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https://github.com/triqs/dft_tools
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725 lines
32 KiB
Fortran
725 lines
32 KiB
Fortran
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c ******************************************************************************
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c
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c TRIQS: a Toolbox for Research in Interacting Quantum Systems
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c
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c Copyright (C) 2011 by L. Pourovskii, V. Vildosola, C. Martins, M. Aichhorn
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c
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c TRIQS is free software: you can redistribute it and/or modify it under the
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c terms of the GNU General Public License as published by the Free Software
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c Foundation, either version 3 of the License, or (at your option) any later
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c version.
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c
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c TRIQS is distributed in the hope that it will be useful, but WITHOUT ANY
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c WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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c FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
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c details.
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c
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c You should have received a copy of the GNU General Public License along with
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c TRIQS. If not, see <http://www.gnu.org/licenses/>.
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c
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c *****************************************************************************/
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SUBROUTINE set_projections(e1,e2)
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C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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C %% %%
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C %% This subroutine sets up the projection matrices in the energy %%
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C %% window [e1,e2].Two types of projection can be defined : %%
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C %% - The projectors <u_orb|ik,ib,is> for the correlated orbital %%
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C %% only. (orb = iatom,is,m) %%
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C %% (They are stored in the table pr_crorb) %%
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C %% - The Theta projectors <theta_orb|k,ib> for all the orbitals %%
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C %% (They are stored in the table pr_orb) %%
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C %% %%
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C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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C Definiton of the variables :
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C ----------------------------
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C
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USE almblm_data
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USE common_data
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USE prnt
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USE projections
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USE reps
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USE symm
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IMPLICIT NONE
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C
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REAL(KIND=8) :: e1, e2
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INTEGER :: iorb, icrorb, ik, is, ib, m, l, lm, nbbot, nbtop
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INTEGER :: isrt, n, ilo, iatom, i, imu, jatom, jorb,isym, jcrorb
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LOGICAL :: included,param
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COMPLEX(KIND=8), DIMENSION(:), ALLOCATABLE :: coeff
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COMPLEX(KIND=8), DIMENSION(:,:), ALLOCATABLE :: tmp_mat
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COMPLEX(KIND=8), DIMENSION(:,:), ALLOCATABLE :: tmp_matbis
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COMPLEX(KIND=8), DIMENSION(:,:,:), ALLOCATABLE :: tmp_matn
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C
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C
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C
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WRITE(buf,'(a)')'Creation of the projectors...'
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CALL printout(0)
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C
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C
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C ======================================================================
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C Selection of the bands which lie in the chosen energy window [e1;e2] :
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C ======================================================================
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C
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kp(:,:)%included=.FALSE.
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C the field kp%included = boolean which is .TRUE. when there is at least one band
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C at this k-point whose energy eignevalue is in the energy window.
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DO is=1,ns
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DO ik=1,nk
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included=.FALSE.
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DO ib=kp(ik,is)%nbmin,kp(ik,is)%nbmax
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IF(.NOT.included.AND.kp(ik,is)%eband(ib) > e1.AND.
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& kp(ik,is)%eband(ib).LE.e2) THEN
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C If the energy eigenvalue E of the band ib at the k-point ik is such that e1 < E =< e2,
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C then all the band with ib1>ib must be "included" in the computation and kp%nb_bot is initialized at the value ib.
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included=.TRUE.
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kp(ik,is)%nb_bot=ib
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ELSEIF(included.AND.kp(ik,is)%eband(ib) > e2) THEN
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C If the energy eigenvalue E of the current band ib at the k-point ik is such that E > e2 and all the previous
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C band are "included", then the field kp%included = .TRUE. and kp%nb_top = ib-1 (the index of the previous band)
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kp(ik,is)%nb_top=ib-1
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kp(ik,is)%included=.TRUE.
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EXIT
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C The loop on the band ib is stopped, since all the bands after ib have an energy > that of ib.
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ELSEIF(ib==kp(ik,is)%nbmax.AND.kp(ik,is)%eband(ib)
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& > e1.AND.kp(ik,is)%eband(ib).LE.e2) THEN
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C If the energy eigenvalue E of the last band ib=kp%nbmax at the k-point ik is such that e1 < E =< e2 and all the
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C previous bands are "included", then the band ib must be "included" and kp%nb_bot is initialized at the value kp%nbmax.
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kp(ik,is)%nb_top=ib
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kp(ik,is)%included=.TRUE.
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ENDIF
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C If the eigenvalues of the bands at the k-point ik are < e1 and included=.FALSE.
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C of if the eigenvalues of the bands at the k-point ik are in the energy window [e1,e2] and included=.TRUE.,
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C nothing is done...
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ENDDO ! End of the ib loop
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C If all the eigenvalues of the bands at the k-point ik are not in the window,
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C then kp%included remains at the value .FALSE. and the field kp%nb_top and kp%nb_bot are set to 0.
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IF (.not.kp(ik,is)%included) THEN
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kp(ik,is)%nb_bot=0
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kp(ik,is)%nb_top=0
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ENDIF
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ENDDO ! End of the ik loop
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ENDDO ! End of the is loop
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C ---------------------------------------------------------------------------------------
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C Checking of the input files if spin-polarized inputs and SO is taken into account:
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C There should not be any difference between up and dn limits for each k-point.
