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mirror of https://github.com/LCPQ/quantum_package synced 2024-12-23 04:43:50 +01:00

Merge pull request #157 from lorenzotenti/master

print_mo works with new version of Molden, loc_cele fixed.
This commit is contained in:
Emmanuel Giner 2016-03-15 01:23:00 +01:00
commit 3223f9a14c
4 changed files with 255 additions and 259 deletions

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@ -31,7 +31,7 @@ OPENMP : 1 ; Append OpenMP flags
# -ftz : Flushes denormal results to zero # -ftz : Flushes denormal results to zero
# #
[OPT] [OPT]
FCFLAGS : -xHost -O2 -ip -ftz -g FCFLAGS : -O2 -xHost -ip -ftz
# Profiling flags # Profiling flags
################# #################

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@ -104,6 +104,8 @@ subroutine write_Ao_basis(i_unit_output)
write(i_unit_output,*)'' write(i_unit_output,*)''
write(i_unit_output,'(A47,2X,I3)')'TOTAL NUMBER OF BASIS SET SHELLS =', i_shell write(i_unit_output,'(A47,2X,I3)')'TOTAL NUMBER OF BASIS SET SHELLS =', i_shell
write(i_unit_output,'(A47,2X,I3)')'NUMBER OF CARTESIAN GAUSSIAN BASIS FUNCTIONS =', ao_num write(i_unit_output,'(A47,2X,I3)')'NUMBER OF CARTESIAN GAUSSIAN BASIS FUNCTIONS =', ao_num
! this is for the new version of molden
write(i_unit_output,'(A12)')'PP =NONE'
write(i_unit_output,*)'' write(i_unit_output,*)''
@ -126,7 +128,9 @@ subroutine write_Mo_basis(i_unit_output)
write(i_unit_output,'(18X,F8.5)')-1.d0 write(i_unit_output,'(18X,F8.5)')-1.d0
write(i_unit_output,*)'' write(i_unit_output,*)''
do i = 1, ao_num do i = 1, ao_num
write(i_unit_output,'(2X,I3, 2X A1, I3, 2X A4 , F9.6)')i,trim(element_name(int(nucl_charge(ao_nucl(i))))),ao_nucl(i),(ao_l_char_space(i)),mo_coef(i,j) ! write(i_unit_output,'(2X,I3, 2X A1, I3, 2X A4 , F9.6)')i,trim(element_name(int(nucl_charge(ao_nucl(i))))),ao_nucl(i),(ao_l_char_space(i)),mo_coef(i,j)
! F12.6 for larger coefficients...
write(i_unit_output,'(2X,I3, 2X A1, I3, 2X A4 , F12.6)')i,trim(element_name(int(nucl_charge(ao_nucl(i))))),ao_nucl(i),(ao_l_char_space(i)),mo_coef(i,j)
! write(i_unit_output,'(I3, X A1, X I3, X A4 X F16.8)')i,trim(element_name(int(nucl_charge(ao_nucl(i))))),ao_nucl(i),(ao_l_char_space(i)) ! write(i_unit_output,'(I3, X A1, X I3, X A4 X F16.8)')i,trim(element_name(int(nucl_charge(ao_nucl(i))))),ao_nucl(i),(ao_l_char_space(i))
enddo enddo
write(i_unit_output,*)'' write(i_unit_output,*)''

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@ -17,9 +17,11 @@ C
data small/1.d-6/ data small/1.d-6/
zprt=.true. zprt=.true.
