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一种用于细粉尘检测系统的具有双模式超低噪声跨阻放大器的77分贝动态范围模拟前端。

A 77-dB Dynamic-Range Analog Front-End for Fine-Dust Detection Systems with Dual-Mode Ultra-Low Noise TIA.

作者信息

Rad Reza E, Hejazi Arash, Asl Seyed-Ali H, Shehzad Khuram, Verma Deeksha, Kim SungJin, Rikan Behnam S, Pu YoungGun, Kim Joon Tae, Hwang Keum Cheol, Yang Youngoo, Lee Kang-Yoon

机构信息

Department of Electrical and Computer Engineering, Sungkyunkwan University, Suwon 16419, Korea.

SKAIChips Co., Ltd., Suwon 16419, Korea.

出版信息

Sensors (Basel). 2021 Sep 23;21(19):6360. doi: 10.3390/s21196360.

DOI:10.3390/s21196360
PMID:34640682
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8512889/
Abstract

This paper presents an analog front-end for fine-dust detection systems with a 77-dB-wide dynamic range and a dual-mode ultra-low noise TIA with 142-dBΩ towards the maximum gain. The required high sensitivity of the analog signal conditioning path dictates having a high sensitivity at the front-end while the Input-Referred Noise (IRN) is kept low. Therefore, a TIA with a high sensitivity to detected current bio-signals is provided by a photodiode module. The analog front end is formed by the TIA, a DC-Offset Cancellation (DCOC) circuit, a Single-to-Differential Amplifier (SDA), and two Programmable Gain Amplifiers (PGAs). Gain adjustment is implemented by a coarse-gain-step using selective loads with four different gain values and fine-gain steps by 42 dB dynamic range during 16 fine steps. The settling time of the TIA is compensated using a capacitive compensation which is applied for the last stage. An off-state circuitry is proposed to avoid any off-current leakage. This TIA is designed in a 0.18 µm standard CMOS technology. Post-layout simulations show a high gain operation with a 67 dB dynamic range, input-referred noise, less than 600 fA/√Hz in low frequencies, and less than 27 fA/√Hz at 20 kHz, a minimum detectable current signal of 4 pA, and a 2.71 mW power consumption. After measuring the full path of the analog signal conditioning path, the experimental results of the fabricated chip show a maximum gain of 142 dB for the TIA. The Single-to-Differential Amplifier delivers a differential waveform with a unity gain. The PGA1 and PGA2 show a maximum gain of 6.7 dB and 6.3 dB, respectively. The full-path analog front-end shows a wide dynamic range of up to 77 dB in the measurement results.

摘要

本文介绍了一种用于细粉尘检测系统的模拟前端,其具有77dB宽的动态范围以及一个在最大增益时具有142dBΩ的双模超低噪声跨阻放大器(TIA)。模拟信号调理路径所需的高灵敏度要求前端具有高灵敏度,同时保持低输入参考噪声(IRN)。因此,光电二极管模块提供了对检测到的电流生物信号具有高灵敏度的TIA。模拟前端由TIA、直流失调消除(DCOC)电路、单端转差分放大器(SDA)和两个可编程增益放大器(PGA)组成。增益调整通过使用具有四个不同增益值的选择性负载进行粗增益步长实现,并在16个精细步长期间通过42dB动态范围进行精细增益步长调整。TIA的建立时间通过应用于最后一级的电容补偿来补偿。提出了一种关断状态电路以避免任何关断电流泄漏。该TIA采用0.18μm标准CMOS技术设计。布局后仿真显示,其高增益操作具有67dB动态范围,低频输入参考噪声小于600fA/√Hz,20kHz时小于27fA/√Hz,最小可检测电流信号为4pA,功耗为2.71mW。在测量模拟信号调理路径的全路径后,所制造芯片的实验结果表明TIA的最大增益为142dB。单端转差分放大器提供单位增益的差分波形。PGA1和PGA2的最大增益分别为6.7dB和6.3dB。测量结果表明全路径模拟前端具有高达77dB的宽动态范围。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/726f/8512889/77dd38265591/sensors-21-06360-g017.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/726f/8512889/77dd38265591/sensors-21-06360-g017.jpg

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