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C Printing a Warning if this is not the case.
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C -------------------
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C
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IF (ifSP.AND.ifSO) THEN
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param=.TRUE.
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DO ik=1,nk
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param=param.AND.(kp(ik,1)%included.eqv.kp(ik,2)%included)
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param=param.AND.(kp(ik,1)%nb_bot==kp(ik,2)%nb_bot)
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param=param.AND.(kp(ik,1)%nb_top==kp(ik,2)%nb_top)
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IF (.not.param) EXIT
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C For a valid compoutation, the same k-points must be included for up and dn states,
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C and the upper and lower limits must be the same in both case.
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ENDDO
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IF (.not.param) THEN
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WRITE(buf,'(a,a)')'A Spin-orbit computation for this',
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& ' compound is not possible with these input files.'
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CALL printout(0)
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WRITE(buf,'(a)')'END OF THE PRGM'
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CALL printout(0)
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STOP
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ENDIF
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ENDIF
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C ---------------------------------------------------------------------------------------
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C
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C
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C ==================================================================
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C Orthonormalization of the radial wave functions for each orbital :
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C ==================================================================
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C
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C This step is essential for setting the Theta projectors.
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IF(.NOT.ALLOCATED(norm_radf)) THEN
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ALLOCATE(norm_radf(norb))
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C norm_radf is a table of "ortfunc" elements, its size ranges from 1 to norb.
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DO iorb=1,norb
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l=orb(iorb)%l
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isrt=orb(iorb)%sort
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norm_radf(iorb)%n=nLO(l,isrt)+2
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n=norm_radf(iorb)%n
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ALLOCATE(norm_radf(iorb)%s12(n,n,ns))
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C norm_radf%n = size of the matrix s12
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C norm_radf%s12 = matrix of size n*n (one for spin up, one for spin down, if necessary)
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DO is=1,ns
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norm_radf(iorb)%s12(1:n,1:n,is)=0d0
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norm_radf(iorb)%s12(1,1,is)=1d0
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norm_radf(iorb)%s12(2,2,is)=u_dot_norm(l,isrt,is)
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C Initialization of the matrix norm_radf%s12 for each orbital (l,isrt).
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C We remind tha it is assumed that nLO has the value 0 or 1 only !!
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DO ilo=1,nLO(l,isrt)
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norm_radf(iorb)%s12(2+ilo,2+ilo,is)=1d0
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norm_radf(iorb)%s12(2+ilo,1,is)=
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= ovl_LO_u(ilo,l,isrt,is)
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norm_radf(iorb)%s12(1,2+ilo,is)=
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= ovl_LO_u(ilo,l,isrt,is)
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norm_radf(iorb)%s12(2+ilo,2,is)=
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= ovl_LO_udot(ilo,l,isrt,is)
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norm_radf(iorb)%s12(2,2+ilo,is)=
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= ovl_LO_udot(ilo,l,isrt,is)
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ENDDO
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C Computation of the square root of norm_radf:
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CALL orthogonal_r(norm_radf(iorb)%
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& s12(1:n,1:n,is),n,.FALSE.)
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C the field norm_radf%s12 is finally the C matrix described in the tutorial (or in equation (3.63) in my thesis)
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ENDDO
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ENDDO
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ENDIF
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C
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C =====================================
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C Creation of the projection matrices :
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C =====================================
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C
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IF(.NOT.ALLOCATED(pr_orb)) THEN
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ALLOCATE(pr_crorb(ncrorb,nk,ns))
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ALLOCATE(pr_orb(norb,nk,ns))
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ENDIF
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C pr_crorb = table of "proj_mat" elements for the correlated orbitals (size from 1 to ncrorb, from 1 to nk, from 1 to ns)
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C pr_orb = table of "proj_mat_n" elements for all the orbitals (size from 1 to norb, from 1 to nk, from 1 to ns)
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DO is=1,ns
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DO ik=1,nk
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C Only the k-points with inlcuded bands are considered for the projectors.
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IF(.NOT.kp(ik,is)%included) CYCLE
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C ------------------------------------------------
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C Wannier Projectors for the correlated orbitals :
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C ------------------------------------------------
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DO icrorb=1,ncrorb
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l=crorb(icrorb)%l
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iatom=crorb(icrorb)%atom
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isrt=crorb(icrorb)%sort
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C Case of l=0 :
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C -------------
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IF (l==0) THEN
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IF(ALLOCATED(pr_crorb(icrorb,ik,is)%mat)) THEN
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DEALLOCATE(pr_crorb(icrorb,ik,is)%mat)
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ENDIF
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ALLOCATE(pr_crorb(icrorb,ik,is)%
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% mat(1,kp(ik,is)%nb_bot:kp(ik,is)%nb_top))
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C pr_crorb%mat = the projection matrix with 1 line and (nb_top-nb_bot) columns
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DO ib=kp(ik,is)%nb_bot,kp(ik,is)%nb_top
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pr_crorb(icrorb,ik,is)%mat(1,ib)=
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= kp(ik,is)%Alm(1,iatom,ib)
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DO ilo=1,nLO(l,isrt)
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pr_crorb(icrorb,ik,is)%mat(1,ib)=
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= pr_crorb(icrorb,ik,is)%mat(1,ib)+
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+ kp(ik,is)%Clm(ilo,1,iatom,ib)*
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* ovl_LO_u(ilo,l,isrt,is)
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ENDDO ! End of the ilo loop
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ENDDO ! End of the ib loop
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C prcrorb(icrorb,ik,is)%mat(1,ib)= <ul1(icrorb,1,is)|psi(is,ik,ib)> = Alm+Clm*ovl_LO_u
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C
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C Case of any other l :
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C ---------------------
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ELSE
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lm=l*l
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C Since the correlated orbital is the l orbital, the elements range from l*l+1 to (l+1)^2
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C the sum from 0 to (l-1) of m (from -l to l) is l^2.
