全驱动飞行器视觉伺服与物理交互任务的通用控制体系

2021 Aerial Robotic Systems Physically Interacting with the Environment (AIRPHARO) Pub Date : 2021-10-01 DOI:10.1109/AIRPHARO52252.2021.9571053

Gianluca Corsini, Martin Jacquet, A. E. Jimenez-Cano, Amr Afifi, D. Sidobre, A. Franchi

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引用次数: 2

摘要

在本文中，我们提出了一种通用控制架构，允许全驱动的空中机器人自主完成需要与外部环境进行感知和物理交互的任务。我们整合了新颖的飞行末端执行器范式和混合视觉移动(HVS)方案，设计了全驱动空中机器人的通用控制体系结构。由于提出的解决方案，完全驱动的空中机器人可以自主完成需要感知和物理交互的任务，而无需求助于任何外力/扭矩传感器。完整地描述了控制体系结构，具有扳手观测器和导纳滤波器，并随后在实际实验中进行了验证。所建议的控制体系结构的代码是开源的。

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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A General Control Architecture for Visual Servoing and Physical Interaction Tasks for Fully-actuated Aerial Vehicles

In this paper, we present a general control architecture that allows fully-actuated aerial robots to autonomously accomplish tasks that require both perception and physical interaction with the external environment. We integrate the novel Flying End-Effector paradigm and a Hybrid Visual Ser-voing (HVS) scheme to design a general control architecture for fully-actuated aerial robots. Thanks to the proposed solution, a fully-actuated aerial robot can autonomously accomplish tasks that require both perception and physical interaction without resorting to any external force/torque sensor. The control architecture is entirely described, features a wrench observer and an admittance filter, and is subsequently validated on real experiments. The code for the proposed control architecture is provided open-source.

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2021 Aerial Robotic Systems Physically Interacting with the Environment (AIRPHARO)

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