li, Huanhuan
5e806b21-10a7-465c-9db3-32e466ae42f1
Zhang, Chao
71be8f4c-9fd7-4dc6-96ba-a01f5d47e2f8
Zhao, Yunfeng
f1db7538-6b13-4d50-8b34-ad39038fb598
Yang, Zaili
82d4eebc-4532-4343-8555-35169e79bb6d
Li, Yan, Li, Huanhuan, Zhang, Chao, Zhao, Yunfeng and Yang, Zaili
(2024)
Incorporation of adaptive compression into a GPU parallel computing framework for analyzing large-scale vessel trajectories.
Transportation Research Part C: Emerging Technologies, 163, [104648].
(doi:10.1016/j.trc.2024.104648).
Abstract
Automatic Identification System (AIS) offers a wealth of vessel navigation data, which underpins research in maritime data mining, situational awareness, and knowledge discovery within the realm of intelligent transportation systems. The flourishing marine industry has prompted AIS satellites and base stations to generate massive amounts of vessel trajectory data, escalating both data storage and calculation costs. The conventional Douglas-Peucker (DP) algorithm used for trajectory compression sets a uniform threshold, which hampers effective compression. Additionally, compressing and accelerating the computation of large datasets poses a significant challenge in real-world applications. To address these limitations, this paper aims to develop a new Graphics Processing Unit (GPU) parallel computing and compression framework that enables the acceleration of the optimal threshold calculation for each trajectory automatically in maritime big data mining. It achieves this by incorporating a new Adaptive DP with Speed and Course (ADPSC) algorithm, which utilizes the dynamic navigation characteristics of different vessels. It can effectively solve the associated computational time cost concern when using the ADPSC algorithm to compress vast trajectory datasets in the real world. Additionally, this paper proposes a novel evaluation metric for assessing compression efficacy based on the Dynamic Time Warping (DTW) method. Comprehensive experiments encompass vessel trajectory datasets from three representative research areas: Tianjin Port, Chengshan Jiao Promontory, and Caofeidian Port. The experimental results demonstrate that 1) the newly developed ADPSC method outperforms in terms of compression, and 2) the designed GPU parallel computing framework can significantly shorten the compression time for extensive datasets. The GPU-accelerated compression methodology not only minimizes storage and transmission costs for data from both manned and unmanned vessels but also enhances data processing speed, supporting real-time decision-making. From a theoretical perspective, it provides the key to the puzzle of realizing the real-time anti-collision of manned and unmanned ships, particularly in complex waters. It hence makes significant contributions to maritime safety in the autonomous shipping era.
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Accepted/In Press date: 30 April 2024
e-pub ahead of print date: 9 May 2024
Published date: 9 May 2024
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Local EPrints ID: 503674
URI: http://eprints.soton.ac.uk/id/eprint/503674
ISSN: 0968-090X
PURE UUID: 8fd189c2-56d7-4298-a4b7-80e87705af4d
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Date deposited: 08 Aug 2025 16:41
Last modified: 22 Aug 2025 02:49
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Author:
Yan Li
Author:
Huanhuan Li
Author:
Chao Zhang
Author:
Yunfeng Zhao
Author:
Zaili Yang
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