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auto_correlation.f
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auto_correlation.f
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#include "GPU.h"
!
! Calculates the auto correlation function: AC(t) = <PSI(0)|PSI(t)>,
! and it's Fourier transform: FAC(w) = F[AC(t)],
! using FFTW.
!
! Calculates the occupation of the adiabatic (MO) states, and
! sums over the elements of the density matrix.
!
! Alberto Torres
!
! Notes:
! - Works only in the molecular representations
! - Devs.: - Call Auto_Correlation_init after calculating bra(t=0),
! then Auto_Correlation after calc. ket,
! and finally, after the dynamics completes, Auto_Correlation_end.
! - Call MO_Occupation after MO orbitals have been calculated.
! To do:
! - moving basis
! - work with restart = true
! - MO_Occupation, done
! - WF_AutoCorrelation, partially
module Auto_Correlation_m
use blas95
use Matrix_Math
use type_m
use constants_m , only : twopi, h_bar, pico_2_sec
use parameters_m , only : n_part, n_t, t_i, t_f, DOS_range, restart, nuclear_matter
public :: Auto_Correlation_init, Auto_Correlation_restart, Auto_Correlation, Auto_Correlation_end, &
MO_Occupation
private
logical :: atoms_move
integer, parameter :: out_AC = 70, &
out_Occ = 71, &
out_Coh = 72
complex*16, allocatable :: PSI_0(:,:), & ! initial WaveFunction (<bra|)
AC(:,:) ! WF Auto-Correlation
contains
!=============================================
subroutine Auto_Correlation_init( basis, bra )
!=============================================
implicit none
type(STO_basis), intent(in) :: basis(:)
complex*16, intent(in) :: bra(:,:)
! local variables
integer :: n
! dimension
n = size(basis)
!------------------
! do atoms move? Or: does the basis change over time?
if( nuclear_matter == "MDynamics" ) then
atoms_move = .true.
write(*,'(a)') "Auto_Correlation_init: not implemented for 'moving' basis set. Results will be spurious."
else
atoms_move = .false.
end if
allocate( PSI_0(n, n_part), source = bra )
!------------------
! save PSI_0 for restart (binary format)
open(out_AC, file='AC.restart', status='unknown', form='unformatted')
write(out_AC) PSI_0
close(out_AC)
!------------------
! open file
open(out_AC, file='Auto_Correlation.dat', status='unknown', form='formatted')
! header
if(n_part == 1 ) then
write(out_AC,'(a)') "# time(ps) mod phase Re Im of <e(0)|e(t)>"
else
write(out_AC,'(a)') "# time(ps) mod_e mod_h phase_e phase_h Re_e Re_h Im_e Im_h of <q(0)|q(t)>, q=e,h"
end if
!------------------
! Calculate auto correlation at t=t_i:
allocate( AC(n_t, n_part) )
call Auto_Correlation( basis, bra, t_i, 1 )
end subroutine Auto_Correlation_init
!
!
!
!=====================================================================
subroutine Auto_Correlation_restart( n )
!=====================================================================
implicit none
integer, intent(in) :: n
! read initial saved PSI_0
allocate( PSI_0(n, n_part) )
open(out_AC, file='AC.restart', status='old', form='unformatted', access='sequential', action='read')
read(out_AC) PSI_0
close(out_AC)
! read Autocorrelation
allocate( AC(n_t, n_part) )
! open file
open(out_AC, file='Auto_Correlation.dat', status='old', access='append')
end subroutine Auto_Correlation_restart
!
!
!
!===================================================
subroutine Auto_Correlation( basis_t, ket_t, t, it )
!===================================================
implicit none
type(STO_basis), intent(in) :: basis_t(:)
complex*16, intent(in) :: ket_t(:,:)
real*8, intent(in) :: t
integer, intent(in) :: it
! local variables
integer :: n, i
! dimension
n = size(basis_t)
! calculate auto correlation: AC = <bra_0|ket_t>
do i = 1, n_part
AC(it,i) = dotu( PSI_0(:,i), ket_t(:,i) )
end do
! write results
write(out_AC,'(7f10.6)') t, abs(AC(it,:)), datan2(dimag(AC(it,:)),dreal(AC(it,:))), AC(it,:)
call flush(out_AC)
end subroutine Auto_Correlation
!
!
!
!==============================
subroutine Auto_Correlation_end
!==============================
implicit none
include 'fftw3.f'
! local variables
integer :: i, n
integer*8 :: plan
real*8 :: T, w
real*8, allocatable :: FAC(:,:) ! holds the Fourier transform of the Auto Correlation
n = 2*n_t
! deallocate and allocate
deallocate( PSI_0 )
allocate( FAC(n,n_part) )
! calculate fourier transform with FFTW
do i = 1, n_part
call dfftw_plan_dft_c2r_1d( plan, n, AC(:,i), FAC(:,i), FFTW_ESTIMATE ) ! this is FFTW_BACKWARD
call dfftw_execute_dft_c2r( plan, AC(:,i), FAC(:,i) )
call dfftw_destroy_plan( plan )
end do
FAC = FAC/n ! normalize
close(out_AC)
open(out_AC, file='Auto_Correlation_Fourier.dat', status='unknown')
T = 2*(t_f - t_i)*pico_2_sec ! in seconds
! available frequency output units: index, Hz, rad/s, s, and eV
do i = n/2+1, n
w = i-n-1 ! index
w = w/T ! f = index/T - 1/s (Hz)
w = twopi*w ! w = 2.pi.f - rad/s
! w = merge( 0.d0, 1.d0/w/pico_2_sec, w==0.d0 ) ! T = 1/f - period units
w = (pico_2_sec*h_bar)*w ! E = h_bar.w - eV (photon's energy for freq. w)
write(out_AC, '(3es18.8)') w, FAC(i,:)
end do
write(out_AC,*) ''
do i = 1, n/2
w = i-1 ! index
w = w/T ! f = index/T - 1/s (Hz)
w = twopi*w ! w = 2.pi.f - rad/s
! w = merge( 0.d0, 1.d0/w/pico_2_sec, w==0.d0 ) ! T = 1/f - period (T) units
w = (pico_2_sec*h_bar)*w ! E = h_bar.w - eV (photon's energy for freq. w)
write(out_AC, '(3es18.8)') w, FAC(i,:)
end do
close(out_AC)
deallocate( AC, FAC)
call system('rm -f AC.restart')
end subroutine Auto_Correlation_end
!
