Solving the 1d diffusion equation using the FTCS and Crank-Nicolson methods
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Updated
Mar 9, 2017 - C
Solving the 1d diffusion equation using the FTCS and Crank-Nicolson methods
Solving the 2D diffusion equation using the FTCS explicit and Crank-Nicolson implicit scheme with Alternate Direction Implicit method on uniform square grid
Solving the 2D steady state heat equation using the Successive Over Relaxation (SOR) explicit and the Line Successive Over Relaxation (LSOR) Implicit method
Investigation into the use of Domain Specific Languages with the NEMO ocean model
A N-dimensional lattice iterator for C++
Quant analysis library
A gas burner's cone, modeled with a conduction-based finite difference method (FDM) in MATLAB
Pricing TARN Using Numerical Methods
Solution to Burger's Equation (inviscid), written in C, using Adams-Bashforth Methods. These methods include the one, two, and three step algorithms.
Implementation of various different numerical methods for solving PDEs. Furthermore, solutions of more complex scenarios of heat transform are examined.
Parallel Multigrid solvers for Poisson, modified Helmholtz and implicit hyperdiffusion
Python library for computing non-uniform 1D finite difference derivatives
Finite differences simulations. Implemented with c++, mpi and matlab.
Numerical check on analytic gradient + hessian of function.
From multiple degree-of-freedom to distributed systems: linear strings and sound synthesis
Solves the compressible Navier-Stokes equations using the finite difference method to simulate a 2D Rayleigh-Taylor instability.
Simulation numérique de l’équation de la diffusion par la méthode des différences finies
This is a two-dimensional fluid solver written in a hybrid CPU-GPU architecture platform This code has been written as part of the requiremnts for the following courses at the University of Utah: Computational Fluid Dynamics Parallel computing on many-cores @ Authors: Arash Nemati Hayati Akshay Singhvi Lucas Ulmer
Finite Volume Solver for 1D advection-diffusion using a Point Implicit Method written as part of a class project for "Fundamentals of CFD" course at ETH Zurich
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