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IF(ALLOCATED(pr_crorb(icrorb,ik,is)%mat)) THEN
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DEALLOCATE(pr_crorb(icrorb,ik,is)%mat)
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ENDIF
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ALLOCATE(pr_crorb(icrorb,ik,is)%
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% mat(-l:l,kp(ik,is)%nb_bot:kp(ik,is)%nb_top))
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C pr_crorb%mat = the projection matrix with (2*l+1) lines and (nb_top-nb_bot) columns
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DO m=-l,l
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lm=lm+1
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DO ib=kp(ik,is)%nb_bot,kp(ik,is)%nb_top
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pr_crorb(icrorb,ik,is)%mat(m,ib)=
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= kp(ik,is)%Alm(lm,iatom,ib)
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DO ilo=1,nLO(l,isrt)
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pr_crorb(icrorb,ik,is)%mat(m,ib)=
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= pr_crorb(icrorb,ik,is)%mat(m,ib)+
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+ kp(ik,is)%Clm(ilo,lm,iatom,ib)*
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* ovl_LO_u(ilo,l,isrt,is)
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ENDDO ! End of the ilo loop
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ENDDO ! End of the ib loop
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ENDDO ! End of the m loop
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C prcrorb(icrorb,ik,is)%mat(m,ib)= <ul1(icrorb,m,is)|psi(is,ik,ib)> = Alm+Clm*ovl_LO_u
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ENDIF ! End of the if l=0 if-then-else
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ENDDO ! End of the icrorb loop
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C
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C ---------------------------------------
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C Theta Projectors for all the orbitals :
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C ---------------------------------------
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DO iorb=1,norb
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l=orb(iorb)%l
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n=norm_radf(iorb)%n
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iatom=orb(iorb)%atom
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C Case of l=0 :
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C -------------
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IF (l==0) THEN
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IF(ALLOCATED(pr_orb(iorb,ik,is)%matn)) THEN
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DEALLOCATE(pr_orb(iorb,ik,is)%matn)
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ENDIF
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ALLOCATE(pr_orb(iorb,ik,is)%
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% matn(1,kp(ik,is)%nb_bot:kp(ik,is)%nb_top,n))
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ALLOCATE(coeff(1:n))
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C pr_orb%matn = the projection matrix with 1 line and (nb_top-nb_bot) columns for the n (size of s12) coefficients
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C coeff = table of size n which will contain the decomposition of the Bloch state |psi_ik,ib,is>
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C as in equation 22 of the tutorial (Alm, Blm, and Clm )
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DO ib=kp(ik,is)%nb_bot,kp(ik,is)%nb_top
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coeff(1)=kp(ik,is)%Alm(1,iatom,ib)
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coeff(2)=kp(ik,is)%Blm(1,iatom,ib)
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coeff(3:n)=kp(ik,is)%Clm(1:n-2,1,iatom,ib)
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coeff=MATMUL(coeff,norm_radf(iorb)%s12(1:n,1:n,is))
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C coeff = coefficients c_(j,lm) of the decomposition of the state |psi> in the orthogonalized basis |phi_j>
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C as defined in the tutorial (equation 25)
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pr_orb(iorb,ik,is)%matn(1,ib,1:n)=coeff(1:n)
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ENDDO
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DEALLOCATE(coeff)
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C pr_orb(iorb,ik,is)%matn(m,ib,1:n) is then the Theta projector as defined in equation 26 of the tutorial.
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C
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C Case of any other l :
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C ---------------------
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ELSE
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lm=l*l
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C As the orbital is the l orbital, the elements range from l*l+1 to (l+1)^2
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C the sum from 0 to (l-1) of m (from -l to l) is l^2.
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IF(ALLOCATED(pr_orb(iorb,ik,is)%matn)) THEN
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DEALLOCATE(pr_orb(iorb,ik,is)%matn)
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ENDIF
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ALLOCATE(pr_orb(iorb,ik,is)%
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% matn(-l:l,kp(ik,is)%nb_bot:kp(ik,is)%nb_top,n))
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ALLOCATE(coeff(1:n))
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C pr_orb%matn = the projection matrix with (2*l+1) lines and (nb_top-nb_bot) columns for the n (size of s12) coefficients
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C coeff = table of size n which will contain the decomposition of the Bloch state |psi_ik,ib,is>
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C as in equation 22 of the tutorial (Alm, Blm, and Clm )
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DO m=-l,l
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lm=lm+1
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DO ib=kp(ik,is)%nb_bot,kp(ik,is)%nb_top
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coeff(1)=kp(ik,is)%Alm(lm,iatom,ib)
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coeff(2)=kp(ik,is)%Blm(lm,iatom,ib)
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coeff(3:n)=kp(ik,is)%Clm(1:n-2,lm,iatom,ib)
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coeff=MATMUL(coeff,
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& norm_radf(iorb)%s12(1:n,1:n,is))
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C coeff = coefficients c_(j,lm) of the decomposition of the state |psi> in the orthogonalized basis |phi_j>
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C as defined in the tutorial (equation 25)
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pr_orb(iorb,ik,is)%matn(m,ib,1:n)=coeff(1:n)
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ENDDO
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ENDDO ! End of the m loop
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DEALLOCATE(coeff)
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C pr_orb(iorb,ik,is)%matn(m,ib,1:n) is then the Theta projector as defined in equation 26 of the tutorial.
