This work is licensed under the Creative Commons Attribution 4.0 International License.
Vinayak, P. P., Prabu, C. S. K., Vishwanath, N., & Prakash, S. O. (2021). Numerical simulation of ship navigation in rough seas based on ecmwf data. Brodogradnja(1).Search in Google Scholar
Qiang, L., Bing-Dong, Y., & Bi-Guang, H. (2018). Calculation and measurement of tide height for the navigation of ship at high tide using artificial neural network. Polish Maritime Research, 25(s3), 99-110.Search in Google Scholar
Liu, Z. (2019). Pre filtered backstepping control for underactuated ship path following. Polish Maritime Research, 26(2), 68-75.Search in Google Scholar
Tan, W. C., Chua, K. H., & Wu, Y. (2020). The automated risk estimation for the navigation of autonomous ships by learning with navigation feature. International Journal of Computational Methods.Search in Google Scholar
Fang, M. C., Tsai, K. Y., & Fang, C. C. (2018). A simplified simulation model of ship navigation for safety and collision avoidance in heavy traffic areas. The Journal of Navigation, 71(4), 837-860.Search in Google Scholar
Desanto, J. B., Chadwell, C. D., & Sandwell, D. T. (2018). Kinematic post-processing of ship navigation data using precise point positioning. Journal of Navigation, 72(3), 1-10.Search in Google Scholar
Bolbot, V., Theotokatos, G., & Wennersberg, L. (2022). A method to identify and rank objects and hazardous interactions affecting autonomous ships navigation. Journal of Navigation, 75, 572 - 593.Search in Google Scholar
Weng, J., Li, G., & Zhao, Y. (2022). Detection of abnormal ship trajectory based on the complex polygon. Journal of navigation.Search in Google Scholar
Huang, Z., Hu, Q., Mei, Q., Yang, C., & Wu, Z. (2021). Identity recognition on waterways: a novel ship information tracking method based on multimodal data. Journal of navigation(6), 74.Search in Google Scholar
White, P. F., Piro, D. J., Knight, B. G., & Makl, K. J. (2022). A hybrid numerical framework for simulation of ships maneuvering in waves. Journal of ship research(2), 66.Search in Google Scholar
Bolbot, V., Theotokatos, G., Boulougouris, E., & Vassalos, D. (2020). A novel cyber-risk assessment method for ship systems. Safety science(131-), 131.Search in Google Scholar
Dymarski, C. (2019). A concept design of diesel - hydraulic propulsion system for passenger ship intended for inland shallow water navigation. Polish Maritime Research, 26(3), 30-38.Search in Google Scholar
Ladue, D., & Tetreault, B. (2017). Improving navigation safety with better charts: prototyping ais for ship reporting of enc discrepancies. Sea Technology, 58(3), 20-24.Search in Google Scholar
Li, L., Lu, W., Niu, J., Liu, J., & Liu, D. (2017). Ais data-based decision model for navigation risk in sea areas. Journal of Navigation, 1-15.Search in Google Scholar
Rawson, A., Brito, M., Sabeur, Z., & Tran-Thanh, L. (2021). A machine learning approach for monitoring ship safety in extreme weather events. Safety science(141-), 141.Search in Google Scholar
Luo, W., Yang, B., & Sun, Y. (2021). Hydrodynamic analysis of kvlcc2 ship sailing near inclined banks. Mathematical Problems in Engineering, 2021.Search in Google Scholar
Nguyen, V. T., & Chandar, D. (2023). Ship specific optimization of pre-duct energy saving devices using reduced order models. Applied Ocean Research, 131, 103449-.Search in Google Scholar
Yuan, Z. M. (2019). Ship hydrodynamics in confined waterways. Journal of Ship Research, 63(1), 16-29.Search in Google Scholar
Gupta, P., Taskar, B., Steen, S., & Rasheed, A. (2021). Statistical modeling of ship’s hydrodynamic performance indicator. Applied Ocean Research, 111, 102623-.Search in Google Scholar
Tripathi, S., & Vijayakumar, R. (2024). Numerical and experimental study of stern flaps impact on resistance and propulsion of high–speed displacement ships. Ocean engineering(Jan.15), 292.Search in Google Scholar
He, J., Yang, C. J., Zhu, R. C., & Noblesse, F. (2023). Alternative flow models, vector green functions and boundary integral flow representations in ship and offshore hydrodynamics. Ocean Engineering, 270, 113630-.Search in Google Scholar
Zhaopeng Song,Min Zeng,Zhengliang Li,Xiaowu Ma & Zhimiao Li.(2024).Numerical investigation of inlet-pipe configurations on fluid dynamics and flow-field characteristics inside filling valve.Flow Measurement and Instrumentation102612-.Search in Google Scholar
Han M.M. & Wang C.M.(2022).Potential flow theory-based analytical and numerical modelling of porous and perforated breakwaters: A review.Ocean Engineering.Search in Google Scholar
Huai Yi Xie.(2024).Dipole-dipole interactions in the presence of a topological insulator stratified sphere: dyadic Green’s function method.Physica Scripta(6).Search in Google Scholar
