Simulation of Light Propagation Modes in Optical Fibers
This package contains 13 programs simulating light propagation modes in optical fibers, implemented with MATLAB-based numerical modeling approaches.
Calculation of Effective Refractive Index for Fiber Core Fundamental Mode Using Bisection Method
A MATLAB program implementing bisection method algorithm to compute the effective refractive index of optical fiber core fundamental mode, featuring numerical convergence with error tolerance control.
Simulation of Light Propagation in Two-Dimensional Photonic Crystal Fibers Using the Finite-Difference Time-Domain Method
Implementation of the Finite-Difference Time-Domain (FDTD) method for simulating light propagation phenomena in 2D photonic crystal fiber structures, including code-level discussions on numerical discretization and boundary condition handling.
Temperature Filtering Characteristics Analysis of Fiber Chirped Bragg Grating Filters Using Transfer Matrix Method
Computational analysis of temperature-dependent filtering properties in fiber chirped Bragg grating filters through transfer matrix method implementation
Signal Processing for Phase-sensitive OTDR Scheme in Fiber Optic Micro-Vibration Sensors
Signal processing program for phase-sensitive OTDR scheme in fiber optic micro-vibration sensors, developed using MATLAB for direct simulation and algorithm verification.
Nonlinear Transmission of Signal Light in Optical Fibers with Dispersion and Phase Modulation Effects
Solving the Nonlinear Transmission Equation for Signal Light in Optical Fibers Affected by Dispersion, Self-Phase Modulation, and Cross-Phase Modulation Effects – Implementation Approaches Using Numerical Methods like Split-Step Fourier Algorithm
Simulation of Optical Soliton Transmission in Fiber Couplers
Simulation Study of Optical Soliton Transmission in Fiber Couplers - This paper conducts MATLAB-based simulations to model the propagation process of optical solitons in fiber couplers, providing detailed analysis of soliton dynamics and coupling mechanisms.
Solving the Nonlinear Schrödinger Equation for Beam Propagation in Optical Fibers
Simulates nonlinear beam propagation in optical fibers by solving the Schrödinger equation with key physical effects including second-order dispersion and loss, implemented with robust numerical algorithms for photonics applications
Split-Step Fourier Method
The implementation utilizes the Split-Step Fourier Method to solve the nonlinear Schrödinger equation, enabling accurate calculation of dispersion and self-phase modulation (SPM) effects in optical fibers.
Second-Order Dispersion Effects on Optical Pulse Propagation in Optical Fibers
Analysis of second-order dispersion effects during optical pulse transmission in fibers and solution methods with numerical implementation approaches