脑电信号传感检测芯片系统综述*

doi:10.16257/j.cnki.1681-1070.2022.0512

摘要/Abstract

摘要： 低电压低频微弱脑电（Electroencephalogram, EEG）信号检测微芯片对于构建可穿戴或可佩戴的EEG检测微设备或系统非常重要。EEG传感检测微芯片可以应用于医学、神经科学以及脑机接口（Brain-Computer Interface, BCI）技术的研究。EEG传感器可以准确、灵敏、安全、可靠地实现微弱低频颅外EEG电压的感知，将感知的信号反馈到传感后调理电路；有效的传感后调理芯片系统可以对前端传感器感知的微弱小信号进行放大、带外信号滤除、噪声抑制或消除等。通过生物模数转化器把放大的模拟EEG电压转换为数字信号，对信号打包并无线发射到远处终端，EEG信号的可靠感知直接影响到EEG接收终端后续EEG算法的有效开展。由于便携可穿戴微型医疗设备或系统的迫切需要，EEG信号传感器与传感后调理芯片的设计变得越来越重要。综述了EEG信号检测微传感器芯片系统国内外的研究进展，主要是通过传感器即EEG电极的信号感知和传感后的EEG信号调理芯片，并对EEG传感器芯片发展进行了总结与展望。

关键词: 脑电, 传感器, 脑电调理芯片

Abstract: Microchips applied for sensing low-voltage and low-frequency micro electroencephalogram (EEG) signals are very important for constructing wearable and portable EEG micro-devices and micro-systems. The EEG sensing microchips are very critical for medicine, neuroscience, brain-computer interface (BCI) and other scientific researches. The EEG sensors could detect the weak and low-frequency extra cranial scalp EEG signals sensitively, accurately, safely, reliably and conveniently. Then, the sensed weak EEG signals are fed into the post-sensor conditioning circuits. Effective post-sensor conditioning chips can amplify the sensed weak EEG signals received from the pre-sensors, eliminate out-of-band irrelevant signals, reduce different noises. Relied on the biological-ADC, the amplified EEG signals are converted into digital signals. EEG signals are packed and wireless transmitted to remote terminals. And, EEG sensing reliability will affect effective developments of EEG algorithms at remote receiving terminals directly. As the urgent requirements of portable or wearable micro-devices and micro-systems, the developments of EEG sensors and post-sensor conditioning microchips become very critical. The researches of EEG micro sensors and post-sensor conditioning microchips at home and abroad are reviewed, EEG signals perception through the designed EEG sensors, which are also namely EEG electrodes; and the post-sensor conditioning microchips. The exploitation of EEG sensors and microchips and look ahead for the future is summarized.

Key words: electroencephalogram, sensor, electroencephalogramconditioningchip

中图分类号:

TN402
R318.6

王梓斌, 刘国柱, 孙建辉. 脑电信号传感检测芯片系统综述^*[J]. 电子与封装, 2022, 22(5): 050302 .

WANG Zibin, LIU Guozhu, SUN Jianhui. ElectroencephalogramSignal Sensing Chip System Review[J]. Electronics & Packaging, 2022, 22(5): 050302 .

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中国半导体行业协会封装分会会刊

中国电子学会电子制造与封装技术分会会刊

脑电信号传感检测芯片系统综述^*

ElectroencephalogramSignal Sensing Chip System Review

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