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///////////////////////////////////////////////////////////////////////////////
//
// File: Intrepid_Polylib.hpp
//
// For more information, please see: http://www.nektar.info
//
// The MIT License
//
// Copyright (c) 2006 Division of Applied Mathematics, Brown University (USA),
// Department of Aeronautics, Imperial College London (UK), and Scientific
// Computing and Imaging Institute, University of Utah (USA).
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// Description:
// This file is redistributed with the Intrepid package. It should be used
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// This file is NOT covered by the usual Intrepid/Trilinos LGPL license.
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// Origin: Nektar++ library, http://www.nektar.info, downloaded on
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///////////////////////////////////////////////////////////////////////////////
/** \file Intrepid_Polylib.hpp
\brief Header file for a set of functions providing orthogonal polynomial
polynomial calculus and interpolation.
\author Created by Spencer Sherwin, Aeronautics, Imperial College London,
modified and redistributed by D. Ridzal.
*/
#ifndef INTREPID_POLYLIB_HPP
#define INTREPID_POLYLIB_HPP
#include "Intrepid_ConfigDefs.hpp"
#include "Intrepid_Types.hpp"
#include "Teuchos_Assert.hpp"
namespace Intrepid {
/**
\page pagePolylib The Polylib library
\section sectionPolyLib Routines For Orthogonal Polynomial Calculus and Interpolation
Spencer Sherwin,
Aeronautics, Imperial College London
Based on codes by Einar Ronquist and Ron Henderson
Abbreviations
- z - Set of collocation/quadrature points
- w - Set of quadrature weights
- D - Derivative matrix
- h - Lagrange Interpolant
- I - Interpolation matrix
- g - Gauss
- gr - Gauss-Radau
- gl - Gauss-Lobatto
- j - Jacobi
- m - point at minus 1 in Radau rules
- p - point at plus 1 in Radau rules
-----------------------------------------------------------------------\n
MAIN ROUTINES\n
-----------------------------------------------------------------------\n
Points and Weights:
- zwgj Compute Gauss-Jacobi points and weights
- zwgrjm Compute Gauss-Radau-Jacobi points and weights (z=-1)
- zwgrjp Compute Gauss-Radau-Jacobi points and weights (z= 1)
- zwglj Compute Gauss-Lobatto-Jacobi points and weights
Derivative Matrices:
- Dgj Compute Gauss-Jacobi derivative matrix
- Dgrjm Compute Gauss-Radau-Jacobi derivative matrix (z=-1)
- Dgrjp Compute Gauss-Radau-Jacobi derivative matrix (z= 1)
- Dglj Compute Gauss-Lobatto-Jacobi derivative matrix
Lagrange Interpolants:
- hgj Compute Gauss-Jacobi Lagrange interpolants
- hgrjm Compute Gauss-Radau-Jacobi Lagrange interpolants (z=-1)
- hgrjp Compute Gauss-Radau-Jacobi Lagrange interpolants (z= 1)
- hglj Compute Gauss-Lobatto-Jacobi Lagrange interpolants
Interpolation Operators:
- Imgj Compute interpolation operator gj->m
- Imgrjm Compute interpolation operator grj->m (z=-1)
- Imgrjp Compute interpolation operator grj->m (z= 1)
- Imglj Compute interpolation operator glj->m
Polynomial Evaluation:
- jacobfd Returns value and derivative of Jacobi poly. at point z
- jacobd Returns derivative of Jacobi poly. at point z (valid at z=-1,1)
-----------------------------------------------------------------------\n
LOCAL ROUTINES\n
-----------------------------------------------------------------------\n
- jacobz Returns Jacobi polynomial zeros
- gammaf Gamma function for integer values and halves
------------------------------------------------------------------------\n
Useful references:
- [1] Gabor Szego: Orthogonal Polynomials, American Mathematical Society,
Providence, Rhode Island, 1939.