niter=500 niter=1000000
conv=1.d-8 conv=1.d-8
C niter=1000000
C conv=1.d-6
write (6,5) n,m,conv write (6,5) n,m,conv
5 format (//5x,'Unitary transformation of',i3,' vectors'/ 5 format (//5x,'Unitary transformation of',i3,' vectors'/
* 5x,'following the principle of maximum overlap with a set of', * 5x,'following the principle of maximum overlap with a set of',

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@ -92,13 +92,182 @@
nrot(1) = 6 ! number of orbitals to be localized nrot(1) = 64 ! number of orbitals to be localized
integer :: index_rot(1000,1) integer :: index_rot(1000,1)
cmoref = 0.d0 cmoref = 0.d0
irot = 0
! H2 molecule for the mixed localization
do i=1,64
irot(i,1) = i+2
enddo
do i=1,17
cmoref(i+1,i,1)=1.d0
enddo
cmoref(19,19-1,1)=1.d0
cmoref(20,19-1,1)=-1.d0
cmoref(19,20-1,1)=-1.d0
cmoref(20,20-1,1)=-1.d0
cmoref(21,20-1,1)=2.d0
cmoref(22,21-1,1)=1.d0
cmoref(23,22-1,1)=1.d0
cmoref(24,23-1,1)=1.d0
cmoref(25,24-1,1)=1.d0
cmoref(26,24-1,1)=-1.d0
cmoref(25,25-1,1)=-1.d0
cmoref(26,25-1,1)=-1.d0
cmoref(27,25-1,1)=2.d0
cmoref(28,26-1,1)=1.d0
cmoref(29,27-1,1)=1.d0
cmoref(30,28-1,1)=1.d0
cmoref(31,29-1,1)=1.d0
cmoref(32,29-1,1)=-1.d0
cmoref(31,30-1,1)=-1.d0
cmoref(32,30-1,1)=-1.d0
cmoref(33,30-1,1)=2.d0
cmoref(34,31-1,1)=1.d0
cmoref(35,32-1,1)=1.d0
cmoref(36,33-1,1)=1.d0
do i=33,49
cmoref(i+5,i,1)= 1.d0
enddo
cmoref(55,52-2,1)=1.d0
cmoref(56,52-2,1)=-1.d0
cmoref(55,53-2,1)=-1.d0
cmoref(56,53-2,1)=-1.d0
cmoref(57,53-2,1)=2.d0
cmoref(58,54-2,1)=1.d0
cmoref(59,55-2,1)=1.d0
cmoref(60,56-2,1)=1.d0
cmoref(61,57-2,1)=1.d0
cmoref(62,57-2,1)=-1.d0
cmoref(61,58-2,1)=-1.d0
cmoref(62,58-2,1)=-1.d0
cmoref(63,58-2,1)=2.d0
cmoref(64,59-2,1)=1.d0
cmoref(65,60-2,1)=1.d0
cmoref(66,61-2,1)=1.d0
cmoref(67,62-2,1)=1.d0
cmoref(68,62-2,1)=-1.d0
cmoref(67,63-2,1)=-1.d0
cmoref(68,63-2,1)=-1.d0
cmoref(69,63-2,1)=2.d0
cmoref(70,64-2,1)=1.d0
cmoref(71,65-2,1)=1.d0
cmoref(72,66-2,1)=1.d0
! H2 molecule
! do i=1,66
! irot(i,1) = i
! enddo
!
! do i=1,18
! cmoref(i,i,1)=1.d0
! enddo
! cmoref(19,19,1)=1.d0
! cmoref(20,19,1)=-1.d0
! cmoref(19,20,1)=-1.d0
! cmoref(20,20,1)=-1.d0
! cmoref(21,20,1)=2.d0
! cmoref(22,21,1)=1.d0
! cmoref(23,22,1)=1.d0
! cmoref(24,23,1)=1.d0
!
!
! cmoref(25,24,1)=1.d0
! cmoref(26,24,1)=-1.d0
! cmoref(25,25,1)=-1.d0
! cmoref(26,25,1)=-1.d0
! cmoref(27,25,1)=2.d0
! cmoref(28,26,1)=1.d0
! cmoref(29,27,1)=1.d0
! cmoref(30,28,1)=1.d0
!
! cmoref(31,29,1)=1.d0
! cmoref(32,29,1)=-1.d0
! cmoref(31,30,1)=-1.d0
! cmoref(32,30,1)=-1.d0
! cmoref(33,30,1)=2.d0
! cmoref(34,31,1)=1.d0
! cmoref(35,32,1)=1.d0
! cmoref(36,33,1)=1.d0
!
! do i=34,51
! cmoref(i+3,i,1)= 1.d0
! enddo
!
! cmoref(55,52,1)=1.d0
! cmoref(56,52,1)=-1.d0
! cmoref(55,53,1)=-1.d0
! cmoref(56,53,1)=-1.d0
! cmoref(57,53,1)=2.d0
! cmoref(58,54,1)=1.d0
! cmoref(59,55,1)=1.d0
! cmoref(60,56,1)=1.d0
!