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ENDIF ! End of the if l=0 if-then-else
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ENDDO ! End of the iorb loop
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C
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ENDDO ! End of the loop on ik
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ENDDO ! End of the loop on is
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C
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C
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C ==========================================================================
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C Multiplication of the projection matrices by the local rotation matrices :
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C ==========================================================================
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C
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C ------------------------------------------------
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C Wannier Projectors for the correlated orbitals :
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C ------------------------------------------------
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C
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DO jcrorb=1,ncrorb
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jatom=crorb(jcrorb)%atom
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isrt=crorb(jcrorb)%sort
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l=crorb(jcrorb)%l
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C
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C The case l=0 is a particular case of "non-mixing" basis.
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C --------------------------------------------------------
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IF (l==0) THEN
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C For the s orbital, no multiplication is needed, since the matrix representation of any rotation
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C (and thus Rloc) is always 1.
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DO ik=1,nk
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DO is=1,ns
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C Only the k-points with inlcuded bands are considered for the projectors.
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IF(.NOT.kp(ik,is)%included) CYCLE
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nbtop=kp(ik,is)%nb_top
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nbbot=kp(ik,is)%nb_bot
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IF(ALLOCATED(pr_crorb(jcrorb,ik,is)%mat_rep)) THEN
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DEALLOCATE(pr_crorb(jcrorb,ik,is)%mat_rep)
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ENDIF
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ALLOCATE(pr_crorb(jcrorb,ik,is)
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& %mat_rep(1,nbbot:nbtop))
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pr_crorb(jcrorb,ik,is)%mat_rep(1,nbbot:nbtop)=
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= pr_crorb(jcrorb,ik,is)%mat(1,nbbot:nbtop)
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C As a result, prcrorb%matrep = prcrorb%mat
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ENDDO
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ENDDO
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C
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C If the basis representation needs a complete spinor rotation approach (matrices of size 2*(2*l+1) )
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C ---------------------------------------------------------------------------------------------------
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ELSEIF (reptrans(l,isrt)%ifmixing) THEN
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C If this option is used, then ifSO=.TRUE. (because of the restriction in set_ang_trans.f)
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C Moreover ifSP=.TRUE. (since ifSO => ifSP in this version)
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C As a result, we know that nb_bot(up)=nb_bot(dn) and nb_top(up)=nb_top(dn)
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DO ik=1,nk
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C Only the k-points with inlcuded bands are considered for the projectors.
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IF(.NOT.kp(ik,1)%included) CYCLE
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nbbot=kp(ik,1)%nb_bot
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nbtop=kp(ik,1)%nb_top
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C In this case, the projection matrix will be stored in prcrorb%matrep with is=1.
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IF(ALLOCATED(pr_crorb(jcrorb,ik,1)%mat_rep)) THEN
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DEALLOCATE(pr_crorb(jcrorb,ik,1)%mat_rep)
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ENDIF
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ALLOCATE(pr_crorb(jcrorb,ik,1)%
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% mat_rep(1:2*(2*l+1),nbbot:nbtop))
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C The element prcrorb%matrep for is=2 is set to 0, since all the matrix will be stored in the matrix matrep for is=1
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IF(.not.ALLOCATED(pr_crorb(jcrorb,ik,2)%mat_rep)) THEN
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ALLOCATE(pr_crorb(jcrorb,ik,2)%mat_rep(1,1))
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pr_crorb(jcrorb,ik,2)%mat_rep(1,1)=0.d0
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ENDIF
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C Creation of a matrix tmp_mat which "concatenates" up and dn parts of pr_crorb.
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ALLOCATE(tmp_mat(1:2*(2*l+1),nbbot:nbtop))
|
|
tmp_mat(1:(2*l+1),nbbot:nbtop)=
|
|
= pr_crorb(jcrorb,ik,1)%mat(-l:l,nbbot:nbtop)
|
|
C The first (2l+1) lines are the spin-up part of the projection matrix prcrorb%mat.
|
|
C
|
|
C ---------------------------------------------------------------------------------------
|
|
C Interruption of the prgm if there is no dn part of pr_orb.
|
|
C -------------------------
|
|
C
|
|
IF(.not.ifSP) THEN
|
|
WRITE(buf,'(a,a,i2,a)')'The projectors on ',
|
|
& 'the dn states are required for isrt = ',isrt,
|
|
& ' but there is no spin-polarized input files.'
