An Energy-Efficient FD-fNIRS Readout Circuit Employing a Mixer-First Analog Frontend and a $\Sigma$-$\Delta$ Phase-to-Digital Converter

Zhouchen Ma;Cheng Chen;Yuxiang Lin;Liang Qi;Yongfu Li;Xia Bi;Mohamad Sawan;Guoxing Wang;Jian Zhao
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Abstract

This paper presents a low-power frequency-domain functional near-infrared spectroscopy (FD-fNIRS) readout circuit for the absolute value measurement of tissue optical characteristics. The paper proposes a mixer-first analog front-end (AFE) structure and a 1-bit $\Sigma$ - $\Delta$ phase-to-digital converter (PDC) to reduce the required circuit bandwidth and the laser modulation frequency, thereby saving power while maintaining high resolution. The proposed chip achieves sub-0.01 ${}^{\circ}$ phase resolution and consumes 6.8 mW of power. Nine optical solid phantoms are produced to evaluate the chip. Compared to a self-built high-precision measurement platform that combines a network analyzer with an avalanche photodiode (APD) module, the maximum measuring errors of the absorption coefficient and reduced scattering coefficient are 10.6% and 12.3%, respectively.
采用混频器先行模拟前端和 Σ-Δ 相位数字转换器的高能效 FD-fNIRS 读出电路。
本文提出了一种用于组织光学特性绝对值测量的低功耗频域功能性近红外光谱(FD-fNIRS)读出电路。本文提出了一种混频器优先的模拟前端(AFE)结构和 1 位 Σ-Δ 相位数字转换器(PDC),以降低所需的电路带宽和激光调制频率,从而在保持高分辨率的同时节省功耗。所提出的芯片实现了低于 0.01° 的相位分辨率,功耗仅为 6.8 mW。为评估该芯片,制作了九个光学实体模型。与结合了网络分析仪和雪崩光电二极管(APD)模块的自建高精度测量平台相比,吸收系数和还原散射系数的最大测量误差分别为 10.6% 和 12.3%。
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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