! cmoref(61,57,1)=1.d0
! cmoref(62,57,1)=-1.d0
! cmoref(61,58,1)=-1.d0
! cmoref(62,58,1)=-1.d0
! cmoref(63,58,1)=2.d0
! cmoref(64,59,1)=1.d0
! cmoref(65,60,1)=1.d0
! cmoref(66,61,1)=1.d0
!
! cmoref(67,62,1)=1.d0
! cmoref(68,62,1)=-1.d0
! cmoref(67,63,1)=-1.d0
! cmoref(68,63,1)=-1.d0
! cmoref(69,63,1)=2.d0
! cmoref(70,64,1)=1.d0
! cmoref(71,65,1)=1.d0
! cmoref(72,66,1)=1.d0
! H atom
! do i=1,33
! irot(i,1) = i
! enddo
!
! do i=1,18
! cmoref(i,i,1)=1.d0
! enddo
! cmoref(19,19,1)=1.d0
! cmoref(20,19,1)=-1.d0
! cmoref(19,20,1)=-1.d0
! cmoref(20,20,1)=-1.d0
! cmoref(21,20,1)=2.d0
! cmoref(22,21,1)=1.d0
! cmoref(23,22,1)=1.d0
! cmoref(24,23,1)=1.d0
! cmoref(25,24,1)=1.d0
! cmoref(26,24,1)=-1.d0
! cmoref(25,25,1)=-1.d0
! cmoref(26,25,1)=-1.d0
! cmoref(27,25,1)=2.d0
! cmoref(28,26,1)=1.d0
! cmoref(29,27,1)=1.d0
! cmoref(30,28,1)=1.d0
!
! cmoref(31,29,1)=1.d0
! cmoref(32,29,1)=-1.d0
! cmoref(31,30,1)=-1.d0
! cmoref(32,30,1)=-1.d0
! cmoref(33,30,1)=2.d0
! cmoref(34,31,1)=1.d0
! cmoref(35,32,1)=1.d0
! cmoref(36,33,1)=1.d0
! Definition of the index of the MO to be rotated ! Definition of the index of the MO to be rotated
! irot(2,1) = 21 ! the first mo to be rotated is the 21 th MO ! irot(2,1) = 21 ! the first mo to be rotated is the 21 th MO
@ -106,25 +275,67 @@
! irot(4,1) = 23 ! ! irot(4,1) = 23 !
! irot(5,1) = 24 ! ! irot(5,1) = 24 !
! irot(6,1) = 25 ! ! irot(6,1) = 25 !
! do i = 1,12
! irot(i,1) = i+6 !N2
! enddo ! irot(1,1) = 5
irot(1,1) = 5 ! irot(2,1) = 6
irot(2,1) = 6 ! irot(3,1) = 7
irot(3,1) = 7 ! irot(4,1) = 8
irot(4,1) = 8 ! irot(5,1) = 9
irot(5,1) = 9 ! irot(6,1) = 10
irot(6,1) = 10 !
! cmoref(5,1,1) = 1.d0 !
! cmoref(6,2,1) = 1.d0 !
! cmoref(7,3,1) = 1.d0 !
! cmoref(40,4,1) = 1.d0 !
! cmoref(41,5,1) = 1.d0 !
! cmoref(42,6,1) = 1.d0 !
!END N2
!HEXATRIENE
! irot(1,1) = 20
! irot(2,1) = 21
! irot(3,1) = 22
! irot(4,1) = 23
! irot(5,1) = 24
! irot(6,1) = 25
!
! cmoref(7,1,1) = 1.d0 !
! cmoref(26,1,1) = 1.d0 !
! cmoref(45,2,1) = 1.d0 !
! cmoref(64,2,1) = 1.d0 !
! cmoref(83,3,1) = 1.d0 !
! cmoref(102,3,1) = 1.d0 !
! cmoref(7,4,1) = 1.d0 !
! cmoref(26,4,1) = -1.d0 !
! cmoref(45,5,1) = 1.d0 !
! cmoref(64,5,1) = -1.d0 !
! cmoref(83,6,1) = 1.d0 !
! cmoref(102,6,1) = -1.d0 !
!END HEXATRIENE
!!!!H2 H2 CAS
! irot(1,1) = 1
! irot(2,1) = 2
!
