Poisson equationΒΆ

We solve the Poisson equation on the unit-square, with homogeneous Dirichlet boundary conditions. You can run the example either directly within the Python interpreter (Python version 3 is required!):

python3 poisson.py

or you can run it with Netgen providing you also a graphical user interface

netgen poisson.py
# solve the Poisson equation -Delta u = f
# with Dirichlet boundary condition u = 0

from ngsolve import *
from netgen.geom2d import unit_square

ngsglobals.msg_level = 1

# generate a triangular mesh of mesh-size 0.2
mesh = Mesh(unit_square.GenerateMesh(maxh=0.2))

# H1-conforming finite element space
fes = H1(mesh, order=3, dirichlet=[1,2,3,4])

# define trial- and test-functions
u = fes.TrialFunction()
v = fes.TestFunction()

# the right hand side
f = LinearForm(fes)
f += SymbolicLFI(32 * (y*(1-y)+x*(1-x)) * v)

# the bilinear-form 
a = BilinearForm(fes, symmetric=True)
a += SymbolicBFI(grad(u)*grad(v))


# the solution field 
gfu = GridFunction(fes)
gfu.vec.data = a.mat.Inverse(fes.FreeDofs(), inverse="sparsecholesky") * f.vec
# print (u.vec)

# plot the solution (netgen-gui only)
Draw (gfu)
Draw (-grad(gfu), mesh, "Flux")

exact = 16*x*(1-x)*y*(1-y)
print ("L2-error:", sqrt (Integrate ( (gfu-exact)*(gfu-exact), mesh)))

The solution visualized in Netgen: