3#ifndef DUNE_DUAL_Q1_LOCALFINITEELEMENT_HH
4#define DUNE_DUAL_Q1_LOCALFINITEELEMENT_HH
38 template<
class D,
class R,
int dim,
bool faceDual=false>
52 setupFaceDualCoefficients();
54 setupDualCoefficients();
88 return GeometryTypes::cube(
dim);
93 void setupFaceDualCoefficients();
96 void setupDualCoefficients();
103 template<
class D,
class R,
int dim,
bool faceDual>
104 void DualQ1LocalFiniteElement<D,R,dim,faceDual>::setupDualCoefficients()
120 for (
int i=0; i<
size; i++)
123 Dune::Impl::LagrangeCubeLocalBasis<D,R,dim,1> q1Basis;
124 for(
size_t pt=0; pt<quad.size(); pt++) {
128 q1Basis.evaluateFunction(pos,q1Values);
130 D weight = quad[pt].weight();
132 for (
int k=0; k<
size; k++) {
133 integral[k] += q1Values[k]*weight;
135 for (
int l=0; l<=k; l++)
136 massMat[k][l] += weight*(q1Values[k]*q1Values[l]);
141 for (
int i=0; i<
size-1; i++)
142 for (
int j=i+1; j<
size; j++)
143 massMat[i][j] = massMat[j][i];
147 for (
int i=0; i<
size; i++) {
150 rhs[i] = integral[i];
153 massMat.
solve(coeffs[i] ,rhs);
157 basis.setCoefficients(coeffs);
158 interpolation.setCoefficients(coeffs);
161 template<
class D,
class R,
int dim,
bool faceDual>
162 void DualQ1LocalFiniteElement<D,R,dim,faceDual>::setupFaceDualCoefficients()
169 Dune::Impl::LagrangeCubeLocalBasis<D,R,dim,1> q1Basis;
171 const auto& refElement = Dune::ReferenceElements<D,dim>::general(type());
174 for (
int i=0; i<refElement.size(1);i++) {
185 const auto& geometry = refElement.template geometry<1>(i);
189 for (
int k=0; k<
size/2; k++)
192 for(
size_t pt=0; pt<quad.size(); pt++) {
194 const auto& pos = quad[pt].position();
195 const auto& elementPos = geometry.global(pos);
198 q1Basis.evaluateFunction(elementPos,q1Values);
200 D weight = quad[pt].weight();
202 for (
int k=0; k<refElement.size(i,1,
dim); k++) {
203 int row = refElement.subEntity(i,1,k,
dim);
204 integral[k] += q1Values[row]*weight;
206 for (
int l=0; l<refElement.size(i,1,
dim); l++) {
207 int col = refElement.subEntity(i,1,l,
dim);
208 massMat[k][l] += weight*(q1Values[row]*q1Values[col]);
216 for (
int l=0; l<refElement.size(i,1,
dim); l++) {
218 int row = refElement.subEntity(i,1,l,
dim);
220 rhs[l] = integral[l];
223 massMat.
solve(x ,rhs);
225 for (
int k=0; k<refElement.size(i,1,
dim); k++) {
226 int col = refElement.subEntity(i,1,k,
dim);
227 coeffs[row][col]=x[k];
232 basis.setCoefficients(coeffs);
233 interpolation.setCoefficients(coeffs);
void solve(V1 &x, const V2 &b, bool doPivoting=true) const
static const QuadratureRule & rule(const GeometryType &t, int p, QuadratureType::Enum qt=QuadratureType::GaussLegendre)
traits helper struct
Definition localfiniteelementtraits.hh:11
LB LocalBasisType
Definition localfiniteelementtraits.hh:14
LC LocalCoefficientsType
Definition localfiniteelementtraits.hh:18
LI LocalInterpolationType
Definition localfiniteelementtraits.hh:22
The local dual Q1 finite element on cubes.
Definition dualq1.hh:40
LocalFiniteElementTraits< DualQ1LocalBasis< D, R, dim >, DualQ1LocalCoefficients< dim >, DualQ1LocalInterpolation< dim, DualQ1LocalBasis< D, R, dim > > > Traits
Definition dualq1.hh:45
unsigned int size() const
Number of shape functions in this finite element.
Definition dualq1.hh:79
const Traits::LocalInterpolationType & localInterpolation() const
Definition dualq1.hh:73
const Traits::LocalBasisType & localBasis() const
Definition dualq1.hh:59
const Traits::LocalCoefficientsType & localCoefficients() const
Definition dualq1.hh:66
DualQ1LocalFiniteElement()
Definition dualq1.hh:49
static constexpr GeometryType type()
Definition dualq1.hh:86
Dual Lagrange shape functions of order 1 on the reference cube.
Definition dualq1localbasis.hh:27
Layout map for dual Q1 elements.
Definition dualq1localcoefficients.hh:23
Definition dualq1localinterpolation.hh:19