! cmoref(1,1,1) = 1.d0
! cmoref(37,2,1) = 1.d0
!END H2
!!!! LOCALIZATION ON THE BASIS FUNCTIONS
! do i = 1, nrot(1)
! irot(i,1) = i
! cmoref(i,i,1) = 1.d0
! enddo
!END BASISLOC
! do i = 1, nrot(1)
! irot(i,1) = 4+i
! enddo
do i = 1, nrot(1) do i = 1, nrot(1)
print*,'irot(i,1) = ',irot(i,1) print*,'irot(i,1) = ',irot(i,1)
enddo enddo
pause ! pause
cmoref(4,1,1) = 1.d0 ! 2S function
cmoref(5,2,1) = 1.d0 ! 2S function
cmoref(6,3,1) = 1.d0 ! 2S function
cmoref(19,4,1) = 1.d0 ! 2S function
cmoref(20,5,1) = 1.d0 ! 2S function
cmoref(21,6,1) = 1.d0 ! 2S function
! you define the guess vectors that you want ! you define the guess vectors that you want
! the new MO to be close to ! the new MO to be close to
@ -138,233 +349,21 @@
! own guess vectors for the MOs ! own guess vectors for the MOs
! The new MOs are provided in output ! The new MOs are provided in output
! in the same order than the guess MOs ! in the same order than the guess MOs
! do i = 1, nrot(1)
! C-C bonds ! j = 5+(i-1)*15
! 1-2 ! cmoref(j,i,1) = 0.2d0
! i_atom = 1 ! cmoref(j+3,i,1) = 0.12d0
! shift = (i_atom -1) * 15 ! print*,'j = ',j
! cmoref(1+shift,1,1) = -0.012d0 ! 2S function ! enddo
! cmoref(2+shift,1,1) = 0.18d0 ! ! pause
! cmoref(3+shift,1,1) = 0.1d0 !
! cmoref(5+shift,1,1) = -0.1d0 ! 2pX function
! cmoref(6+shift,1,1) = -0.1d0 ! 2pZ function
! i_atom = 2
! shift = (i_atom -1) * 15
! cmoref(1+shift,1,1) = -0.012d0 ! 2S function
! cmoref(2+shift,1,1) = 0.18d0 !
! cmoref(3+shift,1,1) = 0.1d0 !
! cmoref(5+shift,1,1) = 0.1d0 ! 2pX function
! cmoref(6+shift,1,1) = 0.1d0 ! 2pZ function
! ! 1-3
! i_atom = 1
! shift = (i_atom -1) * 15
! cmoref(1+shift,2,1) = -0.012d0 ! 2S function
! cmoref(2+shift,2,1) = 0.18d0 !
! cmoref(3+shift,2,1) = 0.1d0 !
! cmoref(5+shift,2,1) = 0.1d0 ! 2pX function
! cmoref(6+shift,2,1) = -0.1d0 ! 2pZ function
! i_atom = 3
! shift = (i_atom -1) * 15
! cmoref(1+shift,2,1) = -0.012d0 ! 2S function
! cmoref(2+shift,2,1) = 0.18d0 !
! cmoref(3+shift,2,1) = 0.1d0 !
! cmoref(5+shift,2,1) = -0.1d0 ! 2pX function
! cmoref(6+shift,2,1) = 0.1d0 ! 2pZ function
! ! 4-6
! i_atom = 4
! shift = (i_atom -1) * 15
! cmoref(1+shift,3,1) = -0.012d0 ! 2S function
! cmoref(2+shift,3,1) = 0.18d0 !
! cmoref(3+shift,3,1) = 0.1d0 !
! cmoref(5+shift,3,1) = 0.1d0 ! 2pX function
! cmoref(6+shift,3,1) = -0.1d0 ! 2pZ function
! i_atom = 6
! shift = (i_atom -1) * 15
! cmoref(1+shift,3,1) = -0.012d0 ! 2S function
! cmoref(2+shift,3,1) = 0.18d0 !
! cmoref(3+shift,3,1) = 0.1d0 !
! cmoref(5+shift,3,1) = -0.1d0 ! 2pX function
! cmoref(6+shift,3,1) = 0.1d0 ! 2pZ function
! ! 6-5
! i_atom = 6
! shift = (i_atom -1) * 15
! cmoref(1+shift,4,1) = -0.012d0 ! 2S function
! cmoref(2+shift,4,1) = 0.18d0 !
! cmoref(3+shift,4,1) = 0.1d0 !
