102: 1D Stationary convection-diffusion equation
Solve the equation
\[-\nabla ( D \nabla u - v u) = 0\]
in $\Omega=(0,1)$ with boundary condition $u(0)=0$ and $u(1)=1$. $v$ could be e.g. the velocity of a moving medium or the gradient of an electric field.
This is a convection dominant second order boundary value problem which obeys a local and a global maximum principle: the solution which is bounded by the values at the boundary and has no local extrema in the interior. If $v$ is large compared to $D$, a boundary layer is observed.
The maximum principle of the solution can only be guaranteed it the discretization is performed accordingly: the flux function must monotonically increase in the first argument and monotonically decrease in the second argument.
The example describes three possible ways to define the flux function and demonstrates the impact on the qualitative properties of the solution.
module Example102_StationaryConvectionDiffusion1D
using Printf
using VoronoiFVM
using ExtendableGrids
using GridVisualize
# Central difference flux. The velocity term is discretized using the
# average of the solution in the endpoints of the grid. If the local Peclet
# number v*h/D>1, the monotonicity property is lost. Grid refinement
# can fix this situation by decreasing $h$.
function central_flux!(f, u, edge, data)
f_diff = data.D * (u[1, 1] - u[1, 2])
vh = project(edge, data.v)
f[1] = f_diff + vh * (u[1, 1] + u[1, 2]) / 2
end
# The simple upwind flux corrects the monotonicity properties essentially
# via brute force and loses one order of convergence for small $h$ compared
# to the central flux.
function upwind_flux!(f, u, edge, data)
fdiff = data.D * (u[1] - u[1, 2])
vh = project(edge, data.v)
if vh > 0
f[1] = fdiff + vh * u[1, 1]
else
f[1] = fdiff + vh * u[1, 2]
end
end
# The exponential fitting flux has the proper monotonicity properties and
# kind of interpolates in a clever way between central
# and upwind flux. It can be derived by solving the two-point boundary value problem
# at the grid interval analytically.
# Bernoulli function used in the exponential fitting discretization
function bernoulli(x)
if abs(x) < nextfloat(eps(typeof(x)))
return 1
end
return x / (exp(x) - 1)
end
function exponential_flux!(f, u, edge, data)
vh = project(edge, data.v)
Bplus = data.D * bernoulli(vh / data.D)
Bminus = data.D * bernoulli(-vh / data.D)
f[1] = Bminus * u[1, 1] - Bplus * u[1, 2]
end
function calculate(grid, data, flux, verbose)
sys = VoronoiFVM.System(grid, VoronoiFVM.Physics(; flux = flux, data = data))
# Add species 1 to region 1
enable_species!(sys, 1, [1])
# Set boundary conditions
boundary_dirichlet!(sys, 1, 1, 0.0)
boundary_dirichlet!(sys, 1, 2, 1.0)
# Create a solution array
inival = unknowns(sys; inival = 0.5)
solution = unknowns(sys)
# Create solver control info
control = VoronoiFVM.NewtonControl()
control.verbose = verbose
# Stationary solution of the problem
solution = solve(sys; inival, verbose)
return solution
end
function main(; n = 10, Plotter = nothing, verbose = false, D = 0.01, v = 1.0)
# Create a one-dimensional discretization
h = 1.0 / convert(Float64, n)
grid = simplexgrid(collect(0:h:1))
data = (v = [v], D = D)Calculate three stationary solutions with different ways to calculate flux
solution_exponential = calculate(grid, data, exponential_flux!, verbose)
solution_upwind = calculate(grid, data, upwind_flux!, verbose)
solution_central = calculate(grid, data, central_flux!, verbose)Visualize solutions using GridVisualize.jl
p = GridVisualizer(; Plotter = Plotter, layout = (3, 1))
scalarplot!(p[1, 1], grid, solution_exponential[1, :]; title = "exponential")
scalarplot!(p[2, 1], grid, solution_upwind[1, :]; title = "upwind")
scalarplot!(p[3, 1], grid, solution_central[1, :]; title = "centered", show = true)
# Return test value
return sum(solution_exponential) + sum(solution_upwind) + sum(solution_central)
end
using Test
function runtests()
testval = 2.523569744561089
@test main() ≈ testval
end
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