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369 lines
17 KiB
FortranFixed
369 lines
17 KiB
FortranFixed
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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_rotloc
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C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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C %% %%
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C %% This subroutine sets up the Global->local coordinates %%
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C %% rotational matrices for each atom of the system. %%
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C %% These matrices will be used to create the projectors. %%
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C %% (They are the SR matrices defined in the tutorial file.) %%
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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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USE common_data
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USE reps
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USE symm
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USE prnt
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IMPLICIT NONE
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COMPLEX(KIND=8), DIMENSION(:,:), ALLOCATABLE :: tmp_rot, spinrot
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REAL(KIND=8) :: alpha, beta, gama, factor
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INTEGER :: iatom, jatom, imu, isrt
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INTEGER :: is, is1, isym, l, lm
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INTEGER :: ind1, ind2, inof1, inof2
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COMPLEX(KIND=8) :: ephase
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C
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C ====================================================
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C Multiplication by an S matrix for equivalent sites :
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C ====================================================
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C Up to now, rotloc is the rotloc matrix (from Global to local coordinates rotation : (rotloc)_ij = <x_global_i | x_local_j >)
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C The matrix S to go from the representative atom of the sort to another one must be introduced. That's what is done here-after.
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DO isrt=1,nsort
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iatom=SUM(nmult(0:isrt-1))+1
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DO imu=1,nmult(isrt)
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jatom=iatom+imu-1
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DO isym=1,nsym
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C If the symmetry operation isym transforms the representative atom iatom in the jatom,
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C the matrix rotloc is multiplied by the corresponding srot matrix, for each orbital number l.
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C if R[isym](iatom) = jatom, rotloc is multiplied by R[isym] and Rloc is finally R[isym] X rotloc = <x_global|x_sym><x_sym|x_local>
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IF(srot(isym)%perm(iatom)==jatom) THEN
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WRITE(17,*) ' For jatom = ',jatom, ', isym =', isym
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rotloc(jatom)%srotnum=isym
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C Calculation of krotm and iprop.
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rotloc(jatom)%krotm(1:3,1:3)=
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= MATMUL(srot(isym)%krotm(1:3,1:3),
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& rotloc(jatom)%krotm(1:3,1:3))
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rotloc(jatom)%iprop=rotloc(jatom)%iprop*
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* srot(isym)%iprop
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C Evaluation of the Euler angles of the final operation Rloc
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CALL euler(TRANSPOSE(rotloc(jatom)%krotm(1:3,1:3)),
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& alpha,beta,gama)
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C According to Wien convention, euler takes in argument the transpose
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C of the matrix rotloc(jatom)%krotm to give a,b anc c of rotloc(jatom).
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rotloc(jatom)%a=alpha
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rotloc(jatom)%b=beta
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rotloc(jatom)%g=gama
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C
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C =============================================================================================================
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C Calculation of the rotational matrices and evaluation of the fields timeinv and phase for the Rloc matrices :
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C =============================================================================================================
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IF(ifSP.AND.ifSO) THEN
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C No time reversal operation is applied to rotloc (alone). If a time reversal operation must be applied,
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C it comes from the symmetry operation R[isym]. That is why the field timeinv is the same as the one from srot.
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rotloc(jatom)%timeinv=srot(isym)%timeinv
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rotloc(jatom)%phase=0.d0
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DO l=1,lmax
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ALLOCATE(tmp_rot(1:2*(2*l+1),1:2*(2*l+1)))
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tmp_rot=0.d0
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C Whatever the value of beta (0 or Pi), the spinor rotation matrix of isym is block-diagonal.
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C because the time-reversal operation have been applied if necessary.
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factor=srot(isym)%phase/2.d0
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ephase=EXP(CMPLX(0.d0,factor))
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C We remind that the field phase is (g-a) if beta=Pi. As a result, ephase = exp(+i(g-a)/2) = -exp(+i(alpha-gamma)/2)
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C We remind that the field phase is (a+g) if beta=0. As a result, ephase = exp(+i(a+g)/2)=-exp(-i(alpha+gamma)/2)
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C in good agreement with Wien conventions for the definition of this phase factor.