- [2] Abramowitz \& Stegun: Handbook of Mathematical Functions,
Dover, New York, 1972.
- [3] Canuto, Hussaini, Quarteroni \& Zang: Spectral Methods in Fluid
Dynamics, Springer-Verlag, 1988.
- [4] Ghizzetti \& Ossicini: Quadrature Formulae, Academic Press, 1970.
- [5] Karniadakis \& Sherwin: Spectral/hp element methods for CFD, 1999
NOTES
-# Legendre polynomial \f$ \alpha = \beta = 0 \f$
-# Chebychev polynomial \f$ \alpha = \beta = -0.5 \f$
-# All array subscripts start from zero, i.e. vector[0..N-1]
*/
/** \enum Intrepid::EIntrepidPLPoly
\brief Enumeration of coordinate frames (reference/ambient) for geometrical entities (cells, points).
*/
enum EIntrepidPLPoly {
PL_GAUSS=0,
PL_GAUSS_RADAU_LEFT,
PL_GAUSS_RADAU_RIGHT,
PL_GAUSS_LOBATTO,
PL_MAX
};
inline EIntrepidPLPoly & operator++(EIntrepidPLPoly &type) {
return type = static_cast<EIntrepidPLPoly>(type+1);
}
inline EIntrepidPLPoly operator++(EIntrepidPLPoly &type, int) {
EIntrepidPLPoly oldval = type;
++type;
return oldval;
}
/** \class Intrepid::IntrepidPolylib
\brief Providing orthogonal polynomial calculus and interpolation,
created by Spencer Sherwin, Aeronautics, Imperial College London,
modified and redistributed by D. Ridzal.
See \ref pagePolylib "original Polylib documentation".
*/
class IntrepidPolylib {
public:
/* Points and weights */
/** \brief Gauss-Jacobi zeros and weights.
\li Generate \a np Gauss Jacobi zeros, \a z, and weights,\a w,
associated with the Jacobi polynomial \f$ P^{\alpha,\beta}_{np}(z)\f$,
\li Exact for polynomials of order \a 2np-1 or less
*/
template<class Scalar>
static void zwgj (Scalar *z, Scalar *w, const int np, const Scalar alpha, const Scalar beta);
/** \brief Gauss-Radau-Jacobi zeros and weights with end point at \a z=-1.
\li Generate \a np Gauss-Radau-Jacobi zeros, \a z, and weights,\a w,
associated with the polynomial \f$(1+z) P^{\alpha,\beta+1}_{np-1}(z)\f$.
\li Exact for polynomials of order \a 2np-2 or less
*/
template<class Scalar>
static void zwgrjm (Scalar *z, Scalar *w, const int np, const Scalar alpha, const Scalar beta);
/** \brief Gauss-Radau-Jacobi zeros and weights with end point at \a z=1
\li Generate \a np Gauss-Radau-Jacobi zeros, \a z, and weights,\a w,
associated with the polynomial \f$(1-z) P^{\alpha+1,\beta}_{np-1}(z)\f$.
\li Exact for polynomials of order \a 2np-2 or less
*/
template<class Scalar>
static void zwgrjp (Scalar *z, Scalar *w, const int np, const Scalar alpha, const Scalar beta);
/** \brief Gauss-Lobatto-Jacobi zeros and weights with end point at \a z=-1,\a 1
\li Generate \a np Gauss-Lobatto-Jacobi points, \a z, and weights, \a w,
associated with polynomial \f$ (1-z)(1+z) P^{\alpha+1,\beta+1}_{np-2}(z) \f$
\li Exact for polynomials of order \a 2np-3 or less
*/
template<class Scalar>
static void zwglj (Scalar *z, Scalar *w, const int np, const Scalar alpha, const Scalar beta);
/* Derivative operators */
/** \brief Compute the Derivative Matrix and its transpose associated
with the Gauss-Jacobi zeros.
