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Rapid Repetition Rate Fluctuation Measurement of Soliton Crystals in a Microresonator
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Temporal pattern generation with tunable repetition rate using semiconductor laser periodic dynamics.

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    This study demonstrates a semiconductor laser generating diverse, repeatable temporal patterns for time delay reservoir computing. The system utilizes optical feedback and filtering to create tunable, periodic waveforms.

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    Area of Science:

    • Optoelectronics
    • Nonlinear Dynamics
    • Signal Processing

    Background:

    • Semiconductor lasers are crucial for optical communications and signal generation.
    • Optical feedback can induce complex dynamics in lasers, offering potential for novel waveform generation.
    • Time delay reservoir computing requires diverse and repeatable input signals.

    Purpose of the Study:

    • To investigate the generation of repetitive temporal patterns with enhanced intra-pattern sample diversity using a long-cavity semiconductor laser with optical feedback.
    • To demonstrate stable and continuous generation of periodic waveforms with tunable repetition rates.
    • To adapt these generated patterns for applications in time delay reservoir computing.

    Main Methods:

    • Utilizing a semiconductor laser with a 2-m external cavity and controlled optical feedback.
    • Experimentally demonstrating limit cycle dynamics with multiple frequency harmonics.
    • Applying high-pass filtering to adjust harmonic power and achieve distinct temporal patterns.

    Main Results:

    • Stable and continuous generation of periodic waveforms with tunable repetition rates from 3.28 to 4.21 GHz.
    • Achieved enhanced intra-pattern sample diversity in generated temporal patterns.
    • Demonstrated distinct and highly consistent temporal patterns through harmonic adjustment.

    Conclusions:

    • A simple long-cavity semiconductor laser configuration with optical feedback can act as a physical waveform generator.
    • The generated diverse and repeatable signal patterns are suitable for the masking stage of time delay reservoir computing.
    • This approach offers a promising method for generating complex temporal dynamics for advanced computing architectures.