基于计算机视觉的手腕假体半自主控制策略

IF 2.9 Q2 ROBOTICS

Robotics Pub Date : 2023-11-13 DOI:10.3390/robotics12060152

Gianmarco Cirelli, Christian Tamantini, Luigi Pietro Cordella, Francesca Cordella

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引用次数: 0

摘要

减轻截肢者在假肢装置的高水平控制方面的负担是一个开放的研究挑战。基于肌电图的意图检测由于运动伪影、疲劳和稳定性而存在一些局限性。外部感知的整合可以为克服这些限制提供有价值的解决方案。本文提出了一种基于计算机视觉系统(CVS)的腕手假肢半自主控制系统(SCS)。SCS集成了目标检测、抓取选择和手腕方向估计算法。通过将CVS与基于模拟肌电图的意图检测模块相结合，SCS保证了可靠的假肢控制。结果表明，在快速的帧分析频率(2.07 FPS)下，抓取和目标分类准确率较高(≥97%)。SCS的平均角度估计误差≤18°，稳定性≤0.8°。手术测试证明了所提出的方法处理复杂现实场景的能力，并为未来在真实假体装置上的实施铺平了道路。

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 Semiautonomous Control Strategy Based on Computer Vision for a Hand–Wrist Prosthesis

Alleviating the burden on amputees in terms of high-level control of their prosthetic devices is an open research challenge. EMG-based intention detection presents some limitations due to movement artifacts, fatigue, and stability. The integration of exteroceptive sensing can provide a valuable solution to overcome such limitations. In this paper, a novel semiautonomous control system (SCS) for wrist–hand prostheses using a computer vision system (CVS) is proposed and validated. The SCS integrates object detection, grasp selection, and wrist orientation estimation algorithms. By combining CVS with a simulated EMG-based intention detection module, the SCS guarantees reliable prosthesis control. Results show high accuracy in grasping and object classification (≥97%) at a fast frame analysis frequency (2.07 FPS). The SCS achieves an average angular estimation error ≤18° and stability ≤0.8° for the proposed application. Operative tests demonstrate the capabilities of the proposed approach to handle complex real-world scenarios and pave the way for future implementation on a real prosthetic device.

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来源期刊

Robotics Mathematics-Control and Optimization

CiteScore

6.70

自引率

8.10%

发文量

114

审稿时长

11 weeks

期刊介绍： Robotics publishes original papers, technical reports, case studies, review papers and tutorials in all the aspects of robotics. Special Issues devoted to important topics in advanced robotics will be published from time to time. It particularly welcomes those emerging methodologies and techniques which bridge theoretical studies and applications and have significant potential for real-world applications. It provides a forum for information exchange between professionals, academicians and engineers who are working in the area of robotics, helping them to disseminate research findings and to learn from each other’s work. Suitable topics include, but are not limited to: -intelligent robotics, mechatronics, and biomimetics -novel and biologically-inspired robotics -modelling, identification and control of robotic systems -biomedical, rehabilitation and surgical robotics -exoskeletons, prosthetics and artificial organs -AI, neural networks and fuzzy logic in robotics -multimodality human-machine interaction -wireless sensor networks for robot navigation -multi-sensor data fusion and SLAM