E. Mangieri, A. Ahmadi, K. Maharatna, S. Ahmad, P. Chappell
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引用次数: 7
摘要
本文提出了一种用于假肢控制的小型模拟电路。电路直接捕获表面肌电信号作为输入,用户将能够选择不同的姿势。所提出的电路能够仅使用针对不同截肢程度患者的一个肌电图源工作。它还可以适应不同的用户,具有不同的肌电信号振幅信号,即使是单个肌电信号,也可以在电路中改变每个手指的运动。将实际捕获的肌电信号应用于设计,仿真结果验证了该电路对肌电信号的处理能力和对假手的有效控制。该电路采用0.12 μ m CMOS技术设计和实现,一组采样姿势功耗为4 mW。
A novel analogue circuit for controlling prosthetic hands
This paper presents a compact analogue circuit for the controlling of prosthetic hands. The circuit captures directly surface EMG signals as the input by which the user will be able to select different postures. The proposed circuit is able to work using only one EMG source targeting patients with different levels of amputation. It is also adaptable for different users with different EMG amplitude signals and the motion of each finger can be varied in the circuit even with the single EMG. Real captured EMG signals are applied to the design and simulation results demonstrate the capability of the circuit in processing EMG signals and controlling the prosthetic hand in an efficient way. The circuit is designed and implemented with 0.12 mum CMOS technology and consumes 4 mW power for a set of sample postures.
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