open access publication

Article, 2024

AISClean: AIS data-driven vessel trajectory reconstruction under uncertain conditions

Ocean Engineering, ISSN 1873-5258, 0029-8018, Volume 306, Page 117987, 10.1016/j.oceaneng.2024.117987

Contributors

Liang, Maohan 0000-0001-7470-3313 [1] Su, Jianlong [2] Liu, Ryan Wen 0000-0002-1591-5583 (Corresponding author) [2] Lam, Jasmine Siu Lee 0000-0001-7920-2665 (Corresponding author) [3]

Affiliations

  1. [1] National University of Singapore
    2. [NORA names: Singapore; Asia, South];
  2. [2] Wuhan University of Technology
    3. [NORA names: China; Asia, East];
  3. [3] Technical University of Denmark
    4. [NORA names: DTU Technical University of Denmark; University; Denmark; Europe, EU; Nordic; OECD]

Abstract

In maritime transportation, intelligent vessel surveillance has become increasingly prevalent and widespread by collecting and analyzing high massive spatial data from automatic identification system (AIS). The state-of-the-art AIS devices contain various functionalities, such as position transmission, tracking navigation, etc. Widely equipped shipboard AIS devices provide a large amount of real-time and historical vessel trajectory data for maritime management. However, the original AIS data often suffers from unwanted noise (i.e., poorly tracked timestamped points for vessel trajectories) and missing (i.e., no data is received or transmitted for a long term) data during signal acquisition, transmission, and analog-to-digital conversion. This degradation in data quality poses significant risks, including potential miscalculations in vessel collision avoidance systems, inaccuracies in emission calculations, and challenges in port management. In this work, a data-driven vessel trajectory reconstruction framework considering historical features is proposed to enhance the reliability of vessel trajectory. Specifically, a series of statistical methods are proposed to identify noisy data and missing data. Then, a model combining Geohash and dynamic time warping algorithms is developed to restore the trajectories degraded by random noise and missing data in vessel trajectories. Comparative experiments with baseline methods on multiple datasets verify the effectiveness of the proposed data-driven model.

Keywords

AI devices, AIS data, Automatic Identification System, Geohash, acquisition, algorithm, analog-to-digital conversion, avoidance system, baseline, baseline methods, calculations, collision avoidance system, conditions, conversion, data, data quality, data-driven models, dataset, degradation, devices, dynamic time warping algorithm, effect, emission, emission calculations, features, framework, function, historical features, identification system, inaccuracy, management, maritime management, maritime transport, massive spatial data, method, miscalculation, missing data, model, multiple datasets, navigation, noise, noisy data, original AIS data, port, port management, position, positive transmission, quality, random noise, real-time, reconstruction, reconstruction framework, reliability, risk, signal, signal acquisition, spatial data, state-of-the-art, statistical methods, surveillance, system, time warping algorithm, tracking navigation, trajectory, trajectory data, trajectory reconstruction, transmission, transport, uncertain conditions, vessel trajectories, vessel trajectory data, vessel trajectory reconstruction, vessels, warping algorithm

Funders

  • China Scholarship Council

Data Provider: Digital Science

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