

系统工程与电子技术 ›› 2026, Vol. 48 ›› Issue (7): 2424-2433.doi: 10.12305/j.issn.1001-506X.2026.07.26
• 制导、导航与控制 • 上一篇
李强, 周荻, 李思远, 林玉荣
收稿日期:2025-05-08
修回日期:2025-06-29
出版日期:2025-11-06
发布日期:2025-11-06
通讯作者:
周荻
Qiang LI, Di ZHOU, Siyuan LI, Yurong LIN
Received:2025-05-08
Revised:2025-06-29
Online:2025-11-06
Published:2025-11-06
Contact:
Di ZHOU
摘要:
针对气动扰动、目标机动、执行器故障及导弹参数变化带来的复杂影响,提出一种基于深度强化学习(deep reinforcement learning, DRL)的自适应制导框架。首先,采用熵正则化DRL,利用深层神经网络(deep neural network, DNN)作为预测模型,结合遗忘机制增强元学习,动态调整经验回放权重以聚焦当前环境。之后,设计双模型预测架构,集成交叉熵方法模型预测控制(cross-entropy method model predictive control, CEM-MPC)和自适应熵的模型预测路径积分(model predictive path integral, MPPI)控制,监测成本标准差变化率,在波动超阈值时自动切换控制策略,以发挥两种控制器的收敛速度和探索能力优势。仿真表明,相比传统基于学习的非自适应方法,所提方法视线角速率稳定,拦截成功率分别提升47.6%和6.0%,验证了本方法的有效性。
中图分类号:
李强, 周荻, 李思远, 林玉荣. 基于元学习与预测控制的导弹自适应制导[J]. 系统工程与电子技术, 2026, 48(7): 2424-2433.
Qiang LI, Di ZHOU, Siyuan LI, Yurong LIN. Adaptive guidance for missile based on meta-learning and predictive control[J]. Systems Engineering and Electronics, 2026, 48(7): 2424-2433.
表6
仿真环境参数设置"
| 参数 | 值 |
| 导弹−目标距离/m | 3 300 |
| 导弹仰角/rad | (−0.18,0.18) |
| 导弹偏角/rad | (−0.21,0.21) |
| 视线仰角/rad | (−0.6,−0.4) |
| 视线偏角/rad | (0.65,0.85) |
| 目标仰角/rad | (−0.17,0.17) |
| 目标偏角/rad | (−0.35,0.35) |
| 导弹初始速度/(m/s) | 1 000 |
| 目标初始速度/(m/s) | 300 |
| 目标y轴加速度/(m/s−2) | (28sin t,30sin t) |
| 目标z轴加速度/(m/s-2) | (28sin t,30sin t) |
| 执行器故障范围 | (−0.3,0) |
| 执行器故障发生时间/s | 2.5 |
| 零升阻力波动范围/% | (−3,3) |
| 诱导阻力波动范围/% | (−3,3) |
| 大气密度波动范围/% | (−3,3) |
| 推力持续时间/s | 3.0 |
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