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迈向基于多层神经网络的无模型工具动态识别与校准

Towards Model-Free Tool Dynamic Identification and Calibration Using Multi-Layer Neural Network.

作者信息

Su Hang, Qi Wen, Hu Yingbai, Sandoval Juan, Zhang Longbin, Schmirander Yunus, Chen Guang, Aliverti Andrea, Knoll Alois, Ferrigno Giancarlo, De Momi Elena

机构信息

Dipartimento di Elettronica, Informazione e Bioingegneria, Politecnico di Milano, 20133 Milano, Italy.

Department of Informatics, Technical University of Munich, 85748 Munich, Germany.

出版信息

Sensors (Basel). 2019 Aug 21;19(17):3636. doi: 10.3390/s19173636.

DOI:10.3390/s19173636
PMID:31438529
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6749275/
Abstract

In robot control with physical interaction, like robot-assisted surgery and bilateral teleoperation, the availability of reliable interaction force information has proved to be capable of increasing the control precision and of dealing with the surrounding complex environments. Usually, force sensors are mounted between the end effector of the robot manipulator and the tool for measuring the interaction forces on the tooltip. In this case, the force acquired from the force sensor includes not only the interaction force but also the gravity force of the tool. Hence the tool dynamic identification is required for accurate dynamic simulation and model-based control. Although model-based techniques have already been widely used in traditional robotic arms control, their accuracy is limited due to the lack of specific dynamic models. This work proposes a model-free technique for dynamic identification using multi-layer neural networks (MNN). It utilizes two types of MNN architectures based on both feed-forward networks (FF-MNN) and cascade-forward networks (CF-MNN) to model the tool dynamics. Compared with the model-based technique, i.e., curve fitting (CF), the accuracy of the tool identification is improved. After the identification and calibration, a further demonstration of bilateral teleoperation is presented using a serial robot (LWR4+, KUKA, Germany) and a haptic manipulator (SIGMA 7, Force Dimension, Switzerland). Results demonstrate the promising performance of the model-free tool identification technique using MNN, improving the results provided by model-based methods.

摘要

在具有物理交互的机器人控制中,如机器人辅助手术和双边遥操作,可靠的交互力信息的可用性已被证明能够提高控制精度并应对周围复杂环境。通常,力传感器安装在机器人操纵器的末端执行器和用于测量工具尖端上的交互力的工具之间。在这种情况下,从力传感器获取的力不仅包括交互力,还包括工具的重力。因此,为了进行精确的动态仿真和基于模型的控制,需要进行工具动态识别。尽管基于模型的技术已经在传统机器人手臂控制中广泛使用,但由于缺乏特定的动态模型,其精度有限。这项工作提出了一种使用多层神经网络(MNN)进行动态识别的无模型技术。它利用基于前馈网络(FF-MNN)和级联前馈网络(CF-MNN)的两种类型的MNN架构来对工具动态进行建模。与基于模型的技术(即曲线拟合(CF))相比,工具识别的精度得到了提高。在识别和校准之后,使用串联机器人(LWR4 +,库卡,德国)和触觉操纵器(SIGMA 7,力维度,瑞士)进行了双边遥操作的进一步演示。结果证明了使用MNN的无模型工具识别技术具有良好的性能,改进了基于模型的方法所提供的结果。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/81f7/6749275/e5fe66c0a49c/sensors-19-03636-g014.jpg
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