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[CS.AI] Revolutionary Method: Predictor-Guided Reconstruction of Low-Quality PPG Signals for SpO$_2$ Estimation

Published at: 2026-07-11 22:00 Last updated: 2026-07-13 08:40
#algorithm #AI #optimization

Continuous oxygen saturation (SpO$_2$) estimation from wearable photoplethysmography (PPG) is crucial for long-term health monitoring. However, low-quality red and infrared PPG segments can distort waveform morphology and degrade SpO$_2$ prediction accuracy. Existing PPG denoising and reconstruction methods typically focus on either waveform fidelity or heart rate characteristics, while relying solely on time-domain waveform loss is insufficient to preserve frequency structure and SpO$_2$-relevant information.

This paper proposes a SpO$_2$ predictor-guided stage-wise time-frequency reconstruction framework for low-quality dual-wavelength PPG signals. The proposed method first selects high-quality PPG segments to pretrain an SpO$_2$ predictor. A masked reconstruction model is then trained to recover randomly masked PPG regions using a joint reconstruction objective that combines time-domain waveform loss with frequency-domain loss computed from the short-time Fourier transform (STFT).

To ensure the reconstruction task is physiologically relevant, the pretrained SpO$_2$ predictor is incorporated as an additional constraint, encouraging the reconstructed PPG to preserve SpO$_2$ information rather than merely minimizing reconstruction error. The SpO$_2$ predictor and PPG reconstructor model are optimized through four training stages. Experiments on the public OpenOximetry Repository and a private wearable PPG dataset demonstrate that the proposed approach achieves the lowest subject-level MAE, with 2.882% on the public dataset and 2.359% on the private dataset.

Blogger's Review: This study innovatively addresses the reconstruction of low-quality PPG signals by integrating an SpO$_2$ predictor, significantly enhancing the accuracy of oxygen saturation estimation. This approach offers new insights for the further development of wearable health monitoring devices, particularly in signal processing and physiological information extraction.

Original Source: https://arxiv.org/abs/2607.07996

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