采用通用跟踪电源轨的16通道高cmrr神经记录放大器

2018 IEEE International Symposium on Radio-Frequency Integration Technology (RFIT) Pub Date : 2018-08-01 DOI:10.1109/RFIT.2018.8524035

Doojin Jang, Taeju Lee, Hyuntak Jeon, Seoktae Koh, Jaesuk Choi, Junghyup Lee, M. Je

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引用次数: 0

摘要

提出了一种能在大共模信号干扰环境下工作的神经记录放大器。所提出的方案采用两种类型的ldo，它们产生隔离的电源电压和一个缓冲器来感知共模信号。由于隔离电源轨，低噪声放大器(LNA)的固有共模抑制比(ICMRR)和共模输入阻抗都有所增加，即使在共用参考电极的16通道记录下，总共模抑制比(TCMRR)也在89.2 dB以上，最高可达1khz。与传统方法相比，即使电极组织阻抗(ETI)失配28%，LNA输入电容失配1%，TCMRR也提高了48.7 dB。

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16-Channel High-CMRR Neural-Recording Amplifiers Using Common-Made-Tracking Power Supply Rails

This paper presents a neural recording amplifier that operates in environments where large common-mode signals interfere. The proposed scheme employs two types of LDOs that generate isolated supply voltages and a buffer to sense a common-mode signal. Thanks to the isolated supply rails, both the intrinsic common-mode rejection ratio (ICMRR) and common-mode input impedance of the low-noise amplifier (LNA) are increased, which leads to the total common-mode rejection ratio (TCMRR) above 89.2 dB up to 1 kHz even in 16-channel recording with a shared reference electrode. Compared to the conventional method, the TCMRR is improved by 48.7 dB even for 28% mismatch of the electrode-tissue impedance (ETI) and 1% mismatch of the LNA input capacitances.

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2018 IEEE International Symposium on Radio-Frequency Integration Technology (RFIT)

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