A 0.48$^{\circ}$ Phase Error 91.1 dB SNR Bioimpedance Measurement IC for Monitoring Cardiopulmonary Diseases

IF 4.9

IEEE transactions on biomedical circuits and systems Pub Date : 2025-03-21 DOI:10.1109/TBCAS.2025.3572374

Jiarun Yuan;Yanxing Suo;Qiao Cai;Hui Wang;Yongfu Li;Yong Lian;Yang Zhao

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Abstract

This article presents a low-power and low phase error bioimpedance (BioZ) measurement IC designed for monitoring cardiopulmonary diseases. To compensate for the phase shift introduced along the signal path by current generator (CG), electrodes and sensor analog front-end (AFE), a novel phase shift calibration logic is proposed. Utilizing this calibration logic, a single-channel in-phase demodulation-based impedance measurement scheme is developed. A noise shaping pseudo-sine wave CG with data-weighted averaging (DWA) is used to minimize modulation harmonics. Fabricated in a 0.18µm CMOS process, the chip occupies 0.73 mm2 and consumes between 52.7 to 97.5 µA current from a 1.8V supply. The CG achieves 74.1 dB SFDR and −70dB THD at 15.5 kHz with a 50µApk stimulation current. The chip achieves 2mΩ/√Hz input-referred impedance noise at 1Hz, 91.1 dB SNR (BW = 4 Hz), 36 kΩ input range and less than 0.48$^{\circ}$ phase error (0 − 90$^{\circ}$, 1 – 20 kHz). On-body BioZ experiments using a 4-electrode configuration demonstrate clear recordings of Impedance Cardiography (ICG) and respiration signals.

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用于心肺疾病监测的0.48°相位误差91.1dB信噪比生物阻抗测量芯片。

本文介绍了一种用于监测心肺疾病的低功耗、低相位误差生物阻抗（BioZ）测量集成电路。为了补偿电流发生器（CG）、电极和传感器模拟前端（AFE）在信号路径上引入的相移，提出了一种新的相移校准逻辑。利用这种校准逻辑，开发了一种基于单相解调的阻抗测量方案。采用数据加权平均（DWA）的噪声整形伪正弦波CG来最小化调制谐波。该芯片采用0.18μm CMOS工艺制造，占地0.73mm2，从1.8V电源消耗52.7至97.5μA电流。在15.5kHz时，CG在50μApk的激励电流下实现了74.1dB的SFDR和-70dB的THD。该芯片实现了$2 \text{m} \Omega / \sqrt{} Hz$输入参考阻抗噪声为1Hz，信噪比为91.1dB (BW=4Hz), $36 \text{k} \Omega$输入范围和小于0.48°相位误差（0-90°，1-20kHz）。使用4电极配置的人体BioZ实验显示阻抗心电图（ICG）和呼吸信号的清晰记录。

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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IEEE transactions on biomedical circuits and systems

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