|
|
CALL printout(0)
|
|
WRITE(buf,'(a)')'END OF THE PRGM'
|
|
CALL printout(0)
|
|
STOP
|
|
ENDIF
|
|
C ---------------------------------------------------------------------------------------
|
|
C
|
|
C The last (2l+1) lines are the spin-dn part of the projection matrix prcrorb%mat.
|
|
tmp_mat((2*l+2):2*(2*l+1),nbbot:nbtop)=
|
|
= pr_crorb(jcrorb,ik,2)%mat(-l:l,nbbot:nbtop)
|
|
C
|
|
C Multiplication by the local rotation matrix ; Up and dn parts are treated independently
|
|
C since in lapw2 (-alm) the coefficients Alm, Blm and Clm were calculated in the local frame
|
|
C but without taking into account the spinor-rotation matrix.
|
|
ALLOCATE(tmp_matbis(1:(2*l+1),nbbot:nbtop))
|
|
tmp_matbis(1:(2*l+1),nbbot:nbtop)=
|
|
= tmp_mat(1:(2*l+1),nbbot:nbtop)
|
|
CALL rot_projectmat(tmp_matbis,
|
|
& l,nbbot,nbtop,jatom,isrt)
|
|
tmp_mat(1:(2*l+1),nbbot:nbtop)=
|
|
= tmp_matbis(1:(2*l+1),nbbot:nbtop)
|
|
tmp_matbis(1:(2*l+1),nbbot:nbtop)=
|
|
= tmp_mat(2*l+2:2*(2*l+1),nbbot:nbtop)
|
|
CALL rot_projectmat(tmp_matbis,
|
|
& l,nbbot,nbtop,jatom,isrt)
|
|
tmp_mat(2*l+2:2*(2*l+1),nbbot:nbtop)=
|
|
= tmp_matbis(1:(2*l+1),nbbot:nbtop)
|
|
DEALLOCATE(tmp_matbis)
|
|
C
|
|
C Putting pr_crorb in the desired basis associated to (l,isrt)
|
|
C
|
|
pr_crorb(jcrorb,ik,1)%mat_rep(1:2*(2*l+1),nbbot:nbtop)=
|
|
= MATMUL(reptrans(l,isrt)%transmat
|
|
& (1:2*(2*l+1),1:2*(2*l+1)),
|
|
& tmp_mat(1:2*(2*l+1),nbbot:nbtop))
|
|
C pr_crorb%mat_rep = proj_{new_i} = reptrans*proj_{lm} = <new_i|lm>*proj_{lm}
|
|
DEALLOCATE(tmp_mat)
|
|
ENDDO ! End of the ik loop
|
|
C
|
|
C If the basis representation can be reduce to the up/up block (matrices of size (2*l+1) only)
|
|
C --------------------------------------------------------------------------------------------
|
|
ELSE
|
|
DO ik=1,nk
|
|
DO is=1,ns
|
|
C Only the k-points with inlcuded bands are considered for the projectors.
|
|
IF(.NOT.kp(ik,is)%included) CYCLE
|
|
C In this case, nb_top(up) and nb_bot(up) can differ from nb_top(dn) and nb_bot(dn)
|
|
nbbot=kp(ik,is)%nb_bot
|
|
nbtop=kp(ik,is)%nb_top
|
|
IF(ALLOCATED(pr_crorb(jcrorb,ik,is)%mat_rep)) THEN
|
|
DEALLOCATE(pr_crorb(jcrorb,ik,is)%mat_rep)
|
|
ENDIF
|
|
ALLOCATE(pr_crorb(jcrorb,ik,is)
|
|
& %mat_rep(-l:l,nbbot:nbtop))
|
|
pr_crorb(jcrorb,ik,is)%mat_rep(-l:l,nbbot:nbtop)=
|
|
= pr_crorb(jcrorb,ik,is)%mat(-l:l,nbbot:nbtop)
|
|
C
|
|
C Multiplication by the local rotation matrix
|
|
C since in lapw2 (-alm) the coefficients Alm, Blm and Clm were calculated in the local frame
|
|
CALL rot_projectmat(pr_crorb(jcrorb,ik,is)
|
|
& %mat_rep(-l:l,nbbot:nbtop),l,nbbot,nbtop,jatom,isrt)
|
|
C
|
|
C Putting pr_crorb in the desired basis associated to (l,isrt)
|
|
pr_crorb(jcrorb,ik,is)%mat_rep(-l:l,nbbot:nbtop)=
|
|
= MATMUL(reptrans(l,isrt)%transmat(-l:l,-l:l),
|
|
& pr_crorb(jcrorb,ik,is)%mat_rep(-l:l,nbbot:nbtop))
|
|
C pr_crorb%mat_rep = proj_{new_i} = reptrans*proj_{lm} = <new_i|lm>*proj_{lm}
|
|
ENDDO ! End of the is loop
|
|
ENDDO ! End of the ik loop
|
|
ENDIF ! End of the if mixing if-then-else
|
|
ENDDO ! End of the jcrorb loop
|
|
C
|
|
C ---------------------------------------
|
|
C Theta Projectors for all the orbitals :
|
|
C ---------------------------------------
|
|
C
|
|
DO jorb=1,norb
|
|
jatom=orb(jorb)%atom
|
|
isrt=orb(jorb)%sort
|
|
n=norm_radf(jorb)%n
|
|
l=orb(jorb)%l
|
|
C
|
|
C The case l=0 is a particular case of "non-mixing" basis.
