/usr/include/trilinos/Stokhos_RecurrenceBasisImp.hpp is in libtrilinos-stokhos-dev 12.4.2-2.
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// $Source$
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#include "Teuchos_LAPACK.hpp"
#include "Teuchos_SerialDenseMatrix.hpp"
template <typename ordinal_type, typename value_type>
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
RecurrenceBasis(const std::string& name_, ordinal_type p_, bool normalize_,
Stokhos::GrowthPolicy growth_) :
name(name_),
p(p_),
normalize(normalize_),
growth(growth_),
quad_zero_tol(1.0e-14),
#ifdef HAVE_STOKHOS_DAKOTA
sparse_grid_growth_rule(webbur::level_to_order_linear_nn),
#else
sparse_grid_growth_rule(NULL),
#endif
alpha(p+1, value_type(0.0)),
beta(p+1, value_type(0.0)),
delta(p+1, value_type(0.0)),
gamma(p+1, value_type(0.0)),
norms(p+1, value_type(0.0))
{
}
template <typename ordinal_type, typename value_type>
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
RecurrenceBasis(ordinal_type p_, const RecurrenceBasis& basis) :
name(basis.name),
p(p_),
normalize(basis.normalize),
growth(basis.growth),
quad_zero_tol(basis.quad_zero_tol),
sparse_grid_growth_rule(basis.sparse_grid_growth_rule),
alpha(p+1, value_type(0.0)),
beta(p+1, value_type(0.0)),
delta(p+1, value_type(0.0)),
gamma(p+1, value_type(0.0)),
norms(p+1, value_type(0.0))
{
}
template <typename ordinal_type, typename value_type>
void
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
setup()
{
bool is_normalized =
computeRecurrenceCoefficients(p+1, alpha, beta, delta, gamma);
if (normalize && !is_normalized) {
normalizeRecurrenceCoefficients(alpha, beta, delta, gamma);
}
// Compute norms -- when polynomials are normalized, this should work
// out to one (norms[0] == 1, delta[k] == 1, beta[k] == gamma[k]
norms[0] = beta[0]/(gamma[0]*gamma[0]);
for (ordinal_type k=1; k<=p; k++) {
norms[k] = (beta[k]/gamma[k])*(delta[k-1]/delta[k])*norms[k-1];
}
}
template <typename ordinal_type, typename value_type>
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
~RecurrenceBasis()
{
}
template <typename ordinal_type, typename value_type>
ordinal_type
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
order() const
{
return p;
}
template <typename ordinal_type, typename value_type>
ordinal_type
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
size() const
{
return p+1;
}
template <typename ordinal_type, typename value_type>
const Teuchos::Array<value_type>&
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
norm_squared() const
{
return norms;
}
template <typename ordinal_type, typename value_type>
const value_type&
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
norm_squared(ordinal_type i) const
{
return norms[i];
}
template <typename ordinal_type, typename value_type>
Teuchos::RCP< Stokhos::Dense3Tensor<ordinal_type, value_type> >
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
computeTripleProductTensor() const
{
// Compute Cijk = < \Psi_i \Psi_j \Psi_k >
ordinal_type sz = size();
Teuchos::RCP< Stokhos::Dense3Tensor<ordinal_type, value_type> > Cijk =
Teuchos::rcp(new Dense3Tensor<ordinal_type, value_type>(sz));
Teuchos::Array<value_type> points, weights;
Teuchos::Array< Teuchos::Array<value_type> > values;
getQuadPoints(3*p, points, weights, values);
for (ordinal_type i=0; i<sz; i++) {
for (ordinal_type j=0; j<sz; j++) {
for (ordinal_type k=0; k<sz; k++) {
value_type triple_product = 0;
for (ordinal_type l=0; l<static_cast<ordinal_type>(points.size());
l++){
triple_product +=
weights[l]*(values[l][i])*(values[l][j])*(values[l][k]);
}
(*Cijk)(i,j,k) = triple_product;
}
}
}
return Cijk;
}
template <typename ordinal_type, typename value_type>
Teuchos::RCP< Stokhos::Sparse3Tensor<ordinal_type, value_type> >
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
computeSparseTripleProductTensor(ordinal_type theOrder) const
{
// Compute Cijk = < \Psi_i \Psi_j \Psi_k >
value_type sparse_tol = 1.0e-15;
ordinal_type sz = size();
Teuchos::RCP< Stokhos::Sparse3Tensor<ordinal_type, value_type> > Cijk =
Teuchos::rcp(new Sparse3Tensor<ordinal_type, value_type>());
Teuchos::Array<value_type> points, weights;
Teuchos::Array< Teuchos::Array<value_type> > values;
getQuadPoints(3*p, points, weights, values);
for (ordinal_type i=0; i<sz; i++) {
for (ordinal_type j=0; j<sz; j++) {
for (ordinal_type k=0; k<theOrder; k++) {
value_type triple_product = 0;
