DA

  • using distributed arrays; Bratu nonlinear PDE in 3d.
    We solve the Bratu (SFI - solid fuel ignition) problem in a 3D rectangular
    domain, using distributed arrays (DAs) to partition the parallel grid.
  • using distributed arrays; Nonlinear driven cavity with multigrid in 2d.

    The 2D driven cavity problem is solved in a velocity-vorticity formulation.
    The flow can be driven with the lid or with bouyancy or both:
    -lidvelocity <lid>, where <lid> = dimensionless velocity of lid
    -grashof <gr>, where <gr> = dimensionless temperature gradient
    -prandtl <pr>, where <pr> = dimensionless thermal/momentum diffusity ratio
    Mesh parameters are:
    -mx <xg>, where <xg> = number of grid points in the x-direction
    -my <yg>, where <yg> = number of grid points in the y-direction
    -printg : print grid information
    Graphics of the contours of (U,V,Omega,T) are available on each grid:
    -contours : draw contour plots of solution
  • using distributed arrays; Bratu nonlinear PDE in 2d.
    We solve the Bratu (SFI - solid fuel ignition) problem in a 2D rectangular
    domain, using distributed arrays (DAs) to partition the parallel grid.
  • using distributed arrays Nonlinear Radiative Transport PDE with multigrid in 2d.
    Uses 2-dimensional distributed arrays.
    A 2-dim simplified Radiative Transport test problem is used, with analytic Jacobian.

    Solves the linear systems via multilevel methods

    The command line
    options are:
    -tleft <tl>, where <tl> indicates the left Diriclet BC
    -tright <tr>, where <tr> indicates the right Diriclet BC
    -beta <beta>, where <beta> indicates the exponent in T
  • using distributed arrays Nonlinear Radiative Transport PDE with multigrid in 3d.
    Uses 3-dimensional distributed arrays.
    A 3-dim simplified Radiative Transport test problem is used, with analytic Jacobian.

    Solves the linear systems via multilevel methods

    The command line
    options are:
    -tleft <tl>, where <tl> indicates the left Diriclet BC
    -tright <tr>, where <tr> indicates the right Diriclet BC
    -beta <beta>, where <beta> indicates the exponent in T