A 0.8-μW and 74-dB High-Pass Sigma-Delta Modulator with OPAMP Sharing and Noise-Coupling Techniques for Biomedical Signal Acquisition

Shuenn Yuh Lee; Hao Yun Lee; Chia Ho Kung; Po Han Su; Ju Yi Chen

doi:10.1109/TBCAS.2022.3201328

A 0.8-μW and 74-dB High-Pass Sigma-Delta Modulator with OPAMP Sharing and Noise-Coupling Techniques for Biomedical Signal Acquisition

Shuenn Yuh Lee, Hao Yun Lee, Chia Ho Kung, Po Han Su, Ju Yi Chen

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

This work presents a third-order high-pass sigma-delta modulator (HPSDM) for biomedical signal acquisition. The operational amplifier (op-Amp) sharing and noise-coupling techniques are adopted to reduce the required quantity of op-Amps and add a noise-shaping order, which can achieve low power consumption and high resolution. A novel switched-capacitor architecture is proposed to suppress the increasing in-band noise and alleviate the circuit sensitivity to capacitor mismatch in the high-pass integrator. The proposed HPSDM was fabricated in a 0.18-μm standard CMOS process. Measurement results reveal that the proposed HPSDM has a signal-To-noise and distortion ratio (SNDR) of 75.26/74 dB in 200 Hz bandwidth and consumes 1.52/0.8 μW under 1.2/1 V supply voltage, which can achieve a peak Schreier Figure-of-Merit of 156.45/157.98 dB and a peak Walden FoM of 0.802/0.488 pJ/conv.

Original language	English
Pages (from-to)	742-751
Number of pages	10
Journal	IEEE transactions on biomedical circuits and systems
Volume	16
Issue number	5
DOIs	https://doi.org/10.1109/TBCAS.2022.3201328
Publication status	Published - 2022 Oct 1

All Science Journal Classification (ASJC) codes

Biomedical Engineering
Electrical and Electronic Engineering

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title = "A 0.8-μW and 74-dB High-Pass Sigma-Delta Modulator with OPAMP Sharing and Noise-Coupling Techniques for Biomedical Signal Acquisition",

abstract = "This work presents a third-order high-pass sigma-delta modulator (HPSDM) for biomedical signal acquisition. The operational amplifier (op-Amp) sharing and noise-coupling techniques are adopted to reduce the required quantity of op-Amps and add a noise-shaping order, which can achieve low power consumption and high resolution. A novel switched-capacitor architecture is proposed to suppress the increasing in-band noise and alleviate the circuit sensitivity to capacitor mismatch in the high-pass integrator. The proposed HPSDM was fabricated in a 0.18-μm standard CMOS process. Measurement results reveal that the proposed HPSDM has a signal-To-noise and distortion ratio (SNDR) of 75.26/74 dB in 200 Hz bandwidth and consumes 1.52/0.8 μW under 1.2/1 V supply voltage, which can achieve a peak Schreier Figure-of-Merit of 156.45/157.98 dB and a peak Walden FoM of 0.802/0.488 pJ/conv.",

author = "Lee, {Shuenn Yuh} and Lee, {Hao Yun} and Kung, {Chia Ho} and Su, {Po Han} and Chen, {Ju Yi}",

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T1 - A 0.8-μW and 74-dB High-Pass Sigma-Delta Modulator with OPAMP Sharing and Noise-Coupling Techniques for Biomedical Signal Acquisition

AU - Lee, Shuenn Yuh

AU - Lee, Hao Yun

AU - Kung, Chia Ho

AU - Su, Po Han

AU - Chen, Ju Yi

PY - 2022/10/1

Y1 - 2022/10/1

N2 - This work presents a third-order high-pass sigma-delta modulator (HPSDM) for biomedical signal acquisition. The operational amplifier (op-Amp) sharing and noise-coupling techniques are adopted to reduce the required quantity of op-Amps and add a noise-shaping order, which can achieve low power consumption and high resolution. A novel switched-capacitor architecture is proposed to suppress the increasing in-band noise and alleviate the circuit sensitivity to capacitor mismatch in the high-pass integrator. The proposed HPSDM was fabricated in a 0.18-μm standard CMOS process. Measurement results reveal that the proposed HPSDM has a signal-To-noise and distortion ratio (SNDR) of 75.26/74 dB in 200 Hz bandwidth and consumes 1.52/0.8 μW under 1.2/1 V supply voltage, which can achieve a peak Schreier Figure-of-Merit of 156.45/157.98 dB and a peak Walden FoM of 0.802/0.488 pJ/conv.

AB - This work presents a third-order high-pass sigma-delta modulator (HPSDM) for biomedical signal acquisition. The operational amplifier (op-Amp) sharing and noise-coupling techniques are adopted to reduce the required quantity of op-Amps and add a noise-shaping order, which can achieve low power consumption and high resolution. A novel switched-capacitor architecture is proposed to suppress the increasing in-band noise and alleviate the circuit sensitivity to capacitor mismatch in the high-pass integrator. The proposed HPSDM was fabricated in a 0.18-μm standard CMOS process. Measurement results reveal that the proposed HPSDM has a signal-To-noise and distortion ratio (SNDR) of 75.26/74 dB in 200 Hz bandwidth and consumes 1.52/0.8 μW under 1.2/1 V supply voltage, which can achieve a peak Schreier Figure-of-Merit of 156.45/157.98 dB and a peak Walden FoM of 0.802/0.488 pJ/conv.

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A 0.8-μW and 74-dB High-Pass Sigma-Delta Modulator with OPAMP Sharing and Noise-Coupling Techniques for Biomedical Signal Acquisition

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