for (ordinal_type l=0; l<static_cast<ordinal_type>(points.size());
l++){
triple_product +=
weights[l]*(values[l][i])*(values[l][j])*(values[l][k]);
}
if (std::abs(triple_product/norms[i]) > sparse_tol)
Cijk->add_term(i,j,k,triple_product);
}
}
}
Cijk->fillComplete();
return Cijk;
}
template <typename ordinal_type, typename value_type>
Teuchos::RCP< Teuchos::SerialDenseMatrix<ordinal_type, value_type> >
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
computeDerivDoubleProductTensor() const
{
// Compute Bij = < \Psi_i' \Psi_j >
Teuchos::Array<value_type> points, weights;
Teuchos::Array< Teuchos::Array<value_type> > values, derivs;
getQuadPoints(2*p, points, weights, values);
ordinal_type nqp = weights.size();
derivs.resize(nqp);
ordinal_type sz = size();
for (ordinal_type i=0; i<nqp; i++) {
derivs[i].resize(sz);
evaluateBasesAndDerivatives(points[i], values[i], derivs[i]);
}
Teuchos::RCP< Teuchos::SerialDenseMatrix<ordinal_type, value_type> > Bij =
Teuchos::rcp(new Teuchos::SerialDenseMatrix<ordinal_type, value_type>(sz,sz));
for (ordinal_type i=0; i<sz; i++) {
for (ordinal_type j=0; j<sz; j++) {
value_type b = value_type(0.0);
for (int qp=0; qp<nqp; qp++)
b += weights[qp]*derivs[qp][i]*values[qp][j];
(*Bij)(i,j) = b;
}
}
return Bij;
}
template <typename ordinal_type, typename value_type>
void
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
evaluateBases(const value_type& x, Teuchos::Array<value_type>& basis_pts) const
{
// Evaluate basis polynomials P(x) using 3 term recurrence
// P_0(x) = 1/gamma[0], P_-1 = 0
// P_i(x) = [(delta[i-1]*x-alpha[i-1])*P_{i-1}(x) -
// beta[i-1]*P_{i-2}(x)]/gamma[i],
// i=2,3,...
basis_pts[0] = value_type(1)/gamma[0];
if (p >= 1)
basis_pts[1] = (delta[0]*x-alpha[0])*basis_pts[0]/gamma[1];
for (ordinal_type i=2; i<=p; i++)
basis_pts[i] = ((delta[i-1]*x-alpha[i-1])*basis_pts[i-1] -
beta[i-1]*basis_pts[i-2])/gamma[i];
}
template <typename ordinal_type, typename value_type>
void
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
evaluateBasesAndDerivatives(const value_type& x,
Teuchos::Array<value_type>& vals,
Teuchos::Array<value_type>& derivs) const
{
evaluateBases(x, vals);
derivs[0] = 0.0;
if (p >= 1)
derivs[1] = delta[0]/(gamma[0]*gamma[1]);
for (ordinal_type i=2; i<=p; i++)
derivs[i] = (delta[i-1]*vals[i-1] + (delta[i-1]*x-alpha[i-1])*derivs[i-1] -
beta[i-1]*derivs[i-2])/gamma[i];
}
template <typename ordinal_type, typename value_type>
value_type
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
evaluate(const value_type& x, ordinal_type k) const
{
// Evaluate basis polynomials P(x) using 3 term recurrence
// P_0(x) = 1/gamma[0], P_-1 = 0
// P_i(x) = [(delta[i-1]*x-alpha[i-1])*P_{i-1}(x) -
// beta[i-1]*P_{i-2}(x)]/gamma[i],
// i=2,3,...
value_type v0 = value_type(1.0)/gamma[0];
if (k == 0)
return v0;
value_type v1 = (x*delta[0]-alpha[0])*v0/gamma[1];
if (k == 1)
return v1;
value_type v2 = value_type(0.0);
for (ordinal_type i=2; i<=k; i++) {
v2 = ((delta[i-1]*x-alpha[i-1])*v1 - beta[i-1]*v0)/gamma[i];
v0 = v1;
v1 = v2;
}
return v2;
}
template <typename ordinal_type, typename value_type>
void
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
print(std::ostream& os) const
{
os << name << " basis of order " << p << "." << std::endl;
os << "Alpha recurrence coefficients:\n\t";
for (ordinal_type i=0; i<=p; i++)
os << alpha[i] << " ";
os << std::endl;
os << "Beta recurrence coefficients:\n\t";
for (ordinal_type i=0; i<=p; i++)
os << beta[i] << " ";
os << std::endl;
os << "Delta recurrence coefficients:\n\t";
for (ordinal_type i=0; i<=p; i++)
os << delta[i] << " ";
os << std::endl;
os << "Gamma recurrence coefficients:\n\t";
for (ordinal_type i=0; i<=p; i++)
os << gamma[i] << " ";
os << std::endl;
os << "Basis polynomial norms (squared):\n\t";
for (ordinal_type i=0; i<=p; i++)
os << norms[i] << " ";
os << std::endl;
}
template <typename ordinal_type, typename value_type>
const std::string&
Stokhos::RecurrenceBasis<ordinal_type, value_type>::
getName() const
{
return name;
}
template <typename ordinal_type, typename value_type>
void
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
getQuadPoints(ordinal_type quad_order,
Teuchos::Array<value_type>& quad_points,
Teuchos::Array<value_type>& quad_weights,
Teuchos::Array< Teuchos::Array<value_type> >& quad_values) const
{
//This is a transposition into C++ of Gautschi's code for taking the first
// N recurrance coefficient and generating a N point quadrature rule.
