Wireless sEMG/footswitch driven FPGA embedded digital processor for dynamic MFCV estimation

2018 13th International Conference on Design & Technology of Integrated Systems In Nanoscale Era (DTIS) Pub Date : 2018-04-09 DOI:10.1109/DTIS.2018.8368575

G. Mezzina, D. Venuto

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Abstract

This paper proposes the design and the implementation of an FPGA-based Cyber-physical system for the real-time monitoring of the Muscle Fiber Conduction Velocity (MFCV). The MFCV is evaluated during the walking by using of 4 wireless surface EMG electrodes, and 2 footswitches. The implemented algorithm, for the MFCV assessment, is based on the extraction of the degree of resemblance between 2 EMG signals from the same leg. The processor architecture has been fully implemented on FPGA. The system data transmission is entrusted to a Bluetooth module, which connects the FPGA to an external device. The complete system occupies 12% ALMs, 5903 ALUTs, 5% registers, 3.28% block memory, provide of the Altera Cyclone V. The computation time is respectively 125ns for the footswitch and 316ms for the EMG data, while 63.5±0.25ms are spent for the processing and MFCV evaluation. The technique has been validated on 6 subjects and the measurement results are here reported. The in-vivo measures agree with the clinical results, providing an MFCV=7.6m/s±0.36m/s, i.e., <0.1m/s w.r.t. typical value, for healthy subjects in the same operating conditions.

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用于动态MFCV估计的无线sEMG/脚踏开关驱动FPGA嵌入式数字处理器

本文提出了一种基于fpga的肌肉纤维传导速度实时监测系统的设计与实现。通过使用4个无线表面肌电电极和2个足部开关来评估行走过程中的MFCV。所实现的MFCV评估算法是基于提取来自同一条腿的2个肌电信号之间的相似度。该处理器架构已在FPGA上完全实现。系统数据传输由蓝牙模块完成，蓝牙模块将FPGA与外部设备连接。整个系统占用Altera Cyclone v提供的12% alm, 5903 alu, 5%寄存器，3.28%块内存，脚开关计算时间为125ns，肌电数据计算时间为316ms，处理和MFCV评估时间为63.5±0.25ms。该技术已在6名受试者上进行了验证，并报告了测量结果。体内测量结果与临床结果一致，在相同操作条件下，健康受试者的MFCV=7.6m/s±0.36m/s，即<0.1m/s w.r.t.典型值。

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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2018 13th International Conference on Design & Technology of Integrated Systems In Nanoscale Era (DTIS)

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