On Design and Implementation of Neural-Machine Interface for Artificial Legs

IF 11.7 1区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

IEEE Transactions on Industrial Informatics Pub Date : 2011-09-05 DOI:10.1109/TII.2011.2166770

Xiaorong Zhang;Yuhong Liu;Fan Zhang;Jin Ren;Yan Lindsay Sun;Qing Yang;He Huang

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引用次数: 57

Abstract

The quality-of-life of leg amputees can be improved dramatically by using a cyber-physical system (CPS) that controls artificial legs based on neural signals representing amputees' intended movements. The key to the CPS is the neural-machine interface (NMI) that senses electromyographic (EMG) signals to make control decisions. This paper presents a design and implementation of a novel NMI using an embedded computer system to collect neural signals from a physical system—a leg amputee, provide adequate computational capability to interpret such signals, and make decisions to identify user's intent for prostheses control in real time. A new deciphering algorithm, composed of an EMG pattern classifier and a postprocessing scheme, was developed to identify the user's intended lower limb movements. To deal with environmental uncertainty, a trust management mechanism was designed to handle unexpected sensor failures and signal disturbances. Integrating the neural deciphering algorithm with the trust management mechanism resulted in a highly accurate and reliable software system for neural control of artificial legs. The software was then embedded in a newly designed hardware platform based on an embedded microcontroller and a graphic processing unit (GPU) to form a complete NMI for real-time testing. Real-time experiments on a leg amputee subject and an able-bodied subject have been carried out to test the control accuracy of the new NMI. Our extensive experiments have shown promising results on both subjects, paving the way for clinical feasibility of neural controlled artificial legs.

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人工腿神经机接口的设计与实现

通过使用基于代表截肢者预期动作的神经信号控制假腿的网络物理系统（CPS），可以显著提高截肢者的生活质量。CPS的关键是神经机器接口（NMI），它可以感知肌电图（EMG）信号以做出控制决策。本文介绍了一种新型NMI的设计和实现，该NMI使用嵌入式计算机系统来收集来自物理系统（截肢者）的神经信号，提供足够的计算能力来解释这些信号，并做出决策来实时识别用户对假肢控制的意图。开发了一种新的破译算法，该算法由EMG模式分类器和后处理方案组成，用于识别用户想要的下肢运动。为了应对环境的不确定性，设计了一种信任管理机制来处理意外的传感器故障和信号干扰。将神经解密算法与信任管理机制相结合，形成了一个高度准确可靠的假腿神经控制软件系统。然后，该软件被嵌入到一个新设计的基于嵌入式微控制器和图形处理单元（GPU）的硬件平台中，以形成一个完整的NMI进行实时测试。在一名截肢者和一名身体健全的受试者身上进行了实时实验，以测试新型NMI的控制准确性。我们的大量实验在这两个受试者身上都显示出了有希望的结果，为神经控制假腿的临床可行性铺平了道路。

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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来源期刊

IEEE Transactions on Industrial Informatics 工程技术-工程：工业

CiteScore

24.10

自引率

8.90%

发文量

1202

审稿时长

5.1 months

期刊介绍： The IEEE Transactions on Industrial Informatics is a multidisciplinary journal dedicated to publishing technical papers that connect theory with practical applications of informatics in industrial settings. It focuses on the utilization of information in intelligent, distributed, and agile industrial automation and control systems. The scope includes topics such as knowledge-based and AI-enhanced automation, intelligent computer control systems, flexible and collaborative manufacturing, industrial informatics in software-defined vehicles and robotics, computer vision, industrial cyber-physical and industrial IoT systems, real-time and networked embedded systems, security in industrial processes, industrial communications, systems interoperability, and human-machine interaction.