\li Compute the derivative matrix \a D associated with the n_th order Lagrangian
interpolants through the \a np Gauss-Jacobi points \a z such that \n
\f$ \frac{du}{dz}(z[i]) = \sum_{j=0}^{np-1} D[i*np+j] u(z[j]) \f$
*/
template<class Scalar>
static void Dgj (Scalar *D, const Scalar *z, const int np, const Scalar alpha, const Scalar beta);
/** \brief Compute the Derivative Matrix and its transpose associated
with the Gauss-Radau-Jacobi zeros with a zero at \a z=-1.
\li Compute the derivative matrix \a D associated with the n_th
order Lagrangian interpolants through the \a np Gauss-Radau-Jacobi
points \a z such that \n \f$ \frac{du}{dz}(z[i]) =
\sum_{j=0}^{np-1} D[i*np+j] u(z[j]) \f$
*/
template<class Scalar>
static void Dgrjm (Scalar *D, const Scalar *z, const int np, const Scalar alpha, const Scalar beta);
/** \brief Compute the Derivative Matrix associated with the
Gauss-Radau-Jacobi zeros with a zero at \a z=1.
\li Compute the derivative matrix \a D associated with the n_th
order Lagrangian interpolants through the \a np Gauss-Radau-Jacobi
points \a z such that \n \f$ \frac{du}{dz}(z[i]) =
\sum_{j=0}^{np-1} D[i*np+j] u(z[j]) \f$
*/
template<class Scalar>
static void Dgrjp (Scalar *D, const Scalar *z, const int np, const Scalar alpha, const Scalar beta);
/** \brief Compute the Derivative Matrix associated with the
Gauss-Lobatto-Jacobi zeros.
\li Compute the derivative matrix \a D associated with the n_th
order Lagrange interpolants through the \a np
Gauss-Lobatto-Jacobi points \a z such that \n \f$
\frac{du}{dz}(z[i]) = \sum_{j=0}^{np-1} D[i*np+j] u(z[j]) \f$
*/
template<class Scalar>
static void Dglj (Scalar *D, const Scalar *z, const int np, const Scalar alpha, const Scalar beta);
/* Lagrangian interpolants */
/** \brief Compute the value of the \a i th Lagrangian interpolant through
the \a np Gauss-Jacobi points \a zgj at the arbitrary location \a z.
\li \f$ -1 \leq z \leq 1 \f$
\li Uses the defintion of the Lagrangian interpolant:\n
\f$
\begin{array}{rcl}
h_j(z) = \left\{ \begin{array}{ll}
\displaystyle \frac{P_{np}^{\alpha,\beta}(z)}
{[P_{np}^{\alpha,\beta}(z_j)]^\prime
(z-z_j)} & \mbox{if $z \ne z_j$}\\
& \\
1 & \mbox{if $z=z_j$}
\end{array}
\right.
\end{array}
\f$
*/
template<class Scalar>
static Scalar hgj (const int i, const Scalar z, const Scalar *zgj,
const int np, const Scalar alpha, const Scalar beta);
/** \brief Compute the value of the \a i th Lagrangian interpolant through the
\a np Gauss-Radau-Jacobi points \a zgrj at the arbitrary location
\a z. This routine assumes \a zgrj includes the point \a -1.
\li \f$ -1 \leq z \leq 1 \f$
\li Uses the defintion of the Lagrangian interpolant:\n
%
\f$ \begin{array}{rcl}
h_j(z) = \left\{ \begin{array}{ll}
\displaystyle \frac{(1+z) P_{np-1}^{\alpha,\beta+1}(z)}
{((1+z_j) [P_{np-1}^{\alpha,\beta+1}(z_j)]^\prime +
P_{np-1}^{\alpha,\beta+1}(z_j) ) (z-z_j)} & \mbox{if $z \ne z_j$}\\
& \\
1 & \mbox{if $z=z_j$}
\end{array}
\right.