|
|
C --------------------------------------------------------
|
|
IF (l==0) THEN
|
|
C For the s orbital, no multiplication is needed, since the matrix representation of any rotation
|
|
C (and therefore Rloc) is always 1.
|
|
DO ik=1,nk
|
|
DO is=1,ns
|
|
C Only the k-points with inlcuded bands are considered for the projectors.
|
|
IF(.NOT.kp(ik,is)%included) CYCLE
|
|
nbtop=kp(ik,is)%nb_top
|
|
nbbot=kp(ik,is)%nb_bot
|
|
IF(ALLOCATED(pr_orb(jorb,ik,is)%matn_rep)) THEN
|
|
DEALLOCATE(pr_orb(jorb,ik,is)%matn_rep)
|
|
ENDIF
|
|
ALLOCATE(pr_orb(jorb,ik,is)%matn_rep
|
|
& (1,nbbot:nbtop,1:n))
|
|
pr_orb(jorb,ik,is)%matn_rep(1,nbbot:nbtop,1:n)=
|
|
= pr_orb(jorb,ik,is)%matn(1,nbbot:nbtop,1:n)
|
|
C As a result, prorb%matnrep = prorb%matn
|
|
ENDDO
|
|
ENDDO
|
|
C
|
|
C If the basis representation needs a complete spinor rotation approach (matrices of size 2*(2*l+1) )
|
|
C ---------------------------------------------------------------------------------------------------
|
|
ELSEIF (reptrans(l,isrt)%ifmixing) THEN
|
|
C If this option is used, then ifSO=.TRUE. (restriction in set_ang_trans.f)
|
|
C Moreover ifSP=.TRUE. (since ifSO => ifSP)
|
|
C As a result, we know that nb_bot(up)=nb_bot(dn) and nb_top(up)=nb_top(dn)
|
|
DO ik=1,nk
|
|
C Only the k-points with inlcuded bands are considered for the projectors.
|
|
IF(.NOT.kp(ik,1)%included) CYCLE
|
|
nbbot=kp(ik,1)%nb_bot
|
|
nbtop=kp(ik,1)%nb_top
|
|
C In this case, the projection matrix will be stored in prorb%matnrep with is=1.
|
|
IF(ALLOCATED(pr_orb(jorb,ik,1)%matn_rep)) THEN
|
|
DEALLOCATE(pr_orb(jorb,ik,1)%matn_rep)
|
|
ENDIF
|
|
ALLOCATE(pr_orb(jorb,ik,1)%
|
|
% matn_rep(1:2*(2*l+1),nbbot:nbtop,1:n))
|
|
C The element prorb%matnrep for is=2 is set to 0, since all the matrix will be stored in the matrix matnrep for is=1
|
|
IF(.not.ALLOCATED(pr_orb(jorb,ik,2)%matn_rep)) THEN
|
|
ALLOCATE(pr_orb(jorb,ik,2)%matn_rep(1,1,1))
|
|
pr_orb(jorb,ik,2)%matn_rep(1,1,1)=0.d0
|
|
ENDIF
|
|
C Creation of a matrix tmp_matn which "concatenates" up and dn parts of pr_orb
|
|
ALLOCATE(tmp_matn(1:2*(2*l+1),nbbot:nbtop,1:n))
|
|
tmp_matn(1:(2*l+1),nbbot:nbtop,1:n)=
|
|
= pr_orb(jorb,ik,1)%matn(-l:l,nbbot:nbtop,1:n)
|
|
C The first (2l+1) lines are the spin-up part of the projection matrix prorb%matn.
|
|
C
|
|
C ---------------------------------------------------------------------------------------
|
|
C Interruption of the prgm if there is no dn part of pr_orb.
|
|
C -------------------------
|
|
C
|
|
IF(.not.ifSP) THEN
|
|
WRITE(buf,'(a,a,i2,a)')'The projectors on ',
|
|
& 'the down states are required for isrt = ',isrt,
|
|
& ' but there is no spin-polarized input files.'
|
|
CALL printout(0)
|
|
WRITE(buf,'(a)')'END OF THE PRGM'
|
|
CALL printout(0)
|
|
STOP
|
|
ENDIF
|
|
C ---------------------------------------------------------------------------------------
|
|
C
|
|
C The last (2l+1) lines are the spin-dn part of the projection matrix prorb%matn.
|
|
tmp_matn(2*l+2:2*(2*l+1),nbbot:nbtop,1:n)=
|
|
= pr_orb(jorb,ik,2)%matn(-l:l,nbbot:nbtop,1:n)
|
|
C
|
|
DO i=1,n
|
|
C Multiplication by the local rotation matrix ; Up and dn parts are treated independently
|
|
C since in lapw2 (-alm) the coefficients Alm, Blm and Clm were calculated in the local frame
|
|
C but without taking into account the spinor-rotation matrix.
