An Event-triggered Visual Servoing Predictive Control Strategy for the Surveillance of Contour-based Areas using Multirotor Aerial Vehicles

2022 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) Pub Date : 2022-10-23 DOI:10.1109/IROS47612.2022.9981176

Sotirios N. Aspragkathos, Mario Sinani, G. Karras, Fotis Panetsos, K. Kyriakopoulos

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Abstract

In this paper, an Event-triggered Image-based Visual Servoing Nonlinear Model Predictive Controller (ET-IBVS-NMPC) for multirotor aerial vehicles is presented. The proposed scheme is developed for the autonomous surveillance of contour-based areas with different characteristics (e.g. forest paths, coastlines, road pavements). For this purpose, an appropriately trained Deep Neural Network (DNN) is employed for the accurate detection of the contours. In an effort to reduce the remarkably large computational cost required by an IBVS-NMPC algorithm, a triggering condition is designed to define when the Optimal Control Problem (OCP) should be resolved and new control inputs will be calculated. Between two successive triggering instants, the control input trajectory is applied to the robot in an open-loop fashion, which means that no control input computations are required. As a result, the system's computing effort and energy consumption are lowered, while its autonomy and flight duration are increased. The visibility and input constraints, as well as the external disturbances, are all taken into account throughout the control design. The efficacy of the proposed strategy is demonstrated through a series of real-time experiments using a quadrotor and an octorotor both equipped with a monocular downward looking camera.

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多旋翼飞行器基于等高线区域监视的事件触发视觉伺服预测控制策略

提出了一种基于事件触发图像的多旋翼飞行器视觉伺服非线性模型预测控制器(ET-IBVS-NMPC)。提出的方案是为具有不同特征的等高线区域(例如森林路径，海岸线，道路人行道)的自主监视而开发的。为此，使用经过适当训练的深度神经网络(DNN)来精确检测轮廓。为了减少IBVS-NMPC算法巨大的计算成本，设计了一个触发条件来定义何时解决最优控制问题(OCP)并计算新的控制输入。在两个连续触发瞬间之间，控制输入轨迹以开环方式应用于机器人，这意味着不需要控制输入计算。从而降低了系统的计算量和能耗，同时提高了系统的自主性和飞行时间。可见性和输入约束以及外部干扰在整个控制设计中都被考虑在内。通过一系列的实时实验证明了该策略的有效性，该实验采用了四旋翼和八旋翼，它们都配备了单目向下看的相机。

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 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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