Aerial service robots for visual inspection of thermal power plant boiler systems

2012 2nd International Conference on Applied Robotics for the Power Industry (CARPI) Pub Date : 2012-09-01 DOI:10.1109/CARPI.2012.6473374

M. Burri, J. Nikolic, C. Hurzeler, G. Caprari, R. Siegwart

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引用次数: 94

Abstract

This work focuses on the use of MAVs for industrial inspection tasks. An efficient flight controller based on a model predictive control paradigm is developed. It allows for agile maneuvers in confined spaces while incorporating delays, saturations and inaccurate vehicle state estimates only available at low rate. The fast gradient method is used to solve the optimization problem and meet real-time constraints, given limited computational resources. The vehicle state is estimated from an on-board forward-looking camera system, tightly fused with inertial measurements. Experiments using a realistic industrial mock environment demonstrate the effectiveness, robustness and limitations of the proposed approach. The results show that egomotion estimation is robust under rapid motion, in poorly textured environments and under challenging lighting conditions. When coupled with the model predictive controller, the system requires only limited computational resources and sufficiently tracks an arbitrary trajectory.

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火力发电厂锅炉系统目视检查用空中服务机器人

这项工作的重点是在工业检测任务中使用MAVs。提出了一种基于模型预测控制范式的高效飞行控制器。它允许灵活机动在有限的空间，同时结合延迟，饱和和不准确的车辆状态估计只有在低速率可用。在计算资源有限的情况下，采用快速梯度法求解优化问题，满足实时约束。车辆状态由车载前视摄像系统估算，该系统与惯性测量紧密结合。在真实工业模拟环境下进行的实验证明了该方法的有效性、鲁棒性和局限性。结果表明，在快速运动、纹理较差的环境和具有挑战性的光照条件下，自我运动估计具有鲁棒性。当与模型预测控制器相结合时，系统只需要有限的计算资源，就能充分跟踪任意轨迹。

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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来源期刊

2012 2nd International Conference on Applied Robotics for the Power Industry (CARPI)

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