|
|
ALLOCATE(tmp_matbis(1:(2*l+1),nbbot:nbtop))
|
|
tmp_matbis(1:(2*l+1),nbbot:nbtop)=
|
|
= tmp_matn(1:(2*l+1),nbbot:nbtop,i)
|
|
CALL rot_projectmat(tmp_matbis,
|
|
& l,nbbot,nbtop,jatom,isrt)
|
|
tmp_matn(1:(2*l+1),nbbot:nbtop,i)=
|
|
= tmp_matbis(1:(2*l+1),nbbot:nbtop)
|
|
tmp_matbis(1:(2*l+1),nbbot:nbtop)=
|
|
= tmp_matn(2*l+2:2*(2*l+1),nbbot:nbtop,i)
|
|
CALL rot_projectmat(tmp_matbis,
|
|
& l,nbbot,nbtop,jatom,isrt)
|
|
tmp_matn(2*l+2:2*(2*l+1),nbbot:nbtop,i)=
|
|
= tmp_matbis(1:(2*l+1),nbbot:nbtop)
|
|
DEALLOCATE(tmp_matbis)
|
|
C Putting pr_orb in the desired basis associated to (l,isrt)
|
|
pr_orb(jorb,ik,1)%matn_rep
|
|
& (1:2*(2*l+1),nbbot:nbtop,i)=
|
|
= MATMUL(reptrans(l,isrt)%
|
|
& transmat(1:2*(2*l+1),1:2*(2*l+1)),
|
|
& tmp_matn(1:2*(2*l+1),nbbot:nbtop,i))
|
|
C pr_orb%matn_rep = proj_{new_i} = reptrans*proj_{lm} = <new_i|lm>*proj_{lm}
|
|
ENDDO ! End of the i-loop
|
|
DEALLOCATE(tmp_matn)
|
|
ENDDO ! End of the ik loop
|
|
C
|
|
C If the basis representation can be reduce to the up/up block (matrices of size (2*l+1) only)
|
|
C --------------------------------------------------------------------------------------------
|
|
ELSE
|
|
DO ik=1,nk
|
|
DO is=1,ns
|
|
C Only the k-points with inlcuded bands are considered for the projectors.
|
|
IF(.NOT.kp(ik,is)%included) CYCLE
|
|
C In this case, nb_top(up) and nb_bot(up) can differ from nb_top(dn) and nb_bot(dn)
|
|
nbbot=kp(ik,is)%nb_bot
|
|
nbtop=kp(ik,is)%nb_top
|
|
IF(ALLOCATED(pr_orb(jorb,ik,is)%matn_rep)) THEN
|
|
DEALLOCATE(pr_orb(jorb,ik,is)%matn_rep)
|
|
ENDIF
|
|
ALLOCATE(pr_orb(jorb,ik,is)%
|
|
& matn_rep(-l:l,nbbot:nbtop,1:n))
|
|
pr_orb(jorb,ik,is)%matn_rep(-l:l,nbbot:nbtop,1:n)=
|
|
= pr_orb(jorb,ik,is)%matn(-l:l,nbbot:nbtop,1:n)
|
|
C
|
|
DO i=1,n
|
|
C Multiplication by the local rotation matrix
|
|
C since in lapw2 (-alm) the coefficients Alm, Blm and Clm were calculated in the local frame
|
|
CALL rot_projectmat(pr_orb(jorb,ik,is)
|
|
& %matn_rep(-l:l,nbbot:nbtop,i),
|
|
& l,nbbot,nbtop,jatom,isrt)
|
|
C Putting pr_orb in the desired basis associated to (l,isrt)
|
|
pr_orb(jorb,ik,is)%matn_rep(-l:l,nbbot:nbtop,i)=
|
|
= MATMUL(reptrans(l,isrt)%transmat(-l:l,-l:l),
|
|
& pr_orb(jorb,ik,is)%matn_rep(-l:l,nbbot:nbtop,i))
|
|
C pr_orb%matn_rep = proj_{new_i} = reptrans*proj_{lm} = <new_i|lm>*proj_{lm}
|
|
ENDDO ! End of the i loop
|
|
ENDDO ! End of the is loop
|
|
ENDDO ! End of the ik loop
|
|
ENDIF ! End of the if mixing if-then-else
|
|
ENDDO ! End of the jorb loop
|
|
C
|
|
C
|
|
C =============================================================================
|
|
C Printing the projectors with k-points 1 and nk in the file fort.18 for test :
|
|
C =============================================================================
|
|
DO icrorb=1,ncrorb
|
|
iatom=crorb(icrorb)%atom
|
|
isrt=crorb(icrorb)%sort
|
|
l=crorb(icrorb)%l
|
|
WRITE(18,'()')
|
|
WRITE(18,'(a,i4)') 'icrorb = ', icrorb
|
|
WRITE(18,'(a,i4,a,i4)') 'isrt = ', isrt, ' l = ', l
|
|
IF (l==0) THEN
|
|
WRITE(18,'(a,i4)') 'ik = ', 1
|
|
DO ib = kp(1,1)%nb_bot,kp(1,1)%nb_top
|
|
WRITE(18,*) pr_crorb(icrorb,1,1)%mat_rep(:,ib)
|
|
IF (ifSP)
