基于可解释分层强化学习的防空反导策略优化

doi:10.7527/S1000-6893.2025.32786

Abstract

Abstract:

Air and Missile Defense （AMD） systems are core elements of a nation’s aerospace security shield， and their target-interception capability is key to determining combat effectiveness. With the evolution of warfare， the AMD interception problem is increasingly characterized by large target scales， pronounced value heterogeneity， and stringent real-time requirements. Existing techniques typically face an interception policy space that grows exponentially with target count， poor sample efficiency under delayed rewards， and opaque decision processes， making them insufficient for operational needs. To address these challenges， this paper proposes an interception strategy framework based on Explainable Hierarchical Dueling DQN （EHD-DQN）. This framework suppresses exponential policy-space growth and shortens the decision chain through a hierarchical decoupling of “upper-level ranking → lower-level interception”. A temporally decayed multi-experience buffers is introduced to improve sample efficiency and convergence stability under delayed rewards. Moreover， an explainability module that combines Gradient-weighted Class Activation Mapping （Grad-CAM） and Local Interpretable Model-agnostic Explanations （LIME） is embedded to inject explanation signals into the training loop and provide traceable decision rationales. Compared with Deep Q-Network （DQN）， Deep Deterministic Policy Gradient （DDPG）， Proximal Policy Optimization （PPO）， and three traditional optimization algorithms—Rolling-Horizon Mixed-Integer Linear Programming （RH-MILP）， Non-dominated Sorting Genetic Algorithm Ⅱ （NSGA-Ⅱ）， and Adaptive Large Neighborhood Search （ALNS）， EHD-DQN achieves superior performance in interception count， ammunition utilization， and engagement timing for high-value targets， while furnishing transparent， staff-oriented justifications for command decision-making. The results indicate that EHD-DQN offers an efficient and explainable decision-making paradigm for AMD command-and-control systems.

Key words: hierarchical reinforcement learning, explainable artificial intelligence, air defense and anti-missile decision-making, dueling DQN, collaborative optimization

CLC Number:

Yuheng LIU, Li YANG, Qilong HUANG. Optimizing air and missile defense strategies with explainable hierarchical reinforcement learning[J]. Acta Aeronautica et Astronautica Sinica, 2026, 47(8): 332786.

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类别	弹药数量	火力单元数量	弹药速度
远程火力单元	16	1	高
中程火力单元	20	2	中
近程火力单元	30	2	低

类别	速度/（km·s^-1）	最大转率/（rad·s^-1）
战斗机	0.25	0.10
巡航导弹	0.24	0.21
无人机	0.06	0.05
远/中/近程拦截弹	0.90/0.65/0.45	0.35/0.28/0.22

阶段	时刻	上层高价值目标（ID/类型/距目标）	下层分配
前期	2	T07/战斗机/120，T03/战斗机/128，T05/战斗机/132，T12/巡航弹/160，T21/巡航弹/168	LR1→T07，MR1→T12，MR2→T21，SR1→T31，SR2→T33
前期	4	T07/战斗机/120，T03/战斗机/128，T05/战斗机/132，T12/巡航弹/160，T21/巡航弹/168	LR1→T03，MR1→T09，MR2→T27，SR1→T36，SR2→T37
中期	12	T27/巡航弹/68，T18/巡航弹/72，T24/巡航弹/80，T32/巡航弹/83，T05/战斗机/76	LR1→T05，MR1→T18，MR2→T27，SR1→T35，SR2→T40
中期	14	T18/巡航弹/66，T24/巡航弹/74，T38/巡航弹/82，T34/巡航弹/84，T41/无人机/96	LR1→T11，MR1→T18，MR2→T24，SR1→T41，SR2→T38
后期	22	T33/无人机/70，T40/无人机/74，T41/无人机/78，T24/巡航弹/63，T32/巡航弹/72	LR1→T24，MR1→T32，MR2→T38，SR1→T33，SR2→T40
后期	24	T40/无人机/68，T41/无人机/70，T42/无人机/72，T34/巡航弹/71，T29/巡航弹/73	LR1→T34，MR1→T29，MR2→T32，SR1→T40，SR2→T41

Optimizing air and missile defense strategies with explainable hierarchical reinforcement learning

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