! cmoref(5+shift,4,1) = 0.1d0 ! 2pX function
! cmoref(6+shift,4,1) = 0.1d0 ! 2pZ function
! i_atom = 5
! shift = (i_atom -1) * 15
! cmoref(1+shift,4,1) = -0.012d0 ! 2S function
! cmoref(2+shift,4,1) = 0.18d0 !
! cmoref(3+shift,4,1) = 0.1d0 !
! cmoref(5+shift,4,1) = -0.1d0 ! 2pX function
! cmoref(6+shift,4,1) = -0.1d0 ! 2pZ function
! ! 2-4
! i_atom = 2
! shift = (i_atom -1) * 15
! cmoref(1+shift,5,1) = -0.012d0 ! 2S function
! cmoref(2+shift,5,1) = 0.18d0 !
! cmoref(3+shift,5,1) = 0.1d0 !
! cmoref(6+shift,5,1) = 0.1d0 ! 2pZ function
! i_atom = 4
! shift = (i_atom -1) * 15
! cmoref(1+shift,5,1) = -0.012d0 ! 2S function
! cmoref(2+shift,5,1) = 0.18d0 !
! cmoref(3+shift,5,1) = 0.1d0 !
! cmoref(6+shift,5,1) = -0.1d0 ! 2pZ function
! ! 3-5
! i_atom = 3
! shift = (i_atom -1) * 15
! cmoref(1+shift,6,1) = -0.012d0 ! 2S function
! cmoref(2+shift,6,1) = 0.18d0 !
! cmoref(3+shift,6,1) = 0.1d0 !
! cmoref(6+shift,6,1) = 0.1d0 ! 2pZ function
! i_atom = 5
! shift = (i_atom -1) * 15
! cmoref(1+shift,6,1) = -0.012d0 ! 2S function
! cmoref(2+shift,6,1) = 0.18d0 !
! cmoref(3+shift,6,1) = 0.1d0 !
! cmoref(6+shift,6,1) = -0.1d0 ! 2pZ function
! ! C-H bonds
! ! 2-7
! i_atom = 2
! shift = (i_atom -1) * 15
! cmoref(1+shift,7,1) = -0.012d0 ! 2S function
! cmoref(2+shift,7,1) = 0.18d0 !
! cmoref(3+shift,7,1) = 0.1d0 !
! cmoref(5+shift,7,1) = -0.1d0 ! 2pX function
! cmoref(6+shift,7,1) = 0.1d0 ! 2pZ function
!
! i_atom = 7
! shift_h = (6-1) * 15 + (i_atom - 6)*5
! cmoref(1+shift_h,7,1) = 0.12d0 ! 1S function
! ! 4-10
! i_atom = 4
! shift = (i_atom -1) * 15
! cmoref(1+shift,8,1) = -0.012d0 ! 2S function
! cmoref(2+shift,8,1) = 0.18d0 !
! cmoref(3+shift,8,1) = 0.1d0 !
! cmoref(5+shift,8,1) = -0.1d0 ! 2pX function
! cmoref(6+shift,8,1) = -0.1d0 ! 2pZ function
!
! i_atom = 10
! shift_h = (6-1) * 15 + (i_atom - 6)*5
! cmoref(1+shift_h,8,1) = 0.12d0 ! 1S function
! ! 5-11
! i_atom = 5
! shift = (i_atom -1) * 15
! cmoref(1+shift,9,1) = -0.012d0 ! 2S function
! cmoref(2+shift,9,1) = 0.18d0 !
! cmoref(3+shift,9,1) = 0.1d0 !
! cmoref(5+shift,9,1) = 0.1d0 ! 2pX function
! cmoref(6+shift,9,1) = -0.1d0 ! 2pZ function
!
! i_atom = 11
! shift_h = (6-1) * 15 + (i_atom - 6)*5
! cmoref(1+shift_h,9,1) = 0.12d0 ! 1S function
! ! 3-8
! i_atom = 3
! shift = (i_atom -1) * 15
! cmoref(1+shift,10,1) = -0.012d0 ! 2S function
! cmoref(2+shift,10,1) = 0.18d0 !
! cmoref(3+shift,10,1) = 0.1d0 !
!
! cmoref(5+shift,10,1) = 0.1d0 ! 2pX function
! cmoref(6+shift,10,1) = 0.1d0 ! 2pZ function
!
