利用基于 Voronoi-Based 的障碍物建模和 Q-Learning 增强复杂环境中的多无人飞行器路径规划

IF 1.1 4区工程技术 Q3 ENGINEERING, AEROSPACE

International Journal of Aerospace Engineering Pub Date : 2024-05-27 DOI:10.1155/2024/5114696

Wenjia Su, Min Gao, Xinbao Gao, Zhaolong Xuan

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引用次数: 0

摘要

为解决复杂环境中多个无人飞行器（UAV）的避障路径规划难题，本研究引入了基于 Voronoi 图的模型来表示障碍物密集的环境，并采用马尔可夫决策过程（MDP）来进行单个无人飞行器的路径规划。通过调整 Q 表的初始状态和微调奖惩值，改进了传统的 Q-learning 算法，使单个无人飞行器能够在复杂环境中获得高效的避障路径。利用针对单个无人机的改进型 Q 学习算法，对无人机群的 Q 表进行迭代改进，并根据每个无人机选择的航点进行动态修改。这种方法可确保为多个无人机生成无碰撞路径，仿真结果也验证了这一点，展示了该算法从过去的训练数据中学习的有效性。所提出的方法为在复杂环境中生成实用的无人机轨迹提供了一个稳健的框架。

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Enhanced Multi-UAV Path Planning in Complex Environments With Voronoi-Based Obstacle Modelling and Q-Learning

To tackle the challenge of obstacle avoidance path planning for multiple unmanned aerial vehicles (UAVs) in intricate environments, this study introduces a Voronoi graph–based model to represent the obstacle-laden environment and employs a Markov decision process (MDP) for single UAV path planning. The traditional Q-learning algorithm is enhanced by adjusting the initial state of the Q-table and fine-tuning the reward and penalty values, enabling the acquisition of efficient obstacle avoidance paths for individual UAVs in complex settings. Leveraging the improved Q-learning algorithm for single UAVs, the Q-table is iteratively refined for a fleet of UAVs, with dynamic modifications based on the waypoints chosen by each UAV. This approach ensures the generation of collision-free paths for multiple UAVs, as validated by simulation results that showcase the algorithm’s effectiveness in learning from past training data. The proposed method offers a robust framework for practical UAV trajectory generation in complex environments.

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来源期刊

International Journal of Aerospace Engineering ENGINEERING, AEROSPACE-

CiteScore

2.70

自引率

7.10%

发文量

195

审稿时长

22 weeks

期刊介绍： International Journal of Aerospace Engineering aims to serve the international aerospace engineering community through dissemination of scientific knowledge on practical engineering and design methodologies pertaining to aircraft and space vehicles. Original unpublished manuscripts are solicited on all areas of aerospace engineering including but not limited to: -Mechanics of materials and structures- Aerodynamics and fluid mechanics- Dynamics and control- Aeroacoustics- Aeroelasticity- Propulsion and combustion- Avionics and systems- Flight simulation and mechanics- Unmanned air vehicles (UAVs). Review articles on any of the above topics are also welcome.