8 7 GfsSimulation GfsBox GfsGEdge {} { # Stop the simulation at t = 15 Time { end = 15 } # Use an initial refinement of 6 levels (i.e. 2^6=64x64 for each box) Refine 6 # Insert the solid boundary defined as x*x + y*y - 0.0625*0.0625 = 0 # (i.e. a cylinder of radius 0.0625 centered on the origin) Solid (x*x + y*y - 0.0625*0.0625) # Add a passive tracer called T VariableTracer {} T # Set the initial x-component of the velocity to 1 Init {} { U = 1 } # Adapt the mesh using the vorticity criterion at every timestep # down to a maximum level of 6 and with a maximum tolerance of 1e-2 AdaptVorticity { istep = 1 } { maxlevel = 6 cmax = 1e-2 } # Adapt the mesh using the gradient criterion on variable T at # every timestep, down to a maximum level of 6 and with a maximum tolerance of 1e-2 AdaptGradient { istep = 1 } { maxlevel = 6 cmax = 1e-2 } T # Set a viscosity source term on the velocity vector with x-component U # The Reynolds number is Re = D*U/Nu = 0.125*1/0.00078125 = 160 # where D is the cylinder diameter (as defined in cylinder.gts) SourceDiffusion {} U 0.00078125 SourceDiffusion {} V 0.00078125 # Writes the time and timestep every 10 timesteps on standard error OutputTime { istep = 10 } stderr # Writes the simulation size every 10 timesteps on standard error OutputBalance { istep = 10 } stderr # Writes info about the convergence of the Poisson solver on standard error OutputProjectionStats { istep = 10 } stderr # Pipes a bitmap PPM image representation of the vorticity field at every other timestep # into a conversion pipeline to create a MPEG movie called vort.mpg # Sets the minimum used for colormapping to -10 and the maximum to 10 OutputPPM { istep = 2 } { ppm2mpeg > vort.mpg } { min = -10 max = 10 v = Vorticity } # Pipes a bitmap PPM image representation of the T field at every other timestep # into a MJPEGTools conversion pipeline to create a MPEG movie called t.mpg # Sets the minimum used for colormapping to 0 and the maximum to 1 OutputPPM { istep = 2 } { ppm2mpeg > t.mpg } { min = 0 max = 1 v = T } # Pipes a bitmap PPM image representation of the vorticity field at time 15 # into the ImageMagick converter "convert" to create the corresponding EPS file OutputPPM { start = 15 } { convert -colors 256 ppm:- vort.eps } { min = -10 max = 10 v = Vorticity } # Pipes a bitmap PPM image representation of the T field at time 15 # into the ImageMagick converter "convert" to create the corresponding EPS file OutputPPM { start = 15 } { convert -colors 256 ppm:- t.eps } { min = 0 max = 1 v = T } # Outputs profiling information at the end of the simulation to standard error OutputTiming { start = end } stderr } GfsBox { # Left boundary on the leftmost box is: # Dirichlet U=1 for the x-component of the velocity # Dirichlet T = 1 if y < 0, 0 otherwise left = Boundary { BcDirichlet U 1 BcDirichlet T { return y < 0. ? 1. : 0.; } } } GfsBox {} GfsBox {} GfsBox {} GfsBox {} GfsBox {} GfsBox {} # Right boundary on the rightmost box is outflow GfsBox { right = BoundaryOutflow } # All the boxes are linked by left to right links 1 2 right 2 3 right 3 4 right 4 5 right 5 6 right 6 7 right 7 8 right