mirror of
https://github.com/triqs/dft_tools
synced 2024-11-01 11:43:47 +01:00
186 lines
7.6 KiB
C++
186 lines
7.6 KiB
C++
/*******************************************************************************
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*
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* TRIQS: a Toolbox for Research in Interacting Quantum Systems
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*
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* Copyright (C) 2011 by M. Ferrero, O. Parcollet
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*
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* TRIQS is free software: you can redistribute it and/or modify it under the
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* terms of the GNU General Public License as published by the Free Software
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* Foundation, either version 3 of the License, or (at your option) any later
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* version.
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*
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* TRIQS is distributed in the hope that it will be useful, but WITHOUT ANY
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* WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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* FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
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* details.
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*
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* You should have received a copy of the GNU General Public License along with
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* TRIQS. If not, see <http://www.gnu.org/licenses/>.
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*
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******************************************************************************/
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#include "fourier_matsubara.hpp"
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#include <fftw3.h>
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namespace triqs { namespace gfs {
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namespace impl_local_matsubara {
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inline dcomplex oneFermion(dcomplex a,double b,double tau,double beta) {
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return -a*( b >=0 ? exp(-b*tau)/(1+exp(-beta*b)) : exp(b*(beta-tau))/(1+exp(beta*b)) );
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}
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inline dcomplex oneBoson(dcomplex a,double b,double tau,double beta) {
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return a*( b >=0 ? exp(-b*tau)/(exp(-beta*b)-1) : exp(b*(beta-tau))/(1-exp(b*beta)) );
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}
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}
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template<typename GfElementType> GfElementType convert_green ( dcomplex const& x) { return x;}
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template<> double convert_green<double> ( dcomplex const& x) { return real(x);}
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//--------------------------------------------------------------------------------------
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struct impl_worker {
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tqa::vector<dcomplex> g_in, g_out;
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void direct (gf_view<imfreq,scalar_valued> gw, gf_view<imtime,scalar_valued> const gt) {
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using namespace impl_local_matsubara;
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auto ta = gt(freq_infty());
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//TO BE MODIFIED AFTER SCALAR IMPLEMENTATION TODO
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dcomplex d= ta(1)(0,0), A= ta.get_or_zero(2)(0,0), B = ta.get_or_zero(3)(0,0);
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double b1=0, b2=0, b3=0;
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dcomplex a1, a2, a3;
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double beta=gt.mesh().domain().beta;
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auto L = ( gt.mesh().kind() == full_bins ? gt.mesh().size()-1 : gt.mesh().size());
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double fact= beta/ gt.mesh().size();
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dcomplex iomega = dcomplex(0.0,1.0) * std::acos(-1) / beta;
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dcomplex iomega2 = iomega * 2 * gt.mesh().delta() * ( gt.mesh().kind() == half_bins ? 0.5 : 0.0);
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g_in.resize(gt.mesh().size());
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g_out.resize(gw.mesh().size());
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if (gw.domain().statistic == Fermion){
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b1 = 0; b2 =1; b3 =-1;
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a1 = d-B; a2 = (A+B)/2; a3 = (B-A)/2;
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}
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else {
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b1 = -0.5; b2 =-1; b3 =1;
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a1 = 4*(d-B)/3; a2 = B-(d+A)/2; a3 = d/6+A/2+B/3;
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}
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if (gw.domain().statistic == Fermion){
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for (auto & t : gt.mesh())
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g_in[t.index()] = fact * exp(iomega*t) * ( gt[t] - ( oneFermion(a1,b1,t,beta) + oneFermion(a2,b2,t,beta)+ oneFermion(a3,b3,t,beta) ) );
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}
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else {
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for (auto & t : gt.mesh())
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g_in[t.index()] = fact * ( gt[t] - ( oneBoson(a1,b1,t,beta) + oneBoson(a2,b2,t,beta) + oneBoson(a3,b3,t,beta) ) );
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}
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details::fourier_base(g_in, g_out, L, true);
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for (auto & w : gw.mesh()) {
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gw[w] = g_out( w.index() ) * exp(iomega2*w.index() ) + a1/(w-b1) + a2/(w-b2) + a3/(w-b3);
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}
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gw.singularity() = gt.singularity();// set tail
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}
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void inverse(gf_view<imtime,scalar_valued> gt, gf_view<imfreq,scalar_valued> const gw){
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using namespace impl_local_matsubara;
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static bool Green_Function_Are_Complex_in_time = false;
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// If the Green function are NOT complex, then one use the symmetry property
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// fold the sum and get a factor 2
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auto ta = gw(freq_infty());
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//TO BE MODIFIED AFTER SCALAR IMPLEMENTATION TODO
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dcomplex d= ta(1)(0,0), A= ta.get_or_zero(2)(0,0), B = ta.get_or_zero(3)(0,0);
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double b1, b2, b3;
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dcomplex a1, a2, a3;
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double beta=gw.domain().beta;
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size_t L= gt.mesh().size() - ( gt.mesh().kind() == full_bins ? 1 : 0); //L can be different from gt.mesh().size() (depending on the mesh kind) and is given to the FFT algorithm
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dcomplex iomega = dcomplex(0.0,1.0) * std::acos(-1) / beta;
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dcomplex iomega2 = -iomega * 2 * gt.mesh().delta() * (gt.mesh().kind() == half_bins ? 0.5 : 0.0) ;
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double fact = (Green_Function_Are_Complex_in_time ? 1 : 2)/beta;
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g_in.resize( gw.mesh().size());
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g_out.resize(gt.mesh().size());
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if (gw.domain().statistic == Fermion){
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b1 = 0; b2 =1; b3 =-1;
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a1 = d-B; a2 = (A+B)/2; a3 = (B-A)/2;
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}
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else {
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b1 = -0.5; b2 =-1; b3 =1;
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a1=4*(d-B)/3; a2=B-(d+A)/2; a3=d/6+A/2+B/3;
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}
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g_in() = 0;
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for (auto & w: gw.mesh()) {
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g_in[ w.index() ] = fact * exp(w.index()*iomega2) * ( gw[w] - (a1/(w-b1) + a2/(w-b2) + a3/(w-b3)) );
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}
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// for bosons GF(w=0) is divided by 2 to avoid counting it twice
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if (gw.domain().statistic == Boson && !Green_Function_Are_Complex_in_time ) g_in(0) *= 0.5;
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details::fourier_base(g_in, g_out, L, false);
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// CORRECT FOR COMPLEX G(tau) !!!
