An autonomous Unmanned Aerial Vehicle exploration platform with a hierarchical control method for post-disaster infrastructures

IF 1.5 Q3 AUTOMATION & CONTROL SYSTEMS IET Cybersystems and Robotics Pub Date : 2024-01-24 DOI:10.1049/csy2.12107
Xin Peng, Gaofeng Su, Raja Sengupta
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Abstract

Catastrophic natural disasters like earthquakes can cause infrastructure damage. Emergency response agencies need to assess damage precisely while repeating this process for infrastructures with different shapes and types. The authors aim for an autonomous Unmanned Aerial Vehicle (UAV) platform equipped with a 3D LiDAR sensor to comprehensively and accurately scan the infrastructure and map it with a predefined resolution r. During the inspection, the UAV needs to decide on the Next Best View (NBV) position to maximize the gathered information while avoiding collision at high speed. The authors propose solving this problem by implementing a hierarchical closed-loop control system consisting of a global planner and a local planner. The global NBV planner decides the general UAV direction based on a history of measurements from the LiDAR sensor, and the local planner considers the UAV dynamics and enables the UAV to fly at high speed with the latest LiDAR measurements. The proposed system is validated through the Regional Scale Autonomous Swarm Damage Assessment simulator, which is built by the authors. Through extensive testing in three unique and highly constrained infrastructure environments, the autonomous UAV inspection system successfully explored and mapped the infrastructures, demonstrating its versatility and applicability across various shapes of infrastructure.

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采用分层控制方法的灾后基础设施无人飞行器自主探索平台
地震等灾难性自然灾害会对基础设施造成破坏。应急机构需要精确评估损坏情况,同时针对不同形状和类型的基础设施重复这一过程。在检查过程中,无人机需要决定下一个最佳视角(NBV)位置,以最大限度地收集信息,同时避免高速碰撞。作者建议通过实施由全局规划器和局部规划器组成的分层闭环控制系统来解决这一问题。全局 NBV 规划器根据激光雷达传感器的历史测量结果决定无人飞行器的总体方向,而局部规划器则考虑无人飞行器的动态,使无人飞行器能够根据最新的激光雷达测量结果高速飞行。作者制作的区域规模自主蜂群损害评估模拟器对所提出的系统进行了验证。通过在三个独特且高度受限的基础设施环境中进行广泛测试,自主无人机检测系统成功探索并绘制了基础设施地图,证明了其在各种形状的基础设施中的多功能性和适用性。
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来源期刊
IET Cybersystems and Robotics
IET Cybersystems and Robotics Computer Science-Information Systems
CiteScore
3.70
自引率
0.00%
发文量
31
审稿时长
34 weeks
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