基于分散深度强化学习的动态雷暴环境下多机协同轨迹规划模型

IF 11.5 1区 工程技术 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Advanced Engineering Informatics Pub Date : 2025-05-01 Epub Date: 2025-02-03 DOI:10.1016/j.aei.2025.103157
Bizhao Pang , Xinting Hu , Mingcheng Zhang , Sameer Alam , Guglielmo Lulli
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引用次数: 0

摘要

气候变化导致恶劣天气,特别是雷暴的频率增加,对航线空域的安全和效率构成重大挑战,特别是在空中交通管制服务有限的海洋区域。这些情况需要多机协同轨迹规划,以避免动态雷暴和其他飞机。现有文献通常依赖于集中式方法和单智能体原则,当周围的飞机或雷暴改变路径时,这些方法缺乏协调性和鲁棒性,导致由于大量的轨迹再生需求而导致可扩展性问题。为了解决这些问题,本文引入了一种多智能体协作的自主轨迹规划方法。该问题被建模为分散的马尔可夫决策过程(DEC-MDP),并使用独立的深度确定性策略梯度(IDDPG)学习框架来解决。使用来自所有飞机的综合经验来训练共享的actor-critic网络以优化联合行为。在执行过程中,每架飞机根据自己的观察独立行动,并通过共享策略确保协调。该模型通过广泛的模拟验证,包括不确定性分析、基线比较和消融研究。在已知雷暴路径下,模型的分离率损失为2%,在随机路径下,模型的分离率损失为4%。ETA不确定性分析证明了该模型的鲁棒性,而与快速行进树和集中式DDPG的基线比较则突出了其可扩展性和效率。这些发现有助于推进自主飞机操作。
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A multi-aircraft co-operative trajectory planning model under dynamic thunderstorm cells using decentralized deep reinforcement learning
Climate change induces an increased frequency of adverse weather, particularly thunderstorms, posing significant safety and efficiency challenges in en route airspace, especially in oceanic regions with limited air traffic control services. These conditions require multi-aircraft cooperative trajectory planning to avoid both dynamic thunderstorms and other aircraft. Existing literature has typically relied on centralized approaches and single-agent principles, which lack coordination and robustness when surrounding aircraft or thunderstorms change paths, leading to scalability issues due to heavy trajectory regeneration needs. To address these gaps, this paper introduces a multi-agent cooperative method for autonomous trajectory planning. The problem is modeled as a Decentralized Markov Decision Process (DEC-MDP) and solved using an Independent Deep Deterministic Policy Gradient (IDDPG) learning framework. A shared actor-critic network is trained using combined experiences from all aircraft to optimize joint behavior. During execution, each aircraft acts independently based on its own observations, with coordination ensured through the shared policy. The model is validated through extensive simulations, including uncertainty analysis, baseline comparisons, and ablation studies. Under known thunderstorm paths, the model achieved a 2 % loss of separation rate, increasing to 4 % with random storm paths. ETA uncertainty analysis demonstrated the model’s robustness, while baseline comparisons with the Fast Marching Tree and centralized DDPG highlighted its scalability and efficiency. These findings contribute to advancing autonomous aircraft operations.
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来源期刊
Advanced Engineering Informatics
Advanced Engineering Informatics 工程技术-工程:综合
CiteScore
12.40
自引率
18.20%
发文量
292
审稿时长
45 days
期刊介绍: Advanced Engineering Informatics is an international Journal that solicits research papers with an emphasis on 'knowledge' and 'engineering applications'. The Journal seeks original papers that report progress in applying methods of engineering informatics. These papers should have engineering relevance and help provide a scientific base for more reliable, spontaneous, and creative engineering decision-making. Additionally, papers should demonstrate the science of supporting knowledge-intensive engineering tasks and validate the generality, power, and scalability of new methods through rigorous evaluation, preferably both qualitatively and quantitatively. Abstracting and indexing for Advanced Engineering Informatics include Science Citation Index Expanded, Scopus and INSPEC.
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