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typedef double gt_result_type;
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//typedef typename gf<imtime>::mesh_type::gf_result_type gt_result_type;
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if (gw.domain().statistic == Fermion){
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for (auto & t : gt.mesh()){
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gt[t] = convert_green<gt_result_type> ( g_out( t.index() == L ? 0 : t.index() ) * exp(-iomega*t)
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+ oneFermion(a1,b1,t,beta) + oneFermion(a2,b2,t,beta)+ oneFermion(a3,b3,t,beta) );
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}
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}
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else {
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for (auto & t : gt.mesh())
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gt[t] = convert_green<gt_result_type> ( g_out( t.index() == L ? 0 : t.index() )
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+ oneBoson(a1,b1,t,beta) + oneBoson(a2,b2,t,beta) + oneBoson(a3,b3,t,beta) );
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}
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if (gt.mesh().kind() == full_bins)
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gt.on_mesh(L) = -gt.on_mesh(0)-convert_green<gt_result_type>(ta(1)(0,0));
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// set tail
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gt.singularity() = gw.singularity();
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}
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};
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void fourier_impl (gf_view<imfreq,scalar_valued> gw , gf_view<imtime,scalar_valued> const gt, scalar_valued){
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impl_worker w;
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w.direct(gw,gt);
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}
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void fourier_impl (gf_view<imfreq,matrix_valued> gw , gf_view<imtime,matrix_valued> const gt, matrix_valued){
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impl_worker w;
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for (size_t n1=0; n1<gt.data().shape()[1];n1++)
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for (size_t n2=0; n2<gt.data().shape()[2];n2++){
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auto gw_sl=slice_target_to_scalar(gw,n1,n2);
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auto gt_sl=slice_target_to_scalar(gt,n1,n2);
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w.direct(gw_sl, gt_sl);
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}
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}
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//---------------------------------------------------------------------------
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void inverse_fourier_impl (gf_view<imtime,scalar_valued> gt , gf_view<imfreq,scalar_valued> const gw, scalar_valued){
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impl_worker w;
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w.inverse(gt,gw);
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}
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void inverse_fourier_impl (gf_view<imtime,matrix_valued> gt , gf_view<imfreq,matrix_valued> const gw, matrix_valued){
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impl_worker w;
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for (size_t n1=0; n1<gw.data().shape()[1];n1++)
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for (size_t n2=0; n2<gw.data().shape()[2];n2++){
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auto gt_sl=slice_target_to_scalar(gt, n1, n2);
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auto gw_sl=slice_target_to_scalar(gw, n1, n2);
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w.inverse( gt_sl, gw_sl);
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}
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}
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//---------------------------------------------------------------------------
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void triqs_gf_view_assign_delegation( gf_view<imfreq,scalar_valued> g, gf_keeper<tags::fourier,imtime,scalar_valued> const & L) { fourier_impl ( g ,L.g, scalar_valued() ); }
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void triqs_gf_view_assign_delegation( gf_view<imfreq,matrix_valued> g, gf_keeper<tags::fourier,imtime,matrix_valued> const & L) { fourier_impl ( g, L.g, matrix_valued() ); }
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void triqs_gf_view_assign_delegation( gf_view<imtime,scalar_valued> g, gf_keeper<tags::fourier,imfreq,scalar_valued> const & L) { inverse_fourier_impl( g, L.g, scalar_valued() ); }
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void triqs_gf_view_assign_delegation( gf_view<imtime,matrix_valued> g, gf_keeper<tags::fourier,imfreq,matrix_valued> const & L) { inverse_fourier_impl( g, L.g, matrix_valued() ); }
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}}
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