A 17-bit 104-dB-DR High-Precision Low-Power CMOS Fluorescence Biosensor With Extended Counting ADC and Noise Cancellation

2018 16th IEEE International New Circuits and Systems Conference (NEWCAS) Pub Date : 2018-06-01 DOI:10.1109/NEWCAS.2018.8585682

M. N. Khiarak, K. Sasagawa, T. Tokuda, J. Ohta, S. Martel, Y. Koninck, B. Gosselin

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引用次数: 4

Abstract

This paper presents a high-dynamic range CMOS biosensor fusing a photosensing module with a high-precision extended counting analog-to-digital converter (ADC) with noise cancellation to detect florescence neural signal fluctuations of very low incident power. The 7 MSBs are resolved by a first order continuous-time resettable $\Sigma \triangle \mathrm {A}\mathrm {D}\mathrm {C}$, whereas the residue voltage is quantized by a 10-bit single slope ADC for enabling wide dynamic range and high precision fluorescence sensing. Low-frequency imperfections are canceled out by an embedded noise cancellation scheme which is subtracting the noise and the offset using switches and capacitors. The quantizer is shared between the $\Sigma \triangle $ and the single slope ADC to decrease the chip size and to improve energy-efficiency. The proposed optoelectronic biosensor is implemented in a $0.18-\mu \mathrm {m}$ CMOS technology, consuming $93 \mu \mathrm {W}$ from a 3.3-V supply voltage while achieving a DR of 104dB, and a minimum detectable current of $400-fA_{rms}$, for a conversion time of $506.5\mu s.$

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一种17位104 db - dr高精度低功耗CMOS荧光生物传感器，具有扩展计数ADC和降噪功能

本文介绍了一种高动态范围CMOS生物传感器，该传感器融合了光敏模块和高精度扩展计数模数转换器(ADC)，并具有消噪功能，可检测极低入射功率的荧光神经信号波动。7个msb由一阶连续时间可复位$\Sigma \triangle \mathrm {A}\mathrm {D}\mathrm {C}$解析，而剩余电压由10位单斜率ADC量化，以实现宽动态范围和高精度荧光传感。低频缺陷通过嵌入式噪声消除方案消除，该方案使用开关和电容器减去噪声和偏移量。量化器在$\Sigma \triangle $和单斜率ADC之间共享，以减小芯片尺寸并提高能效。所提出的光电生物传感器采用$0.18-\mu \mathrm {m}$ CMOS技术实现，在3.3 v电源电压下消耗$93 \mu \mathrm {W}$，同时实现104dB的DR，最小可检测电流$400-fA_{rms}$，转换时间为 $506.5\mu s.$

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2018 16th IEEE International New Circuits and Systems Conference (NEWCAS)

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