An Adaptive 3D Artificial Potential Field for Fail-safe UAV Navigation

2022 30th Mediterranean Conference on Control and Automation (MED) Pub Date : 2022-06-28 DOI:10.1109/MED54222.2022.9837223

B. Lindqvist, Jakub Haluška, C. Kanellakis, G. Nikolakopoulos

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引用次数: 6

Abstract

This article presents an obstacle avoidance framework for unmanned aerial vehicles (UAVs), with a focus on providing safe and stable local navigation in critical scenarios. The framework is based on enhanced artificial potential field (APF) concepts, and is paired with a nonlinear model predictive controller (NMPC) for complete local reactive navigation. This paper will consider a series of additions to the classical artificial potential field that addresses UAV-specific challenges, allows for smooth navigation in tightly constrained environments, and ensures safe human-robot interactions. The APF formulation is fundamentally based on using raw LiDAR pointcloud data as input to decouple the safe robot navigation problem from the reliance on any map or obstacle detection software, resulting in a very resilient and fail-safe framework that can be used as an additional safety layer for any 3D-LiDAR equipped UAV in any environment or mission scenario. We evaluate the scheme in both laboratory experiments and field trials, and also place a large emphasis on realistic scenarios for safe human-robot interactions.

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无人机故障安全导航的自适应三维人工势场

本文提出了一种无人机避障框架，重点研究了在关键场景下提供安全稳定的局部导航。该框架基于增强型人工势场(APF)概念，并与非线性模型预测控制器(NMPC)配对，用于完全的局部无功导航。本文将考虑对经典人工势场的一系列补充，以解决无人机特有的挑战，允许在严格受限的环境中顺利导航，并确保安全的人机交互。APF配方基本上是基于使用原始激光雷达点云数据作为输入，将安全机器人导航问题从对任何地图或障碍物检测软件的依赖中分离出来，从而形成一个非常有弹性和故障安全的框架，可作为任何3D-LiDAR装备的无人机在任何环境或任务场景中的额外安全层。我们在实验室实验和现场试验中评估了该方案，并强调了安全人机交互的现实场景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 30th Mediterranean Conference on Control and Automation (MED)

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