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C Up/up block :
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tmp_rot(1:2*l+1,1:2*l+1)=ephase*
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& srot(isym)%rotl(-l:l,-l:l,l)
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C Dn/dn block :
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ephase=CONJG(ephase)
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C now, ephase = exp(+i(a-g)/2) = -exp(-i(alpha-gamma)/2) if beta=Pi
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C now, ephase = exp(-i(a+g)/2) = -exp(+i(alpha+gamma)/2) if beta=0
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tmp_rot(2*l+2:2*(2*l+1),2*l+2:2*(2*l+1))=
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& ephase*srot(isym)%rotl(-l:l,-l:l,l)
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IF (rotloc(jatom)%timeinv) THEN
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C In this case, the time reversal operator was applied to srot.
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rotloc(jatom)%rotl(1:2*(2*l+1),1:2*(2*l+1),l)=
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& MATMUL(tmp_rot(1:2*(2*l+1),1:2*(2*l+1)),CONJG(
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& rotloc(jatom)%rotl(1:2*(2*l+1),1:2*(2*l+1),l)))
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C rotloc(jatom)%rotl now contains D(Rloc) = D(R[isym])*transpose[D(rotloc)].
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ELSE
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C In this case, no time reversal operator was applied to srot.
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rotloc(jatom)%rotl(1:2*(2*l+1),1:2*(2*l+1),l)=
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& MATMUL(tmp_rot(1:2*(2*l+1),1:2*(2*l+1)),
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& rotloc(jatom)%rotl(1:2*(2*l+1),1:2*(2*l+1),l))
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C rotloc(jatom)%rotl now contains D(Rloc) = D(R[isym])*D(rotloc).
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ENDIF
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DEALLOCATE(tmp_rot)
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ENDDO
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ELSE
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C Calculation of the rotational matrices associated to Rloc
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ALLOCATE(tmp_rot(1:2*lmax+1,1:2*lmax+1))
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DO l=1,lmax
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C Use of the subroutine dmat to compute the rotational matrix
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C associated to the Rloc operation in a (2*l+1) space :
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tmp_rot=0.d0
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CALL dmat(l,rotloc(jatom)%a,rotloc(jatom)%b,
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& rotloc(jatom)%g,
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& REAL(rotloc(jatom)%iprop,KIND=8),tmp_rot,2*lmax+1)
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rotloc(jatom)%rotl(-l:l,-l:l,l)=
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= tmp_rot(1:2*l+1,1:2*l+1)
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C rotloc(jatom)%rotl = table of the rotational matrices of the symmetry operation
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C for the different l orbital (from 1 to lmax), in the usual complex basis : dmat = D(R[isym])_l
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C rotloc(jatom)%rotl = D(Rloc[jatom])_{lm}
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ENDDO
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DEALLOCATE(tmp_rot)
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ENDIF ! End of the "ifSO-ifSP" if-then-else
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C
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EXIT
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C Only one symmetry operation is necessary to be applied to R to get the complete rotloc matrix.
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C This EXIT enables to leave the loop as soon as a symmetry operation which transforms the representative atom in jatom is found.
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ENDIF ! End of the "perm" if-then-else
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ENDDO ! End of the isym loop
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C
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C
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C ===========================================================
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C Computation of the rotational matrices in each sort basis :
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C ===========================================================
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ALLOCATE(rotloc(jatom)%rotrep(lmax))
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C
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C Initialization of the rotloc(jatom)%rotrep field = D(Rloc)_{new_i}
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C This field is a table of size lmax which contains the rotloc matrices
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C in the representation basis associated to each included orbital of the jatom.
