Low-Gm CMOS Transconductors with Wide Tuning Range for Bioimpedance Spectroscopy

2023 19th International Conference on Synthesis, Modeling, Analysis and Simulation Methods and Applications to Circuit Design (SMACD) Pub Date : 2023-07-03 DOI:10.1109/SMACD58065.2023.10192142

Israel Corbacho, J. M. Carrillo, J. L. Ausín, M. A. Domínguez, R. Pérez-Aloe, J. F. Duque-Carrillo

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Abstract

Two techniques to design a low-transconductance (Gm) widely-tunable transconductor are described. The operation principle consists in both cases in the subtraction of two nominally equal transconductances, one of which can be electronically tuned. The circuit implementation differs, being one solution based on the use of source followers (SF), a linearization resistor, and a tunable current mirror, and consisting the other approach of differential pairs (DP) with resistive source degeneration, and an electronically programmable current biasing. Both transconductors have been designed in 180 nm CMOS technology to operate with 1.8 V. The SF and DP solutions achieve a minimum Gm nominal value of 1.38 nA/V and 6.03 nA/V, respectively, with a simulated transconductance tuning range of 729.6× and 7129.4×, also respectively, obtained from a Montecarlo analysis. The application of the transconductors to the design of a second-order Gm − C bandpass filter for signals separation in multi-sine bioimpedance spectroscopy is also addressed.

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生物阻抗光谱宽调谐范围的低gm CMOS传感器

介绍了两种设计低跨导宽可调谐晶体管的技术。在这两种情况下，工作原理都是减去两个名义上相等的跨导，其中一个可以通过电子调谐。电路实现有所不同，一种解决方案是基于使用源跟随器(SF)、线性化电阻和可调谐电流镜，另一种方法是差分对(DP)，具有电阻源退化和电子可编程电流偏置。这两种晶体管都采用180nm CMOS技术设计，工作电压为1.8 V。SF和DP方案的最小Gm标称值分别为1.38 nA/V和6.03 nA/V，模拟跨导调谐范围分别为729.6 x和7129.4 x，由蒙特卡罗分析得出。在多正弦生物阻抗谱信号分离的二阶Gm−C带通滤波器的设计中，transconductor的应用也被解决。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2023 19th International Conference on Synthesis, Modeling, Analysis and Simulation Methods and Applications to Circuit Design (SMACD)

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