\end{array} \f$
*/
template<class Scalar>
static Scalar hgrjm (const int i, const Scalar z, const Scalar *zgrj,
const int np, const Scalar alpha, const Scalar beta);
/** \brief Compute the value of the \a i th Lagrangian interpolant through the
\a np Gauss-Radau-Jacobi points \a zgrj at the arbitrary location
\a z. This routine assumes \a zgrj includes the point \a +1.
\li \f$ -1 \leq z \leq 1 \f$
\li Uses the defintion of the Lagrangian interpolant:\n
%
\f$ \begin{array}{rcl}
h_j(z) = \left\{ \begin{array}{ll}
\displaystyle \frac{(1-z) P_{np-1}^{\alpha+1,\beta}(z)}
{((1-z_j) [P_{np-1}^{\alpha+1,\beta}(z_j)]^\prime -
P_{np-1}^{\alpha+1,\beta}(z_j) ) (z-z_j)} & \mbox{if $z \ne z_j$}\\
& \\
1 & \mbox{if $z=z_j$}
\end{array}
\right.
\end{array} \f$
*/
template<class Scalar>
static Scalar hgrjp (const int i, const Scalar z, const Scalar *zgrj,
const int np, const Scalar alpha, const Scalar beta);
/** \brief Compute the value of the \a i th Lagrangian interpolant through the
\a np Gauss-Lobatto-Jacobi points \a zglj at the arbitrary location
\a z.
\li \f$ -1 \leq z \leq 1 \f$
\li Uses the defintion of the Lagrangian interpolant:\n
%
\f$ \begin{array}{rcl}
h_j(z) = \left\{ \begin{array}{ll}
\displaystyle \frac{(1-z^2) P_{np-2}^{\alpha+1,\beta+1}(z)}
{((1-z^2_j) [P_{np-2}^{\alpha+1,\beta+1}(z_j)]^\prime -
2 z_j P_{np-2}^{\alpha+1,\beta+1}(z_j) ) (z-z_j)}&\mbox{if $z \ne z_j$}\\
& \\
1 & \mbox{if $z=z_j$}
\end{array}
\right.
\end{array} \f$
*/
template<class Scalar>
static Scalar hglj (const int i, const Scalar z, const Scalar *zglj,
const int np, const Scalar alpha, const Scalar beta);
/* Interpolation operators */
/** \brief Interpolation Operator from Gauss-Jacobi points to an
arbitrary distribution at points \a zm
\li Computes the one-dimensional interpolation matrix, \a im, to
interpolate a function from at Gauss-Jacobi distribution of \a nz
zeros \a zgj to an arbitrary distribution of \a mz points \a zm, i.e.\n
\f$
u(zm[i]) = \sum_{j=0}^{nz-1} im[i*nz+j] \ u(zgj[j])
\f$
*/
template<class Scalar>
static void Imgj (Scalar *im, const Scalar *zgj, const Scalar *zm, const int nz,
const int mz, const Scalar alpha, const Scalar beta);
/** \brief Interpolation Operator from Gauss-Radau-Jacobi points
(including \a z=-1) to an arbitrary distrubtion at points \a zm
\li Computes the one-dimensional interpolation matrix, \a im, to
interpolate a function from at Gauss-Radau-Jacobi distribution of
\a nz zeros \a zgrj (where \a zgrj[0]=-1) to an arbitrary
distribution of \a mz points \a zm, i.e.
\n
\f$ u(zm[i]) = \sum_{j=0}^{nz-1} im[i*nz+j] \ u(zgrj[j]) \f$
*/
template<class Scalar>
static void Imgrjm(Scalar *im, const Scalar *zgrj, const Scalar *zm, const int nz,
const int mz, const Scalar alpha, const Scalar beta);
/** \brief Interpolation Operator from Gauss-Radau-Jacobi points
(including \a z=1) to an arbitrary distrubtion at points \a zm
\li Computes the one-dimensional interpolation matrix, \a im, to
interpolate a function from at Gauss-Radau-Jacobi distribution of
\a nz zeros \a zgrj (where \a zgrj[nz-1]=1) to an arbitrary
distribution of \a mz points \a zm, i.e.
