可穿戴 EEG 采集的有源电极：综述与电子设计方法。

Active Electrodes for Wearable EEG Acquisition: Review and Electronics Design Methodology.

出版信息

IEEE Rev Biomed Eng. 2017;10:187-198. doi: 10.1109/RBME.2017.2656388. Epub 2017 Jan 20.

DOI:10.1109/RBME.2017.2656388

Abstract

Active electrodes (AEs), i.e., electrodes with built-in readout circuitry, are increasingly being implemented in wearable healthcare and lifestyle applications due to AEs' robustness to environmental interference. An AE locally amplifies and buffers μV-level EEG signals before driving any cabling. The low output impedance of an AE mitigates cable motion artifacts, thus enabling the use of high-impedance dry electrodes for greater user comfort. However, developing a wearable EEG system, with medical grade signal quality on noise, electrode offset tolerance, common-mode rejection ratio, input impedance, and power dissipation, remains a challenging task. This paper reviews state-of-the-art bio-amplifier architectures and low-power analog circuits design techniques intended for wearable EEG acquisition, with a special focus on an AE system interfaced with dry electrodes.

摘要

有源电极（AEs），即内置读出电路的电极，由于其对环境干扰的鲁棒性，越来越多地被应用于可穿戴式医疗保健和生活方式应用中。有源电极在驱动任何电缆之前，会对微伏级别的 EEG 信号进行局部放大和缓冲。有源电极的低输出阻抗可以减轻电缆运动伪影，从而可以使用高阻抗干电极，为用户提供更大的舒适度。然而，开发具有医疗级信号质量（噪声、电极偏移容限、共模抑制比、输入阻抗和功耗）的可穿戴式 EEG 系统仍然是一项具有挑战性的任务。本文综述了用于可穿戴式 EEG 采集的最新生物放大器架构和低功耗模拟电路设计技术，特别关注与干电极接口的有源电极系统。

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可穿戴 EEG 采集的有源电极：综述与电子设计方法。

Active Electrodes for Wearable EEG Acquisition: Review and Electronics Design Methodology.

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