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DO l=1,lmax
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ALLOCATE(rotloc(jatom)%rotrep(l)%mat(1,1))
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rotloc(jatom)%rotrep(l)%mat(1,1)=0.d0
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ENDDO
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C
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C Computation of the elements 'mat' in rotloc(jatom)%rotrep(l)
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DO l=1,lmax
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C The considered orbital is not included, hence no computation
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IF (lsort(l,isrt)==0) cycle
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C The considered orbital is included
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IF (ifSP.AND.ifSO) THEN
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C In this case, 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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DEALLOCATE(rotloc(jatom)%rotrep(l)%mat)
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ALLOCATE(rotloc(jatom)%rotrep(l)%mat
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& (1:2*(2*l+1),1:2*(2*l+1)))
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ALLOCATE(tmp_rot(1:2*(2*l+1),1:2*(2*l+1)))
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C Computation of rotloc(jatom)%rotrep(l)%mat
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IF (reptrans(l,isrt)%ifmixing) THEN
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C In this case, the basis representation requires a complete spinor rotation approach too.
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IF(rotloc(jatom)%timeinv) THEN
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tmp_rot(1:2*(2*l+1),1:2*(2*l+1))=MATMUL(
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& reptrans(l,isrt)%transmat(1:2*(2*l+1),1:2*(2*l+1)),
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& rotloc(jatom)%rotl(1:2*(2*l+1),1:2*(2*l+1),l))
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rotloc(jatom)%rotrep(l)%mat(1:2*(2*l+1),1:2*(2*l+1))=
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= MATMUL(tmp_rot(1:2*(2*l+1),1:2*(2*l+1)),
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& TRANSPOSE(reptrans(l,isrt)%transmat
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& (1:2*(2*l+1),1:2*(2*l+1))))
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C Since the operation is antilinear, the field rotloc(jatom)%rotrep(l)%mat = (reptrans)*spinrot(l)*conjugate(inverse(reptrans))
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C rotloc(jatom)%rotrep(l)%mat = D(Rloc)_{new_i} = <new_i|lm> D(Rloc)_{lm} [<lm|new_i>]^*
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C which is exactly the expression of the spinor rotation matrix in the new basis.
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ELSE
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tmp_rot(1:2*(2*l+1),1:2*(2*l+1))=MATMUL(
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& reptrans(l,isrt)%transmat(1:2*(2*l+1),1:2*(2*l+1)),
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& rotloc(jatom)%rotl(1:2*(2*l+1),1:2*(2*l+1),l))
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rotloc(jatom)%rotrep(l)%mat(1:2*(2*l+1),1:2*(2*l+1))=
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= MATMUL(tmp_rot(1:2*(2*l+1),1:2*(2*l+1)),
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& TRANSPOSE(CONJG(reptrans(l,isrt)%transmat
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& (1:2*(2*l+1),1:2*(2*l+1)))))
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C Since the operation is linear, the field rotloc(jatom)%rotrep(l)%mat = (reptrans)*spinrot(l)*inverse(reptrans)
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C rotloc(jatom)%rotrep(l)%mat = D(Rloc)_{new_i} = <new_i|lm> D(Rloc)_{lm} <lm|new_i>
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C which is exactly the expression of the spinor rotation matrix in the new basis.
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ENDIF
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ELSE
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C In this case, the basis representation is reduced to the up/up block and must be extended.
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ALLOCATE(spinrot(1:2*(2*l+1),1:2*(2*l+1)))
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spinrot(1:2*(2*l+1),1:2*(2*l+1))=0.d0
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spinrot(1:2*l+1,1:2*l+1)=
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& reptrans(l,isrt)%transmat(-l:l,-l:l)
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spinrot(2*l+2:2*(2*l+1),2*l+2:2*(2*l+1))=
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& reptrans(l,isrt)%transmat(-l:l,-l:l)
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IF(rotloc(jatom)%timeinv) THEN
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tmp_rot(1:2*(2*l+1),1:2*(2*l+1))=MATMUL(
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& spinrot(1:2*(2*l+1),1:2*(2*l+1)),
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& rotloc(jatom)%rotl(1:2*(2*l+1),1:2*(2*l+1),l))
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rotloc(jatom)%rotrep(l)%mat(1:2*(2*l+1),1:2*(2*l+1))=
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= MATMUL(tmp_rot(1:2*(2*l+1),1:2*(2*l+1)),
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& TRANSPOSE(spinrot(1:2*(2*l+1),1:2*(2*l+1))))
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C Since the operation is antilinear, the field rotloc(jatom)%rotrep(l)%mat = (reptrans)*spinrot(l)*conjugate(inverse(reptrans))
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C rotloc(jatom)%rotrep(l)%mat = D(Rloc)_{new_i} = <new_i|lm> D(Rloc)_{lm} [<lm|new_i>]^*
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C which is exactly the expression of the spinor rotation matrix in the new basis.