\n
\f$ u(zm[i]) = \sum_{j=0}^{nz-1} im[i*nz+j] \ u(zgrj[j]) \f$
*/
template<class Scalar>
static void Imgrjp(Scalar *im, const Scalar *zgrj, const Scalar *zm, const int nz,
const int mz, const Scalar alpha, const Scalar beta);
/** \brief Interpolation Operator from Gauss-Lobatto-Jacobi points
to an arbitrary distrubtion at points \a zm
\li Computes the one-dimensional interpolation matrix, \a im, to
interpolate a function from at Gauss-Lobatto-Jacobi distribution of
\a nz zeros \a zglj (where \a zglj[0]=-1 , \a zglj[nz-1]=1) to an arbitrary
distribution of \a mz points \a zm, i.e.
\n
\f$ u(zm[i]) = \sum_{j=0}^{nz-1} im[i*nz+j] \ u(zglj[j]) \f$
*/
template<class Scalar>
static void Imglj (Scalar *im, const Scalar *zglj, const Scalar *zm, const int nz,
const int mz, const Scalar alpha, const Scalar beta);
/* Polynomial functions */
/** \brief Routine to calculate Jacobi polynomials, \f$
P^{\alpha,\beta}_n(z) \f$, and their first derivative, \f$
\frac{d}{dz} P^{\alpha,\beta}_n(z) \f$.
\li This function returns the vectors \a poly_in and \a poly_d
containing the value of the \a n-th order Jacobi polynomial
\f$ P^{\alpha,\beta}_n(z) \alpha > -1, \beta > -1 \f$ and its
derivative at the \a np points in \a z[i]
- If \a poly_in = NULL then only calculate derivative
- If \a polyd = NULL then only calculate polynomial
- To calculate the polynomial this routine uses the recursion
relationship (see appendix A ref [4]) :
\f$ \begin{array}{rcl}
P^{\alpha,\beta}_0(z) &=& 1 \\
P^{\alpha,\beta}_1(z) &=& \frac{1}{2} [ \alpha-\beta+(\alpha+\beta+2)z] \\
a^1_n P^{\alpha,\beta}_{n+1}(z) &=& (a^2_n + a^3_n z)
P^{\alpha,\beta}_n(z) - a^4_n P^{\alpha,\beta}_{n-1}(z) \\
a^1_n &=& 2(n+1)(n+\alpha + \beta + 1)(2n + \alpha + \beta) \\
a^2_n &=& (2n + \alpha + \beta + 1)(\alpha^2 - \beta^2) \\
a^3_n &=& (2n + \alpha + \beta)(2n + \alpha + \beta + 1)
(2n + \alpha + \beta + 2) \\
a^4_n &=& 2(n+\alpha)(n+\beta)(2n + \alpha + \beta + 2)
\end{array} \f$
- To calculate the derivative of the polynomial this routine uses
the relationship (see appendix A ref [4]) :
\f$ \begin{array}{rcl}
b^1_n(z)\frac{d}{dz} P^{\alpha,\beta}_n(z)&=&b^2_n(z)P^{\alpha,\beta}_n(z)
+ b^3_n(z) P^{\alpha,\beta}_{n-1}(z) \hspace{2.2cm} \\
b^1_n(z) &=& (2n+\alpha + \beta)(1-z^2) \\
b^2_n(z) &=& n[\alpha - \beta - (2n+\alpha + \beta)z]\\
b^3_n(z) &=& 2(n+\alpha)(n+\beta)
\end{array} \f$
- Note the derivative from this routine is only valid for -1 < \a z < 1.
