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demo_poisson.py
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demo_poisson.py
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# ---
# jupyter:
# jupytext:
# text_representation:
# extension: .py
# format_name: light
# format_version: '1.5'
# jupytext_version: 1.13.6
# ---
# # Poisson equation
#
# This demo is implemented in {download}`demo_poisson.py`. It
# illustrates how to:
#
# - Create a {py:class}`function space <dolfinx.fem.FunctionSpace>`
# - Solve a linear partial differential equation
#
# ## Equation and problem definition
#
# For a domain $\Omega \subset \mathbb{R}^n$ with boundary $\partial
# \Omega = \Gamma_{D} \cup \Gamma_{N}$, the Poisson equation with
# particular boundary conditions reads:
#
# $$
# \begin{align}
# - \nabla^{2} u &= f \quad {\rm in} \ \Omega, \\
# u &= 0 \quad {\rm on} \ \Gamma_{D}, \\
# \nabla u \cdot n &= g \quad {\rm on} \ \Gamma_{N}. \\
# \end{align}
# $$
#
# where $f$ and $g$ are input data and $n$ denotes the outward directed
# boundary normal. The variational problem reads: find $u \in V$ such
# that
#
# $$
# a(u, v) = L(v) \quad \forall \ v \in V,
# $$
#
# where $V$ is a suitable function space and
#
# $$
# \begin{align}
# a(u, v) &:= \int_{\Omega} \nabla u \cdot \nabla v \, {\rm d} x, \\
# L(v) &:= \int_{\Omega} f v \, {\rm d} x + \int_{\Gamma_{N}} g v \, {\rm d} s.
# \end{align}
# $$
#
# The expression $a(u, v)$ is the bilinear form and $L(v)$
# is the linear form. It is assumed that all functions in $V$
# satisfy the Dirichlet boundary conditions ($u = 0 \ {\rm on} \
# \Gamma_{D}$).
#
# In this demo we consider:
#
# - $\Omega = [0,2] \times [0,1]$ (a rectangle)
# - $\Gamma_{D} = \{(0, y) \cup (2, y) \subset \partial \Omega\}$
# - $\Gamma_{N} = \{(x, 0) \cup (x, 1) \subset \partial \Omega\}$
# - $g = \sin(5x)$
# - $f = 10\exp(-((x - 0.5)^2 + (y - 0.5)^2) / 0.02)$
#
# ## Implementation
#
# The modules that will be used are imported:
import importlib.util
if importlib.util.find_spec("petsc4py") is not None:
import dolfinx
if not dolfinx.has_petsc:
print("This demo requires DOLFINx to be compiled with PETSc enabled.")
exit(0)
from petsc4py.PETSc import ScalarType # type: ignore
else:
print("This demo requires petsc4py.")
exit(0)
from mpi4py import MPI
# +
import numpy as np
import ufl
from dolfinx import fem, io, mesh, plot
from dolfinx.fem.petsc import LinearProblem
from ufl import ds, dx, grad, inner
# -
# Note that it is important to first `from mpi4py import MPI` to
# ensure that MPI is correctly initialised.
# We create a rectangular {py:class}`Mesh <dolfinx.mesh.Mesh>` using
# {py:func}`create_rectangle <dolfinx.mesh.create_rectangle>`, and
# create a finite element {py:class}`function space
# <dolfinx.fem.FunctionSpace>` $V$ on the mesh.
# +
msh = mesh.create_rectangle(
comm=MPI.COMM_WORLD,
points=((0.0, 0.0), (2.0, 1.0)),
n=(32, 16),
cell_type=mesh.CellType.triangle,
)
V = fem.functionspace(msh, ("Lagrange", 1))
# -
# The second argument to {py:func}`functionspace
# <dolfinx.fem.functionspace>` is a tuple `(family, degree)`, where
# `family` is the finite element family, and `degree` specifies the
# polynomial degree. In this case `V` is a space of continuous Lagrange
# finite elements of degree 1.
#
# To apply the Dirichlet boundary conditions, we find the mesh facets
# (entities of topological co-dimension 1) that lie on the boundary
# $\Gamma_D$ using {py:func}`locate_entities_boundary
# <dolfinx.mesh.locate_entities_boundary>`. The function is provided
# with a 'marker' function that returns `True` for points `x` on the
# boundary and `False` otherwise.
facets = mesh.locate_entities_boundary(
msh,
dim=(msh.topology.dim - 1),
marker=lambda x: np.isclose(x[0], 0.0) | np.isclose(x[0], 2.0),
)
# We now find the degrees-of-freedom that are associated with the
# boundary facets using {py:func}`locate_dofs_topological
# <dolfinx.fem.locate_dofs_topological>`:
dofs = fem.locate_dofs_topological(V=V, entity_dim=1, entities=facets)
# and use {py:func}`dirichletbc <dolfinx.fem.dirichletbc>` to create a
# {py:class}`DirichletBC <dolfinx.fem.DirichletBC>` class that
# represents the boundary condition:
bc = fem.dirichletbc(value=ScalarType(0), dofs=dofs, V=V)
# Next, the variational problem is defined:
# +
u = ufl.TrialFunction(V)
v = ufl.TestFunction(V)
x = ufl.SpatialCoordinate(msh)
f = 10 * ufl.exp(-((x[0] - 0.5) ** 2 + (x[1] - 0.5) ** 2) / 0.02)
g = ufl.sin(5 * x[0])
a = inner(grad(u), grad(v)) * dx
L = inner(f, v) * dx + inner(g, v) * ds
# -
# A {py:class}`LinearProblem <dolfinx.fem.petsc.LinearProblem>` object is
# created that brings together the variational problem, the Dirichlet
# boundary condition, and which specifies the linear solver. In this
# case an LU solver is used. The {py:func}`solve
# <dolfinx.fem.petsc.LinearProblem.solve>` computes the solution.
# +
problem = LinearProblem(a, L, bcs=[bc], petsc_options={"ksp_type": "preonly", "pc_type": "lu"})
uh = problem.solve()
# -
# The solution can be written to a {py:class}`XDMFFile
# <dolfinx.io.XDMFFile>` file visualization with ParaView or VisIt:
# +
with io.XDMFFile(msh.comm, "out_poisson/poisson.xdmf", "w") as file:
file.write_mesh(msh)
file.write_function(uh)
# -
# and displayed using [pyvista](https://docs.pyvista.org/).
# +
try:
import pyvista
cells, types, x = plot.vtk_mesh(V)
grid = pyvista.UnstructuredGrid(cells, types, x)
grid.point_data["u"] = uh.x.array.real
grid.set_active_scalars("u")
plotter = pyvista.Plotter()
plotter.add_mesh(grid, show_edges=True)
warped = grid.warp_by_scalar()
plotter.add_mesh(warped)
if pyvista.OFF_SCREEN:
pyvista.start_xvfb(wait=0.1)
plotter.screenshot("uh_poisson.png")
else:
plotter.show()
except ModuleNotFoundError:
print("'pyvista' is required to visualise the solution")
print("Install 'pyvista' with pip: 'python3 -m pip install pyvista'")
# -