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ELSE
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tmp_rot(1:2*(2*l+1),1:2*(2*l+1))=MATMUL(
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& spinrot(1:2*(2*l+1),1:2*(2*l+1)),
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& rotloc(jatom)%rotl(1:2*(2*l+1),1:2*(2*l+1),l))
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rotloc(jatom)%rotrep(l)%mat(1:2*(2*l+1),1:2*(2*l+1))=
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= MATMUL(tmp_rot(1:2*(2*l+1),1:2*(2*l+1)),
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& TRANSPOSE(CONJG(spinrot(1:2*(2*l+1),1:2*(2*l+1)))))
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C Since the operation is linear, the field rotloc(jatom)%rotrep(l)%mat = (reptrans)*spinrot(l)*inverse(reptrans)
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C rotloc(jatom)%rotrep(l)%mat = D(Rloc)_{new_i} = <new_i|lm> D(Rloc)_{lm} <lm|new_i>
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C which is exactly the expression of the spinor rotation matrix in the new basis.
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ENDIF
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DEALLOCATE(spinrot)
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ENDIF ! End of the if mixing if-then-else
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DEALLOCATE(tmp_rot)
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C
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ELSE
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C If the basis representation can be reduce to the up/up block (matrices of size (2*l+1) only)
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C --------------------------------------------------------------------------------------------
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DEALLOCATE(rotloc(jatom)%rotrep(l)%mat)
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ALLOCATE(rotloc(jatom)%rotrep(l)%mat(-l:l,-l:l))
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ALLOCATE(tmp_rot(-l:l,-l:l))
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C Computation of rotloc(jatom)%rotrep(l)%mat
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tmp_rot(-l:l,-l:l)=MATMUL(
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& reptrans(l,isrt)%transmat(-l:l,-l:l),
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& rotloc(jatom)%rotl(-l:l,-l:l,l))
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rotloc(jatom)%rotrep(l)%mat(-l:l,-l:l)=
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= MATMUL(tmp_rot(-l:l,-l:l),
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& TRANSPOSE(CONJG(reptrans(l,isrt)%transmat(-l:l,-l:l))))
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C the field rotloc(jatom)%rotrep(l)%mat = (reptrans)*rotl*inverse(reptrans)
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C rotloc(jatom)%rotrep(l)%mat = D(Rloc)_{new_i} = <new_i|lm> D(Rloc)_{lm} <lm|new_i>
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C which is exactly the expression of the rotation matrix for the up/up block in the new basis.
