🚀 Solve the time-dependent Schrodinger equation in unbounded domain
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Updated
Jan 16, 2018 - MATLAB
🚀 Solve the time-dependent Schrodinger equation in unbounded domain
Une simulation de l'évolution d'un paquet d'onde gaussien
Finite-Difference Approximations to the Heat Equation. Implementation of schemes: Forward Time, Centered Space; Backward Time, Centered Space; Crank-Nicolson.
Differents algorithms on python or matlab about numerical analysis - UNI
A python script that displays an animation of an electron propagation and its interaction with arbitrary potential. The program solves the two-dimensional time-dependant Schrödinger equation using Crank-Nicolson algorithm.
Heat Equation: Crank-Nicolson / Explicit Methods, designed to estimate the solution to the heat equation. Python, using 3D plotting result in matplotlib.
Python implementation of 1D Time-dependent Schroedinger Equation solver to study the adiabaticity of any 1D system.
Fast American option pricing using spectral collocation method based on integral form. An independent Crank Nicolson method is included for comparison.
Crank-Nicholson solver for a 1-D heat transfer model.
This repositary contains the MATLAB implementation of main numerical methods like Newton-Raphson, Simpson's integration and numerical ODE solver.
Simulation of a space shuttle tile using 2D partial differential equation solvers
Solving the time dependent Schrödinger equation using the Crank-Nicolson method
Implementation of well-known numerical methods.
I used the Cranck-Nicholson Algorithm to demonstrate the time evolution of a Gaussian wave by Schrödinger's Picture in Quantum Mechanics. The system is a 1-D box with a positive potential well.
Finite Difference algorithms for Partial Differential Equation written in python (Based on Smith book)
Beam propagation method (BPM) for photonic integrated circuits (PIC), implemented in MATLAB with finite-differences in 2D. Includes slab waveguide mode-solver.
Using Finite Element and Finite Difference Methods to Price European Options
Crank-Nicolson method for the heat equation in 2D
This repository contains Python 3 scripts for simulating the passage of a 2D Gaussian wave packet through a double slit. For this, the 2D Schrödinger equation is solved using the Crank-Nicolson numerical method.
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