// The MATLAB version is available at
// http://www.cs.purdue.edu/archives/2002/wxg/codes/gauss.m
ordinal_type num_points =
static_cast<ordinal_type>(std::ceil((quad_order+1)/2.0));
Teuchos::Array<value_type> a(num_points,0);
Teuchos::Array<value_type> b(num_points,0);
Teuchos::Array<value_type> c(num_points,0);
Teuchos::Array<value_type> d(num_points,0);
// If we don't have enough recurrance coefficients, get some more.
if(num_points > p+1){
bool is_normalized = computeRecurrenceCoefficients(num_points, a, b, c, d);
if (!is_normalized)
normalizeRecurrenceCoefficients(a, b, c, d);
}
else { //else just take the ones we already have.
for(ordinal_type n = 0; n<num_points; n++){
a[n] = alpha[n];
b[n] = beta[n];
c[n] = delta[n];
d[n] = gamma[n];
}
if (!normalize)
normalizeRecurrenceCoefficients(a, b, c, d);
}
// With normalized coefficients, A is symmetric and tri-diagonal, with
// diagonal = a, and off-diagonal = b, starting at b[1]
Teuchos::SerialDenseMatrix<ordinal_type,value_type> eig_vectors(num_points,
num_points);
Teuchos::Array<value_type> workspace(2*num_points);
ordinal_type info_flag;
Teuchos::LAPACK<ordinal_type,value_type> my_lapack;
// compute the eigenvalues (stored in a) and right eigenvectors.
if (num_points == 1)
my_lapack.STEQR('I', num_points, &a[0], &b[0], eig_vectors.values(),
num_points, &workspace[0], &info_flag);
else
my_lapack.STEQR('I', num_points, &a[0], &b[1], eig_vectors.values(),
num_points, &workspace[0], &info_flag);
// eigenvalues are sorted by STEQR
quad_points.resize(num_points);
quad_weights.resize(num_points);
for (ordinal_type i=0; i<num_points; i++) {
quad_points[i] = a[i];
if (std::abs(quad_points[i]) < quad_zero_tol)
quad_points[i] = 0.0;
quad_weights[i] = beta[0]*eig_vectors[i][0]*eig_vectors[i][0];
}
// Evalute basis at gauss points
quad_values.resize(num_points);
for (ordinal_type i=0; i<num_points; i++) {
quad_values[i].resize(p+1);
evaluateBases(quad_points[i], quad_values[i]);
}
}
template <typename ordinal_type, typename value_type>
ordinal_type
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
quadDegreeOfExactness(ordinal_type n) const
{
return ordinal_type(2)*n-ordinal_type(1);
}
template <typename ordinal_type, typename value_type>
ordinal_type
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
coefficientGrowth(ordinal_type n) const
{
if (growth == SLOW_GROWTH)
return n;
// else moderate
return ordinal_type(2)*n;
}
template <typename ordinal_type, typename value_type>
ordinal_type
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
pointGrowth(ordinal_type n) const
{
if (growth == SLOW_GROWTH) {
if (n % ordinal_type(2) == ordinal_type(1))
return n + ordinal_type(1);
else
return n;
}
// else moderate
return n;
}
template <typename ordinal_type, typename value_type>
void
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
getRecurrenceCoefficients(Teuchos::Array<value_type>& a,
Teuchos::Array<value_type>& b,
Teuchos::Array<value_type>& c,
Teuchos::Array<value_type>& g) const
{
a = alpha;
b = beta;
c = delta;
g = gamma;
}
template <typename ordinal_type, typename value_type>
void
Stokhos::RecurrenceBasis<ordinal_type,value_type>::
normalizeRecurrenceCoefficients(
Teuchos::Array<value_type>& a,
Teuchos::Array<value_type>& b,
Teuchos::Array<value_type>& c,
Teuchos::Array<value_type>& g) const
{
ordinal_type n = a.size();
a[0] = a[0] / c[0];
b[0] = std::sqrt(b[0]);
g[0] = b[0];
for (ordinal_type k=1; k<n; k++) {
a[k] = a[k] / c[k];
b[k] = std::sqrt((b[k]*g[k])/(c[k]*c[k-1]));
g[k] = b[k];
}
for (ordinal_type k=0; k<n; k++)
c[k] = value_type(1);
}
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