*/
template<class Scalar>
static void jacobfd (const int np, const Scalar *z, Scalar *poly_in, Scalar *polyd,
const int n, const Scalar alpha, const Scalar beta);
/** \brief Calculate the derivative of Jacobi polynomials
\li Generates a vector \a poly of values of the derivative of the
\a n-th order Jacobi polynomial \f$ P^(\alpha,\beta)_n(z)\f$ at the
\a np points \a z.
\li To do this we have used the relation
\n
\f$ \frac{d}{dz} P^{\alpha,\beta}_n(z)
= \frac{1}{2} (\alpha + \beta + n + 1) P^{\alpha,\beta}_n(z) \f$
\li This formulation is valid for \f$ -1 \leq z \leq 1 \f$
*/
template<class Scalar>
static void jacobd (const int np, const Scalar *z, Scalar *polyd, const int n,
const Scalar alpha, const Scalar beta);
/* Helper functions. */
/** \brief Calculate the \a n zeros, \a z, of the Jacobi polynomial, i.e.
\f$ P_n^{\alpha,\beta}(z) = 0 \f$
This routine is only valid for \f$( \alpha > -1, \beta > -1)\f$
and uses polynomial deflation in a Newton iteration
*/
template<class Scalar>
static void Jacobz (const int n, Scalar *z, const Scalar alpha, const Scalar beta);
/** \brief Zero determination through the eigenvalues of a tridiagonal
matrix from the three term recursion relationship.
Set up a symmetric tridiagonal matrix
\f$ \left [ \begin{array}{ccccc}
a[0] & b[0] & & & \\
b[0] & a[1] & b[1] & & \\
0 & \ddots & \ddots & \ddots & \\
& & \ddots & \ddots & b[n-2] \\
& & & b[n-2] & a[n-1] \end{array} \right ] \f$
Where the coefficients a[n], b[n] come from the recurrence relation
\f$ b_j p_j(z) = (z - a_j ) p_{j-1}(z) - b_{j-1} p_{j-2}(z) \f$
where \f$ j=n+1\f$ and \f$p_j(z)\f$ are the Jacobi (normalized)
orthogonal polynomials \f$ \alpha,\beta > -1\f$( integer values and
halves). Since the polynomials are orthonormalized, the tridiagonal
matrix is guaranteed to be symmetric. The eigenvalues of this
matrix are the zeros of the Jacobi polynomial.
*/
template<class Scalar>
static void JacZeros (const int n, Scalar *a, const Scalar alpha, const Scalar beta);
/** \brief QL algorithm for symmetric tridiagonal matrix
This subroutine is a translation of an algol procedure,
num. math. \b 12, 377-383(1968) by martin and wilkinson, as modified
in num. math. \b 15, 450(1970) by dubrulle. Handbook for
auto. comp., vol.ii-linear algebra, 241-248(1971). This is a
modified version from numerical recipes.
This subroutine finds the eigenvalues and first components of the
eigenvectors of a symmetric tridiagonal matrix by the implicit QL
method.
on input:
- n is the order of the matrix;
- d contains the diagonal elements of the input matrix;
- e contains the subdiagonal elements of the input matrix
in its first n-1 positions. e(n) is arbitrary;
on output:
- d contains the eigenvalues in ascending order.
- e has been destroyed;
*/
template<class Scalar>
static void TriQL (const int n, Scalar *d, Scalar *e);
/** \brief Calculate the Gamma function , \f$ \Gamma(x)\f$, for integer
values \a x and halves.
Determine the value of \f$\Gamma(x)\f$ using:
\f$ \Gamma(x) = (x-1)! \mbox{ or } \Gamma(x+1/2) = (x-1/2)\Gamma(x-1/2)\f$
where \f$ \Gamma(1/2) = \sqrt{\pi}\f$
*/
template<class Scalar>
static Scalar gammaF (const Scalar x);
}; // class IntrepidPolylib
} // end of Intrepid namespace
// include templated definitions
#include <Intrepid_PolylibDef.hpp>
#endif
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