This article presents a low-power, high-gain, and wide–dynamic range (DR) photoplethysmography (PPG) sensory system with a novel direct current (dc) compensation loop and light-emitting diode (LED) dimming control. The proposed PPG system exhibits a signal-aware performance, where, at strong PPG signal levels, the dc compensation loop’s capability of removing dc photocurrent is increased and the LED’s driving current is reduced. This ability allows the entire DR to be utilized by the useful alternating current (ac) component of the signal and reduces power dissipation. Fabricated in 0.35- μm standard CMOS technology, the proposed PPG sensor occupies an area of 1.744 mm2 . The proposed system exhibits a high gain and a low input-referred noise current of 19.6 MΩ and 11.23 pArms , respectively, while dissipating only 9.9 μW of power at the receiver’s analog frontend. The proposed dc compensation loop can remove up to 80 μA of dc photocurrent for 2% total harmonic distortion (THD), achieving a DR of 137 dB. An external microcontroller unit (MCU) uses a machine learning (ML) algorithm to extract blood pressure (BP) from the analog output of the implemented PPG sensor chip. Measurements from eight human subjects show a mean absolute error (MAE) and a standard deviation of 2.25 ± 2.82 mmHg for systolic BP (SBP) and 5.01 ± 2.10 mmHg for diastolic BP (DBP).
Research Member
Research Department
Research Date
Research Year
2024
Research Journal
IEEE Sensors Journal
Research Publisher
IEEE
Research Vol
24
Research Rank
7
Research_Pages
10375-10384
Research Website
https://ieeexplore.ieee.org/document/10453460
Research Abstract
Research Rank
International Journal