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一种面向航空母舰甲板运动状态预估的鲁棒学习模型

王可 徐明亮 李亚飞 姜晓恒 鲁爱国 李鉴

王可, 徐明亮, 李亚飞, 姜晓恒, 鲁爱国, 李鉴. 一种面向航空母舰甲板运动状态预估的鲁棒学习模型. 自动化学报, 2024, 50(9): 1785−1793 doi: 10.16383/j.aas.c210664
引用本文: 王可, 徐明亮, 李亚飞, 姜晓恒, 鲁爱国, 李鉴. 一种面向航空母舰甲板运动状态预估的鲁棒学习模型. 自动化学报, 2024, 50(9): 1785−1793 doi: 10.16383/j.aas.c210664
Wang Ke, Xu Ming-Liang, Li Ya-Fei, Jiang Xiao-Heng, Lu Ai-Guo, Li Jian. A robust learning model for deck motion prediction of aircraft carrier. Acta Automatica Sinica, 2024, 50(9): 1785−1793 doi: 10.16383/j.aas.c210664
Citation: Wang Ke, Xu Ming-Liang, Li Ya-Fei, Jiang Xiao-Heng, Lu Ai-Guo, Li Jian. A robust learning model for deck motion prediction of aircraft carrier. Acta Automatica Sinica, 2024, 50(9): 1785−1793 doi: 10.16383/j.aas.c210664

一种面向航空母舰甲板运动状态预估的鲁棒学习模型

doi: 10.16383/j.aas.c210664 cstr: 32138.14.j.aas.c210664
基金项目: 国家自然科学基金 (62036010, 61972362, 61802351), 中国博士后科学基金 (2020M682348), 海洋防务技术创新中心创新基金 (JJ-2022-709-01), 河南省自然科学基金 (232300421235)资助
详细信息
    作者简介:

    王可:郑州大学计算机与人工智能学院讲师. 主要研究方向为基于计算智能的优化与学习. E-mail: iekwang@zzu.edu.cn

    徐明亮:郑州大学计算机与人工智能学院教授. 主要研究方向为计算机图形学, 人工智能. 本文通信作者. E-mail: iexumingliang@zzu.edu.cn

    李亚飞:郑州大学计算机与人工智能学院教授. 主要研究方向为群体智能与机器学习.E-mail: ieyfei@zzu.edu.cn

    姜晓恒:郑州大学计算机与人工智能学院副教授. 主要研究方向为深度学习, 机器视觉.E-mail: jiangxiaoheng@zzu.edu.cn

    鲁爱国:武汉数字工程研究所研究员. 主要研究方向为信息系统与软件, 人机交互.E-mail: aigwx@163.edu.com

    李鉴:武汉数字工程研究所研究员. 主要研究方向为信息系统与软件. E-mail: lij1015@sina.com

A Robust Learning Model for Deck Motion Prediction of Aircraft Carrier

Funds: Supported by National Natural Science Foundation of China (62036010, 61972362, 61802351), China Postdoctoral Science Foundation (2020M682348), Innovation Foundation of Ocean Defense Technology Innovation Center (JJ-2022-709-01), and Natural Science Foundation of Henan Province (232300421235)
More Information
    Author Bio:

    WANG Ke Lecturer at the School of Computer and Artificial Intelligence, Zhengzhou University. His research interest covers computational intelligence based optimization and learning

    XU Ming-Liang Professor at the School of Computer and Artificial Intelligence, Zhengzhou University. His research interest covers computer graphics and artificial intelligence. Corresponding author of this paper

    LI Ya-Fei Professor at the School of Computer and Artificial Intelligence, Zhengzhou University. His research interest covers swarm intelligence and machine learning

    JIANG Xiao-Heng Associate professor at the School of Computer and Artificial Intelligence, Zhengzhou University. His research interest covers deep learning and computer vision

    LU Ai-Guo Professor at Wuhan Digital Engineering Institute. His research interest covers information system and software, and human-computer interaction

    LI Jian Professor at Wuhan Digital Engineering Institute. His research interest covers information system and software

  • 摘要: 航母甲板在风、浪、流等因素影响下做六自由度不规则运动, 影响舰载机着舰精度. 航母甲板运动预估与补偿是自动着舰系统的重要功能之一, 也是提高舰载机着舰安全性与成功率的关键技术之一. 为此, 提出一种面向甲板运动预估的鲁棒学习模型, 通过基本构建单元自适应演化出复杂学习系统. 构建单元的训练采用非梯度的伪逆学习策略, 提高了训练效率, 简化了学习控制超参数调优; 构建单元的架构设计采用数据驱动的策略, 简化了架构超参数调优; 采用图拉普拉斯正则化方法提高了模型对噪声和意外扰动的鲁棒性. 通过某型航母在中等海况条件下以典型航速巡航时的仿真实验, 验证了所提方法在甲板纵摇、横摇以及垂荡运动预估问题中的有效性及鲁棒性.
  • 图  1  舰船平移运动及摇荡运动

    Fig.  1  The translational motion and swaying motion of a ship

    图  2  多个子模型集成学习系统架构

    Fig.  2  The architecture of the ensemble learning system with multiple sub-models

    图  3  不同信噪比下的甲板纵摇预估结果

    Fig.  3  The prediction results of deck pitch with different SNR

    图  5  不同信噪比下的甲板垂荡预估结果

    Fig.  5  The prediction results of deck heave with different SNR

    图  7  PILAE 与 PILAE-Lap 的甲板横摇预估结果对比

    Fig.  7  The deck roll prediction results comparison between PILAE and PILAE-Lap

    图  4  不同信噪比下的甲板横摇预估结果

    Fig.  4  The prediction results of deck roll with different SNR

    图  6  PILAE 与 PILAE-Lap 的甲板纵摇预估结果对比

    Fig.  6  The deck pitch prediction results comparison between PILAE and PILAE-Lap

    图  8  PILAE与PILAE-Lap的甲板垂荡预估结果对比

    Fig.  8  The deck heave prediction results comparison between PILAE and PILAE-Lap

    图  9  本文所提方法与其他方法的训练耗时对比

    Fig.  9  Training time comparison between our proposed method and others

    图  10  本文方法生成的网络架构及运动预估性能

    Fig.  10  The network architectures generated by our proposed method and its motion prediction performance

    图  11  预估性能与子模型个数的关系

    Fig.  11  The prediction performance with different number of sub-model

    表  1  本文所提方法与其他方法的预测均方误差对比

    Table  1  Comparison of prediction MSE between our proposed method with others

    方法PitchRollHeave
    BPNN0.021 20.016 50.075 4
    ELM0.019 80.116 50.076 5
    KELM-PSO0.012 40.013 70.056 0
    Kalman filter0.022 40.573 70.026 1
    Autoregression0.006 60.016 80.020 8
    本文方法0.001 50.025 40.002 9
    注: 加粗字体表示各列最优结果.
    下载: 导出CSV
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出版历程
  • 收稿日期:  2021-07-19
  • 网络出版日期:  2021-11-29
  • 刊出日期:  2024-09-19

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