Mode-Locked Laser Principle Simulation

This self-developed simulation of mode-locked laser principles, while simplified, effectively demonstrates the characteristics of mode-locked laser pulses. Mode-locked lasers play a crucial role in modern laser technology by maintaining specific phase relationships among optical waves. The core algorithm simulates how these phase-locked signals synchronize to form ultrashort pulses through temporal domain superposition calculations. The simulation employs Fourier transform techniques to model spectral components and their interference patterns, implementing key functions like pulse duration calculation and frequency comb generation. Mode-locked lasers are primarily applied in precision measurement, optical communications, and LIDAR systems, making understanding their pulse properties essential for related research fields. Through this coded simulation, we can not only gain deeper insights into mode-locked pulse characteristics but also better apply this knowledge to practical applications through parameter adjustment modules and visualization functions.