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Classification of laser modality for a self-mixing interferometric sensor.

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    Machine learning accurately identifies self-mixing (SM) signal modalities from laser sensors. This prevents measurement errors caused by abrupt shifts, improving sensing accuracy in optical feedback systems.

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    Area of Science:

    • Optoelectronics
    • Laser Physics
    • Signal Processing

    Background:

    • Robust detection and classification of multimodal self-mixing (SM) signals are crucial for accurate information retrieval from optical feedback-based interferometric laser sensors.
    • Abrupt shifts in SM signal modality, caused by varying operating conditions, can lead to significant measurement errors if not identified.
    • Proactive identification of SM signal modality is essential for implementing necessary adjustments in sensor setup or signal processing to mitigate errors.

    Purpose of the Study:

    • To propose and evaluate machine learning-based techniques for identifying and classifying multimodal self-mixing (SM) signals.
    • To address the challenge of unidentified modality shifts in SM interferometric laser sensor data.
    • To enhance the reliability and accuracy of sensing information retrieved from SM sensors.

    Main Methods:

    • Feature extraction from SM signals using Principal Component Analysis (PCA), peak width analysis, and Linear Discriminant Analysis (LDA).
    • Training and testing of machine learning classifiers, including Linear Regression, XGBoost Regressor, and Decision Tree Regressor.
    • Experimental acquisition of a dataset comprising 45 unseen SM signals from an SM sensor for method validation.

    Main Results:

    • The Decision Tree Regressor achieved 100% accuracy in identifying and classifying SM signal modalities.
    • The XGBoost Regressor demonstrated a high accuracy of 96% for SM signal modality classification.
    • Linear Regression achieved 76% accuracy, indicating varying performance among the tested machine learning algorithms.

    Conclusions:

    • Machine learning classifiers, particularly Decision Tree and XGBoost Regressors, are highly effective for robust SM signal modality identification and classification.
    • The proposed feature extraction and classification methods successfully address the challenge of modality shifts, significantly reducing potential measurement errors.
    • Accurate SM signal classification enables adaptive adjustments in sensor systems and signal processing, leading to improved sensing performance and data reliability.