Design of a net-zero charge neural stimulator with feedback control

2014 IEEE Biomedical Circuits and Systems Conference (BioCAS) Proceedings Pub Date : 2014-12-11 DOI:10.1109/BioCAS.2014.6981770

Xilin Liu, Milin Zhang, Hanfei Sun, A. Richardson, T. Lucas, J. Spiegel

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引用次数: 11

Abstract

This paper presents a high efficiency, net-zero charge neural stimulator. A new stimulation strategy is proposed to reduce the charge error that originates from the irreversible charge diffusion, which is a common issue in traditional current matching stimulator designs. In addition, an arbitrary channel configuration of the working and counter electrodes is achieved. Two methodologies are applied to the proposed design to increase the stimulation efficiency: i) feedback control of an adaptive driving voltage, which enables a constant low operating voltage for the entire active circuits; ii) charge recycling, which “recycles” the accumulated charges on the blocking capacitor. An improved current mode DAC and a digital feed-forward error compensation comparator are integrated in the output stage to suppress the process variation, and minimize the charge error in continuous stimulation pulse trains. Performance characterization and invivo experimental result of a prototype chip fabricated in standard 180nm CMOS technology are presented. An efficiency improvement of 51% is measured in the experiment.

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带反馈控制的净零电荷神经刺激器的设计

提出了一种高效、净零电荷的神经刺激器。针对传统电流匹配刺激器设计中普遍存在的电荷不可逆扩散引起的电荷误差问题，提出了一种新的刺激策略。此外，还实现了工作电极和反电极的任意通道配置。两种方法应用于提出的设计以提高激励效率:i)自适应驱动电压的反馈控制，使整个有源电路保持恒定的低工作电压;Ii)电荷回收，即“回收”阻塞电容器上积累的电荷。在输出级集成了改进的电流模式DAC和数字前馈误差补偿比较器，以抑制过程变化，最大限度地降低连续刺激脉冲序列中的电荷误差。介绍了采用标准180nm CMOS工艺制作的原型芯片的性能表征和体内实验结果。在实验中，效率提高了51%。

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2014 IEEE Biomedical Circuits and Systems Conference (BioCAS) Proceedings

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