Abstract:This paper addresses the problem of uneven trajectory distribution, nonlinearity trajectory and multi-maneuvering provided by the ship automatic identification system (AIS) equipment. Due to the such it is difficult to accurately determine the position of the ship by using the AIS equipment to assist the sea command system. Based on the traditional Kalman filter theory, a vessel trajectory prediction algorithm is carried out by constructing a polynomial Kalman filter to predict these using latitude and longitude information. The method also solves the data compensation and slower update problem. As the result of simulating the tracking effect, simple and fast as we can conclude, such method can effectively solve the problem of ship trajectory prediction in the actual process and meet the basic effectiveness and accuracy. In this case, relevant maritime department could predict the ship's purpose and behavior by taking such as a reliable auxiliary means.
Jin Zhi, Liang Shan, Cao Fangping. Visual Servo Tracking Method Based on Automatic Identification System For Vessels in Controlled Areas of Yangtze River [J]. Journal of Computer Applications, 2011, 31(12): 3414-3417. (in Chinese)
Zhao Shuaibing, Tang Cheng, Liang Shan, Wang Dejun. Track Prediction of Vessel in Controlled Waterway Based on Improved Kalman Filter [J]. Journal of Computer Applications, 2012, 32(11): 3247-3250. (in Chinese)
Wang Yibing, Ruan Linlin, Chen Qiongbing, Cai Min, et al. Estimation of Ship Navigation Trajectory Based on AIS Data [C]. China Satellite Navigation Conference, CSNC. (in Chinese)
[5]
Jaskolski, K. Automatic Identification System Dynamic Data Estimation Based on Discrete Kalman Filter Algorithm [J]. Scientific Journal of polish Naval Academy, 2017, 211(4): 71-87.
[6]
Sapankevych, N. and Sankar, R. Time Series Prediction using Support Vector Machines: A survey [J]. IEEE Compute Intell. Mag., 2009, 4(2): 24-38.
[7]
Jiang, S., Jin, H., and Wei, F. LS-SVM Application for Ship Course Model Predictive Control [J]. IEEE International Conference on Mechatronics and Automation (ICMA’13), 2013: 1615-1619.
Wang Yanfeng, Li Hongxiang. Track Prediction of Out of Control Ships in Bridge Area Waters [J]. Journal of Wuhan Institute of Shipbuilding Technology , 2011, 10(4): 34-38. (in Chinese)
[9]
Simsir U, Ertugrul S. Prediction of Manually Controlled Vessels Position and Course Navigating in Narrow Waterways Using Artificial Neural Networks [J]. Applied Soft Computing, 2009, 9(4): 1217-1224.
[10]
Qiao S, Han N, Zhu W. A Self-adaptive Parameter Selection Trajectory Prediction Approach via Hidden Markov Models [J]. IEEE Transactions on Intelligent Transportation Systems, 2016, 16(1): 284-296.
[11]
S. Fossen, T. I. Fossen. Exogenous Kalman Filter (XKF) for Visualization and Motion Prediction of Ships Using Live Automatic Identification System (AIS) Data [J]. Modeling, Identification and Control, 2018, 39(4): 233-244.
Qiao Shaojie, Han Nan, Zhu Xinwen, Shu Hongping, et al. A Dynamic Trajectory Prediction Algorithm Based on Kalman Filter [J]. ACTA Electronica SINICA, 2018, 46(2): 418-423. (in Chinese)
Wei Zhaokun. Zhou Kang, Wei Ming, et al. Ship Motion Pattern, Recognition and Application Based on AIS Data [J]. Journal of Shanghai Maritime University, 2016, 37(2): 18-23. (in Chinese)
Dong Jinnan, Xing Qianli, Ban Xiaolin. Application of Polynomial Predictive Filtering Technology in Intelligent Control [J]. Journal of Changchun Normal University, 2013, 32(2): 32-36. (in Chinese)
2019, Vol. 35 