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DEALLOCATE(tmp_rot)
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ENDIF
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ENDDO ! End of the l loop
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ENDDO ! End of the jatom loop
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ENDDO ! End of the isrt loop
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C
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RETURN
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END
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SUBROUTINE euler(Rot,a,b,c)
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C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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C %% %%
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C %% This subroutine calculates the Euler angles a, b and c of Rot. %%
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C %% The result are stored in a,b,c. (same as in SRC_lapwdm/euler.f) %%
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C %% %%
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C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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C
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IMPLICIT NONE
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REAL(KIND=8) :: a,aa,b,bb,c,cc,zero,pi,y_norm,dot
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REAL(KIND=8), DIMENSION(3,3) :: Rot, Rot_temp
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REAL(KIND=8), DIMENSION(3) :: z,zz,y,yy,yyy,pom,x,xx
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INTEGER :: i,j
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C Definition of the constants
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zero=0d0
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pi=ACOS(-1d0)
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C Definition of Rot_temp=Id
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DO i=1,3
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DO j=1,3
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Rot_temp(i,j)=0
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IF (i.EQ.j) Rot_temp(i,i)=1
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ENDDO
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ENDDO
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C Initialization of y=e_y, z=e_z, yyy and zz
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DO j=1,3
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y(j)=Rot_temp(j,2)
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yyy(j)=Rot(j,2)
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z(j)=Rot_temp(j,3)
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zz(j)=Rot(j,3)
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ENDDO
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C Calculation of yy
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CALL vecprod(z,zz,yy)
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y_norm=DSQRT(dot(yy,yy))
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IF (y_norm.lt.1d-10) THEN
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C If yy=0, this implies that b is zero or pi
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IF (ABS(dot(y,yyy)).gt.1d0) THEN
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aa=dot(y,yyy)/ABS(dot(y,yyy))
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a=ACOS(aa)
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ELSE
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a=ACOS(dot(y,yyy))
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ENDIF
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C
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IF (dot(z,zz).gt.zero) THEN
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c=zero
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b=zero
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IF (yyy(1).gt.zero) a=2*pi-a
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ELSE
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c=a
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||
|
a=zero
|
||
|
b=pi
|
||
|
IF (yyy(1).lt.zero) c=2*pi-c
|
||
|
ENDIF
|
||
|
ELSE
|
||
|
C If yy is not 0, then b belongs to ]0,pi[
|
||
|
DO j=1,3
|
||
|
yy(j)=yy(j)/y_norm
|
||
|
ENDDO
|
||
|
C
|
||
|
aa=dot(y,yy)
|
||
|
bb=dot(z,zz)
|
||
|
cc=dot(yy,yyy)
|
||
|
IF (ABS(aa).gt.1d0) aa=aa/ABS(aa)
|
||
|
IF (ABS(bb).gt.1d0) bb=bb/ABS(bb)
|
||
|
IF (ABS(cc).gt.1d0) cc=cc/ABS(cc)
|
||
|
b=ACOS(bb)
|
||
|
a=ACOS(aa)
|
||
|
c=ACOS(cc)
|
||
|
IF (yy(1).gt.zero) a=2*pi-a
|
||
|
CALL vecprod(yy,yyy,pom)
|
||
|
IF (dot(pom,zz).lt.zero) c=2*pi-c
|
||
|
ENDIF
|
||
|
C
|
||
|
END
|
||
|
|
||
|
|
||
|
SUBROUTINE vecprod(a,b,c)
|
||
|
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||
|
C %% %%
|
||
|
C %% This subroutine calculates the vector product of a and b. %%
|
||
|
C %% The result is stored in c. (same as in SRC_lapwdm/euler.f) %%
|
||
|
C %% %%
|
||
|
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||
|
C
|
||
|
IMPLICIT NONE
|
||
|
REAL(KIND=8), DIMENSION(3) :: a,b,c
|
||
|
C
|
||
|
c(1)=a(2)*b(3)-a(3)*b(2)
|
||
|
c(2)=a(3)*b(1)-a(1)*b(3)
|
||
|
c(3)=a(1)*b(2)-a(2)*b(1)
|
||
|
C
|
||
|
END
|
||
|
|
||
|
REAL(KIND=8) FUNCTION dot(a,b)
|
||
|
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||
|
C %% %%
|
||
|
C %% This function calculates the scalar product of a and b. %%
|
||
|
C %% The result is stored in dot. (same as in SRC_lapwdm/euler.f) %%
|
||
|
C %% %%
|
||
|
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||
|
C
|
||
|
IMPLICIT NONE
|
||
|
REAL(KIND=8) :: a,b
|
||
|
INTEGER :: i
|
||
|
dimension a(3),b(3)
|
||
|
dot=0
|
||
|
DO i=1,3
|
||
|
dot=dot+a(i)*b(i)
|
||
|
ENDDO
|
||
|
C
|
||
|
END
|
||
|
|
||
|
|
||
|
|