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    Area of Science:

    • Biomedical Engineering
    • Signal Processing
    • Machine Learning

    Background:

    • Wearable devices are crucial for continuous health monitoring and early disease detection.
    • Physiological signals from wearables are prone to interference like Motion Artifacts (MA) and Baseline Wanders (BW).
    • Accurate noise detection in wearable signals is vital to prevent false alarms in remote healthcare.

    Purpose of the Study:

    • To develop a Machine Learning (ML)-based method for identifying noise in Photoplethysmogram (PPG) signals.
    • To distinguish between clean, MA-corrupted, and BW-corrupted PPG signal segments.
    • To evaluate the performance of the ML approach without relying on data from other sensors.

    Main Methods:

    • A Machine Learning (ML) model was trained to classify PPG signal segments.
    • The model was designed to differentiate between clean signals and those corrupted by Motion Artifacts (MA) or Baseline Wanders (BW).
    • The approach was validated without using auxiliary sensor data, such as accelerometer readings.

    Main Results:

    • The ML-based classification achieved high accuracy in distinguishing signal types.
    • F1-scores ranged from 89.3% for three-class classification to 99.4% for binary classification.
    • The proposed method effectively identified noise in PPG signals without external sensor references.

    Conclusions:

    • The developed ML approach offers a robust solution for detecting artifacts in wearable PPG signals.
    • This method can enhance the reliability of remote health monitoring systems by reducing false alarms.
    • The sensor-independent nature of this technique makes it broadly applicable to various wearable healthcare devices.