!
!
!==================================================================
subroutine MO_Occupation( t, bra, ket, UNI_el, UNI_hl )
! Calculates the occupation of each level (adiabatic basis set is assumed)
!==================================================================
implicit none
real*8, intent(in) :: t
complex*16, intent(in) :: bra(:,:), ket(:,:)
type(R_eigen), intent(in) :: UNI_el
type(R_eigen), intent(in), optional :: UNI_hl
! local variables
logical, save :: first_call = .true., All_states = .false.
integer :: i, j, n, nE, p
integer, save :: iEmin, iEmax
real*8 :: Emin, Emax
real*8, allocatable :: erg(:,:), occup_erg(:,:)
real*8, allocatable :: coh_diag(:), coh_off(:)
complex*16 :: rho
! check
if( n_part==2 .and. .not.present(UNI_hl)) then
stop 'ERROR: Auto_Correlation.f: MO_Occupation: n_part = 2, but UNI_hl is not present'
end if
! dimension
n = size(bra,1)
!------------------
! find min and max indexes inside limits
if (All_states) then
iEmin = 1
iEmax = n
else
Emin = DOS_range%inicio ! only orbitals within [Emin, Emax] window will be considered
Emax = DOS_range%fim
if (first_call) then
iEmin = max( 1, maxloc(UNI_el%erg, 1, UNI_el%erg< Emin) + 1 ) ! index of the first orbital inside the energy limit
iEmax = min( n, maxloc(UNI_el%erg, 1, UNI_el%erg<=Emax) ) ! and the last one
if (n_part == 2) then
iEmin = min( iEmin, maxloc(UNI_hl%erg, 1, UNI_hl%erg< Emin) + 1 )
iEmax = max( iEmax, maxloc(UNI_hl%erg, 1, UNI_hl%erg<=Emax) )
end if
end if
end if
! nr. of orbitals inside energy window
nE = iEmax - iEmin + 1
if (first_call) then
write(*,*)
write(*,'(a,i6,a,i6,a,i6)') "Orbitals considered to calc. occupation: [",iEmin,",",iEmax,"] ->", nE
write(*,*)
if(.not. restart) then
open(out_Occ, file='dyn.trunk/Occupation.bin', status='unknown', form='unformatted')
write(out_Occ) n_t, nE, n_part, n, iEmin
open(out_Coh, file='dyn.trunk/Coherences.dat', status='unknown')
write(out_Coh,'(a)') "# time (ps); Sum |rho_ij|^2 for i,j: all; diag; off-diag for el (hl)"
else
open(out_Occ, file='dyn.trunk/Occupation.bin', status='old', access='append', form='unformatted')
open(out_Coh, file='dyn.trunk/Coherences.dat', status='old', access='append')
end if
end if
!------------------
! get energies
allocate(erg( nE, n_part ))
erg(:,1) = UNI_el%erg(iEmin:iEmax) ! el energies
if(n_part==2) &
erg(:,2) = UNI_hl%erg(iEmin:iEmax) ! hl energies
!------------------
! calculate occupation per level...
allocate( occup_erg(nE,n_part) )
!$omp parallel private(p,i,j) shared(n_part,iEmin,iEmax)
!$omp do collapse(2)
do p = 1, n_part
do i = iEmin, iEmax
j = i - iEmin + 1
occup_erg(j,p) = dreal( bra(i,p)*ket(i,p) ) ! imag. part is zero by construction (checked)
end do
end do
!$omp end do
!$omp end parallel
! write to file
write(out_Occ) t, erg(:,:), occup_erg(:,:)
!------------------
! Coherences
allocate( coh_diag(n_part), coh_off(n_part) )
coh_diag = 0.d0
coh_off = 0.d0
!$omp parallel do private(i,j,p,rho) default(shared) &
!$omp& collapse(2) reduction(+:coh_diag,coh_off)
do p = 1, n_part
do i = 1, n
rho = bra(i,p)*ket(i,p)
coh_diag(p) = coh_diag(p) + rho*conjg(rho) ! diagonal
do j = i+1, n
rho = bra(i,p)*ket(j,p)
coh_off(p) = coh_off(p) + rho*conjg(rho) ! off-diagonal
end do
end do
end do
!$omp end parallel do
coh_off = 2.d0*coh_off ! We used the Hermitian symmetry of rho above, so the factor 2
if (n_part==1) then
write(out_Coh,'(f11.6,3f20.16)') t, coh_diag+coh_off, coh_diag, coh_off
else
write(out_Coh,'(f11.6,3f20.16,a,3f20.16)') t , coh_diag(1)+coh_off(1), coh_diag(1), coh_off(1), &
' ', coh_diag(2)+coh_off(2), coh_diag(2), coh_off(2)
end if
deallocate( occup_erg, erg )
first_call = .false.
end subroutine MO_Occupation
!
!
!
end module Auto_Correlation_m