! i_atom = 8
! shift_h = (6-1) * 15 + (i_atom - 6)*5
! cmoref(1+shift_h,10,1) = 0.12d0 ! 1S function
! ! 1-9
! i_atom = 1
! shift = (i_atom -1) * 15
! cmoref(1+shift,11,1) = -0.012d0 ! 2S function
! cmoref(2+shift,11,1) = 0.18d0 !
! cmoref(3+shift,11,1) = 0.1d0 !
!
! cmoref(6+shift,11,1) = 0.1d0 ! 2pZ function
! i_atom = 9
! shift_h = (6-1) * 15 + (i_atom - 6)*5
! cmoref(1+shift_h,11,1) = 0.12d0 ! 1S function
!
! ! 6-12
! i_atom = 6
! shift = (i_atom -1) * 15
! cmoref(1+shift,12,1) = -0.012d0 ! 2S function
! cmoref(2+shift,12,1) = 0.18d0 !
! cmoref(3+shift,12,1) = 0.1d0 !
!
! cmoref(6+shift,12,1) = -0.1d0 ! 2pZ function
! i_atom = 12
! shift_h = (6-1) * 15 + (i_atom - 6)*5
! cmoref(1+shift_h,12,1) = 0.12d0 ! 1S function
! cmoref(12,1,1) = 1.d0 !
! cmoref(21,2,1) = 1.d0 !
! cmoref(30,2,1) = 1.d0 !
! cmoref(39,3,1) = 1.d0 !
! cmoref(48,3,1) = 1.d0 !
! cmoref(3,4,1) = 1.d0 !
! cmoref(12,4,1) =-1.d0 !
! cmoref(21,5,1) = 1.d0 !
! cmoref(30,5,1) =-1.d0 !
! cmoref(39,6,1) = 1.d0 !
! cmoref(48,6,1) =-1.d0 !
print*,'passed the definition of the referent vectors ' print*,'passed the definition of the referent vectors '
!Building the S (overlap) matrix in the AO basis.
do i = 1, ao_num do i = 1, ao_num
do j = 1, ao_num do j =1, ao_num
s(i,j,1) = ao_overlap(i,j) s(i,j,1) = ao_overlap(i,j)
enddo enddo
enddo enddo
!Now big loop over symmetry !Now big loop over symmetry
@ -398,20 +397,13 @@
! do i=1,nmo(isym) ! do i=1,nmo(isym)
do i=1,ao_num
do j=1,nrot(isym) do j=1,nrot(isym)
do i=1,ao_num
ddum(i,j)=0.d0 ddum(i,j)=0.d0
do k=1,ao_num
do k=1,ao_num ddum(i,j)=ddum(i,j)+s(i,k,isym)*cmo(k,irot(j,isym),isym)
enddo
ddum(i,j)=ddum(i,j)+s(i,k,isym)*cmo(k,irot(j,isym),isym) enddo
enddo
enddo
enddo enddo
@ -441,7 +433,7 @@
do i=1,nrot(isym) do i=1,nrot(isym)
do j=1,ao_num do j=1,ao_num
write (6,*) 'isym,',isym,nrot(isym),nmo(isym) ! write (6,*) 'isym,',isym,nrot(isym),nmo(isym)
newcmo(j,irot(i,isym),isym)=0.d0 newcmo(j,irot(i,isym),isym)=0.d0
do k=1,nrot(isym) do k=1,nrot(isym)
newcmo(j,irot(i,isym),isym)=newcmo(j,irot(i,isym),isym) + cmo(j,irot(k,isym),isym)*t(k,i) newcmo(j,irot(i,isym),isym)=newcmo(j,irot(i,isym),isym) + cmo(j,irot(k,isym),isym)*t(k,i)
@ -459,7 +451,7 @@
enddo !big loop over symmetry enddo !big loop over symmetry
10 format (4E20.12) 10 format (4E18.12)
! Now we copyt the newcmo into the mo_coef ! Now we copyt the newcmo into the mo_coef
@ -472,9 +464,7 @@
enddo enddo
enddo enddo
enddo enddo
! if(dabs(newcmo(3,19,1) - mo_coef(3,19)) .gt.1.d-10 )then ! pause
print*,'mo_coef(3,19)',mo_coef(3,19)
pause
! we say that it hase been touched, and valid and that everything that ! we say that it hase been touched, and valid and that everything that