|
|
& WRITE(18,*) pr_crorb(icrorb,1,2)%mat_rep(:,ib)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
WRITE(18,'(a,i4)') 'ik = ', nk
|
|
DO ib = kp(nk,1)%nb_bot,kp(nk,1)%nb_top
|
|
WRITE(18,*) pr_crorb(icrorb,nk,1)%mat_rep(:,ib)
|
|
IF (ifSP)
|
|
& WRITE(18,*) pr_crorb(icrorb,nk,2)%mat_rep(:,ib)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ELSEIF (reptrans(l,isrt)%ifmixing) THEN
|
|
WRITE(18,'(a,i4)') 'ik = ', 1
|
|
DO ib = kp(1,1)%nb_bot,kp(1,1)%nb_top
|
|
WRITE(18,*) pr_crorb(icrorb,1,1)%mat_rep(:,ib)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
WRITE(18,'(a,i4)') 'ik = ', nk
|
|
DO ib = kp(nk,1)%nb_bot,kp(nk,1)%nb_top
|
|
WRITE(18,*) pr_crorb(icrorb,nk,1)%mat_rep(:,ib)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ELSE
|
|
WRITE(18,'(a,i4)') 'ik = ', 1
|
|
DO ib = kp(1,1)%nb_bot,kp(1,1)%nb_top
|
|
WRITE(18,*) pr_crorb(icrorb,1,1)%mat_rep(:,ib)
|
|
IF (ifSP)
|
|
& WRITE(18,*) pr_crorb(icrorb,1,2)%mat_rep(:,ib)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
WRITE(18,'(a,i4)') 'ik = ', nk
|
|
DO ib = kp(nk,1)%nb_bot,kp(nk,1)%nb_top
|
|
WRITE(18,*) pr_crorb(icrorb,nk,1)%mat_rep(:,ib)
|
|
IF (ifSP)
|
|
& WRITE(18,*) pr_crorb(icrorb,nk,2)%mat_rep(:,ib)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ENDIF
|
|
ENDDO
|
|
C
|
|
DO iorb=1,norb
|
|
iatom=orb(iorb)%atom
|
|
isrt=orb(iorb)%sort
|
|
l=orb(iorb)%l
|
|
n=norm_radf(iorb)%n
|
|
WRITE(18,'()')
|
|
WRITE(18,'(a,i4)') 'iorb = ', iorb
|
|
WRITE(18,'(a,i4,a,i4)') 'isrt = ', isrt, ' l = ', l
|
|
IF (l==0) THEN
|
|
WRITE(18,'(a,i4)') 'ik = ', 1
|
|
DO i=1,n
|
|
WRITE(18,'(i4)') i
|
|
DO ib = kp(1,1)%nb_bot,kp(1,1)%nb_top
|
|
WRITE(18,*) pr_orb(iorb,1,1)%matn_rep(:,ib,i)
|
|
IF (ifSP)
|
|
& WRITE(18,*) pr_orb(iorb,1,2)%matn_rep(:,ib,i)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ENDDO
|
|
WRITE(18,'(a,i4)') 'ik = ', nk
|
|
DO i=1,n
|
|
WRITE(18,'(i4)') i
|
|
DO ib = kp(nk,1)%nb_bot,kp(nk,1)%nb_top
|
|
WRITE(18,*) pr_orb(iorb,nk,1)%matn_rep(:,ib,i)
|
|
IF (ifSP)
|
|
& WRITE(18,*) pr_orb(iorb,nk,2)%matn_rep(:,ib,i)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ENDDO
|
|
ELSEIF(reptrans(l,isrt)%ifmixing) THEN
|
|
DO i=1,n
|
|
WRITE(18,'(i4)') i
|
|
DO ib = kp(1,1)%nb_bot,kp(1,1)%nb_top
|
|
WRITE(18,*) pr_orb(iorb,1,1)%matn_rep(:,ib,i)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ENDDO
|
|
WRITE(18,'(a,i4)') 'ik = ', nk
|
|
DO i=1,n
|
|
WRITE(18,'(i4)') i
|
|
DO ib = kp(nk,1)%nb_bot,kp(nk,1)%nb_top
|
|
WRITE(18,*) pr_orb(iorb,nk,1)%matn_rep(:,ib,i)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ENDDO
|
|
ELSE
|
|
DO i=1,n
|
|
WRITE(18,'(i4)') i
|
|
DO ib = kp(1,1)%nb_bot,kp(1,1)%nb_top
|
|
WRITE(18,*) pr_orb(iorb,1,1)%matn_rep(:,ib,i)
|
|
IF (ifSP)
|
|
& WRITE(18,*) pr_orb(iorb,1,2)%matn_rep(:,ib,i)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ENDDO
|
|
WRITE(18,'(a,i4)') 'ik = ', nk
|
|
DO i=1,n
|
|
WRITE(18,'(i4)') i
|
|
DO ib = kp(nk,1)%nb_bot,kp(nk,1)%nb_top
|
|
WRITE(18,*) pr_orb(iorb,nk,1)%matn_rep(:,ib,i)
|
|
IF (ifSP)
|
|
& WRITE(18,*) pr_orb(iorb,nk,2)%matn_rep(:,ib,i)
|
|
WRITE(18,'()')
|
|
ENDDO
|
|
ENDDO
|
|
ENDIF
|
|
ENDDO
|
|
C
|
|
RETURN
|
|
END
|
|
|