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/*
* Computations of Scalar partial derivatives for a Map_log mapping
*/
/*
* Copyright (c) 2004 Philippe Grandclement
*
* This file is part of LORENE.
*
* LORENE is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* LORENE is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with LORENE; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
char map_log_deriv_C[] = "$Header: /cvsroot/Lorene/C++/Source/Map/map_log_deriv.C,v 1.3 2014/10/13 08:53:05 j_novak Exp $" ;
/*
* $Id: map_log_deriv.C,v 1.3 2014/10/13 08:53:05 j_novak Exp $
* $Log: map_log_deriv.C,v $
* Revision 1.3 2014/10/13 08:53:05 j_novak
* Lorene classes and functions now belong to the namespace Lorene.
*
* Revision 1.2 2012/01/17 10:33:43 j_penner
* added a derivative with respect to the computational coordinate xi
*
* Revision 1.1 2004/06/22 08:49:58 p_grandclement
* Addition of everything needed for using the logarithmic mapping
*
*
* $Header: /cvsroot/Lorene/C++/Source/Map/map_log_deriv.C,v 1.3 2014/10/13 08:53:05 j_novak Exp $
*
*/
// Header Lorene
#include "map.h"
#include "tensor.h"
//---------------------------------------------------
// d/d\xi
//---------------------------------------------------
namespace Lorene {
void Map_log::dsdxi(const Scalar& uu, Scalar& resu) const {
assert (uu.get_etat() != ETATNONDEF) ;
assert (uu.get_mp().get_mg() == mg) ;
if (uu.get_etat() == ETATZERO) {
resu.set_etat_zero() ;
}
else {
assert( uu.get_etat() == ETATQCQ ) ;
const Valeur& uuva = uu.get_spectral_va() ;
uuva.coef() ; // (uu.va).c_cf is up to date
int nz = mg->get_nzone() ;
int nzm1 = nz - 1 ;
if ( uu.get_dzpuis() == 0 ) {
resu = uuva.dsdx() ; // dsdx == d/d\xi
if (mg->get_type_r(nzm1) == UNSURR) {
resu.set_dzpuis(2) ; // r^2 d/dr has been computed in the
// external domain
}
}
else {
assert(mg->get_type_r(nzm1) == UNSURR) ;
int dzp = uu.get_dzpuis() ;
resu = uuva.dsdx() ;
resu.annule_domain(nzm1) ; // zero in the CED
// Special treatment in the CED
Valeur tmp_ced = - uuva.dsdx() ;
tmp_ced.annule(0, nz-2) ; // only non zero in the CED
tmp_ced.mult_xm1_zec() ;
tmp_ced.set(nzm1) -= dzp * uuva(nzm1) ;
// Recombination shells + CED :
resu.set_spectral_va() += tmp_ced ;
resu.set_dzpuis(dzp+1) ;
}
resu.set_spectral_base( uuva.dsdx().get_base() ) ; // same basis as d/dxi
}
}
//---------------------------------------------------
// Derivee standard par rapport au "vrai" rayon .....
//---------------------------------------------------
void Map_log::dsdr(const Scalar& uu, Scalar& resu) const {
assert (uu.get_etat() != ETATNONDEF) ;
assert (uu.get_mp().get_mg() == mg) ;
if (uu.get_etat() == ETATZERO) {
resu.set_etat_zero() ;
}
else {
assert( uu.get_etat() == ETATQCQ ) ;
const Valeur& uuva = uu.get_spectral_va() ;
uuva.coef() ; // (uu.va).c_cf is up to date
int nz = mg->get_nzone() ;
int nzm1 = nz - 1 ;
if ( uu.get_dzpuis() == 0 ) {
resu = uuva.dsdx() * dxdr ; // dxdr = dxi/dR, - dxi/dU (ZEC)
if (mg->get_type_r(nzm1) == UNSURR) {
resu.set_dzpuis(2) ; // r^2 d/dr has been computed in the
// external domain
}
}
else {
assert(mg->get_type_r(nzm1) == UNSURR) ;
int dzp = uu.get_dzpuis() ;
resu = uuva.dsdx() * dxdr ;
resu.annule_domain(nzm1) ; // zero in the CED
// Special treatment in the CED
Valeur tmp_ced = - uuva.dsdx() ;
tmp_ced.annule(0, nz-2) ; // only non zero in the CED
tmp_ced.mult_xm1_zec() ;
tmp_ced.set(nzm1) -= dzp * uuva(nzm1) ;
// Recombination shells + CED :
resu.set_spectral_va() += tmp_ced ;
resu.set_dzpuis(dzp+1) ;
}
resu.set_spectral_base( uuva.dsdx().get_base() ) ; // same basis as d/dxi
}
}
//---------------------------------------------------
// Derivee par rapport au rayon numerique (r ou lnr)
//---------------------------------------------------
void Map_log::dsdradial (const Scalar& uu, Scalar& resu) const {
assert (uu.get_etat() != ETATNONDEF) ;
assert (uu.get_mp().get_mg() == mg) ;
if (uu.get_etat() == ETATZERO) {
resu.set_etat_zero() ;
}
else {
assert( uu.get_etat() == ETATQCQ ) ;
const Valeur& uuva = uu.get_spectral_va() ;
uuva.coef() ; // (uu.va).c_cf is up to date
int nz = mg->get_nzone() ;
int nzm1 = nz - 1 ;
if ( uu.get_dzpuis() == 0 ) {
resu = uuva.dsdx() * dxdlnr ; // dxdr = dxi/dR, - dxi/dU (ZEC)
if (mg->get_type_r(nzm1) == UNSURR) {
resu.set_dzpuis(2) ; // r^2 d/dr has been computed in the
// external domain
}
}
else {
assert(mg->get_type_r(nzm1) == UNSURR) ;
int dzp = uu.get_dzpuis() ;
resu = uuva.dsdx() * dxdlnr ;
resu.annule_domain(nzm1) ; // zero in the CED
// Special treatment in the CED
Valeur tmp_ced = - uuva.dsdx() ;
tmp_ced.annule(0, nz-2) ; // only non zero in the CED
tmp_ced.mult_xm1_zec() ;
tmp_ced.set(nzm1) -= dzp * uuva(nzm1) ;
// Recombination shells + CED :
resu.set_spectral_va() += tmp_ced ;
resu.set_dzpuis(dzp+1) ;
}
resu.set_spectral_base( uuva.dsdx().get_base() ) ; // same basis as d/dxi
}
}
}
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