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Simple one-dimensional examples of various hydrodynamics techniques

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hydro_examples

Simple one-dimensional examples of various hydrodynamics techniques

This is a collection of simple python codes (+ a few Fortran ones) that demonstrate some basic techniques used in hydrodynamics codes. All the codes are standalone -- there are no interdependencies.

These codes go together with the lecture notes at:

http://bender.astro.sunysb.edu/hydro_by_example/CompHydroTutorial.pdf

and with the pyro2 code:

https://github.com/python-hydro/pyro2

  • advection/

    • advection.py: a 1-d second-order linear advection solver with a wide range of limiters.

    • fdadvect_implicit.py: a 1-d first-order implicit finite-difference linear advection solver using periodic boundary conditions.

    • fdadvect.py: a 1-d first-order explicit finite-difference linear advection solver using upwinded differencing.

    • fv_mol.py: a 1-d method-of-lines second-order accurate advection solver.

    • Fortran/:

      • advect.f90: a Fortran implementation of second-order linear advection. This version does piecewise constant, piecewise linear, and piecewise parabolic (PPM) reconstruction.
  • basic-numerics

    • orbit-converge.py (and orbit.py): a demonstration of the convergence of different ODE integration methods for the problem of Earth orbiting around the Sun.
  • burgers/

    • burgers.py: a 1-d second-order solver for the inviscid Burgers’ equation, with initial conditions corresponding to a shock and a rarefaction.
  • compressible/

    • euler.ipynb: a SymPy IPython notebook that derives the eigenvalues and eigenvectors for the Euler equations.

    • riemann-phase.py: a simple script that plots the Hugoniot curves for a compressible Riemann problem (assuming a gamma-law gas)

  • diffusion/

    • diffusion-explicit.py: solve the constant-diffusivity diffusion equation explicitly. The method is first-order accurate in time, but second- order in space. A Gaussian profile is diffused--the analytic solution is also a Gaussian.

    • diffusion-implicit.py: solve the constant-diffusivity diffusion equation implicitly. Crank-Nicolson time-discretization is used, resulting in a second-order method. A Gaussian profile is diffused.

  • elliptic/

    • poisson_fft.py: an FFT solver for a 2-d Poisson problem with periodic boundaries.
  • finite-volume/

    • conservative-interpolation.ipynb: an IPython notebook that illustrates how to derive high-order conservative interpolants for finite-volume data.
  • incompressible/

    • project.py: a simple example of using a projection to recover a divergence-free velocity field.
  • multigrid/

    • mg_converge.py: a convergence test of the multigrid solver. A Poisson problem is solved at various resolutions and compared to the exact solution. This demonstrates second-order accuracy.

    • mg_test.py: a simple driver for the multigrid solver. This sets up and solves a Poisson problem and plots the behavior of the solution as a function of V-cycle number.

    • multigrid.py: a multigrid class for cell-centered data. This implements pure V-cycles. A square domain with 2 N zones (N a positive integer) is required.

    • patch1d.py: a class for 1-d cell-centered data that lives on a grid. This manages the data, handles boundary conditions, and provides routines for prolongation and restriction to other grids.

  • multiphysics/

    • burgersvisc.py: solve the viscous Burgers equation. The advective terms are treated explicitly with a second-order accurate method. The diffusive term is solved using an implicit Crank-Nicolson discretiza- tion. The overall coupling is second-order accurate.

    • diffusion-reaction.py: solve a diffusion-reaction equation that propagates a diffusive reacting front (flame). A simple reaction term is modeled. The diffusion is solved using a second-order Crank-Nicolson discretization. The reactions are evolved using the VODE ODE solver (via SciPy). The two processes are coupled together using Strang-splitting to be second-order accurate in time.

  • parallel/

    • relax-mpi.f90: a simple example of pure relaxiation using domain decomposition + message passing (through MPI) to implement smoothing in a parallel fashion.

    • relax-omp.f90: a simple example of pure relaxation using OpenMP to parallelize the loops using shared-memory.

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