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2ef517488c
Author | SHA1 | Date | |
---|---|---|---|
2ef517488c | |||
a128c20afa | |||
5902f3231e |
@ -1,6 +1,6 @@
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! -*- F90 -*-
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BEGIN_PROVIDER [logical, bavard]
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bavard=.true.
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bavard=.false.
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! bavard=.false.
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END_PROVIDER
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@ -55,7 +55,6 @@
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end do
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end do
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write(6,*) ' provided integrals (PQ|xx) '
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END_PROVIDER
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@ -116,7 +115,6 @@ BEGIN_PROVIDER [real*8, bielec_PxxQ, (mo_num,n_core_orb+n_act_orb,n_core_orb+n_a
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end do
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end do
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end do
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write(6,*) ' provided integrals (Px|xQ) '
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END_PROVIDER
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@ -146,6 +144,5 @@ BEGIN_PROVIDER [real*8, bielecCI, (n_act_orb,n_act_orb,n_act_orb, mo_num)]
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end do
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end do
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end do
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write(6,*) ' provided integrals (tu|xP) '
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END_PROVIDER
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@ -84,7 +84,6 @@
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end do
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end do
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end do
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write(6,*) ' transformed PQxx'
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END_PROVIDER
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@ -176,7 +175,6 @@ BEGIN_PROVIDER [real*8, bielec_PxxQ_no, (mo_num,n_core_orb+n_act_orb,n_core_orb+
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end do
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end do
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end do
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write(6,*) ' transformed PxxQ '
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END_PROVIDER
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@ -267,7 +265,6 @@ BEGIN_PROVIDER [real*8, bielecCI_no, (n_act_orb,n_act_orb,n_act_orb, mo_num)]
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end do
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end do
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end do
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write(6,*) ' transformed tuvP '
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END_PROVIDER
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@ -12,24 +12,32 @@ subroutine run
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implicit none
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double precision :: energy_old, energy
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logical :: converged
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integer :: iteration
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converged = .False.
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energy = 0.d0
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! do while (.not.converged)
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N_det = 1
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TOUCH N_det psi_det psi_coef
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mo_label = "MCSCF"
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iteration = 1
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do while (.not.converged)
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call run_cipsi
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write(6,*) ' total energy = ',eone+etwo+ecore
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mo_label = "MCSCF"
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mo_label = "Natural"
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mo_coef(:,:) = NatOrbsFCI(:,:)
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call save_mos
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call driver_optorb
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energy_old = energy
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energy = eone+etwo+ecore
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converged = dabs(energy - energy_old) < 1.d-10
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! enddo
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call write_time(6)
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call write_int(6,iteration,'CAS-SCF iteration')
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call write_double(6,energy,'CAS-SCF energy')
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call write_double(6,energy_improvement, 'Predicted energy improvement')
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converged = dabs(energy_improvement) < thresh_scf
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mo_coef = NewOrbs
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call save_mos
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call map_deinit(mo_integrals_map)
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N_det = 1
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iteration += 1
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FREE mo_integrals_map mo_two_e_integrals_in_map psi_det psi_coef
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SOFT_TOUCH mo_coef N_det
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enddo
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end
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@ -1,70 +1,19 @@
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use bitmasks
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BEGIN_PROVIDER [real*8, D0tu, (n_act_orb,n_act_orb) ]
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BEGIN_DOC
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! the first-order density matrix in the basis of the starting MOs
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! matrices are state averaged
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!
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! we use the spin-free generators of mono-excitations
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! E_pq destroys q and creates p
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! D_pq = <0|E_pq|0> = D_qp
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!
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END_DOC
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implicit none
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integer :: t,u,v,x,mu,nu,istate,ispin,jspin,ihole,ipart,jhole,jpart
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integer :: ierr
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integer(bit_kind) :: det_mu(N_int,2)
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integer(bit_kind) :: det_mu_ex(N_int,2)
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integer(bit_kind) :: det_mu_ex1(N_int,2)
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integer(bit_kind) :: det_mu_ex2(N_int,2)
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real*8 :: phase1,phase2,term
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integer :: nu1,nu2
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integer :: ierr1,ierr2
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real*8 :: cI_mu(N_states)
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BEGIN_DOC
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! the first-order density matrix in the basis of the starting MOs.
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! matrix is state averaged.
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END_DOC
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integer :: t,u
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write(6,*) ' providing density matrices D0 and P0 '
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D0tu = 0.d0
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! first loop: we apply E_tu, once for D_tu, once for -P_tvvu
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do mu=1,n_det
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call det_extract(det_mu,mu,N_int)
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do istate=1,n_states
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cI_mu(istate)=psi_coef(mu,istate)
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end do
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do u=1,n_act_orb
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do t=1,n_act_orb
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ipart=list_act(t)
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do u=1,n_act_orb
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ihole=list_act(u)
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! apply E_tu
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call det_copy(det_mu,det_mu_ex1,N_int)
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call det_copy(det_mu,det_mu_ex2,N_int)
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call do_spinfree_mono_excitation(det_mu,det_mu_ex1 &
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,det_mu_ex2,nu1,nu2,ihole,ipart,phase1,phase2,ierr1,ierr2)
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! det_mu_ex1 is in the list
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if (nu1.ne.-1) then
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do istate=1,n_states
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term=cI_mu(istate)*psi_coef(nu1,istate)*phase1
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D0tu(t,u)+=term
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end do
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end if
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! det_mu_ex2 is in the list
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if (nu2.ne.-1) then
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do istate=1,n_states
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term=cI_mu(istate)*psi_coef(nu2,istate)*phase2
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D0tu(t,u)+=term
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end do
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end if
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end do
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end do
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end do
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! we average by just dividing by the number of states
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do x=1,n_act_orb
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do v=1,n_act_orb
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D0tu(v,x)*=1.0D0/dble(N_states)
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end do
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end do
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D0tu(t,u) = one_e_dm_mo_alpha_average( list_act(t), list_act(u) ) + &
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one_e_dm_mo_beta_average ( list_act(t), list_act(u) )
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enddo
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enddo
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END_PROVIDER
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@ -90,7 +39,9 @@ BEGIN_PROVIDER [real*8, P0tuvx, (n_act_orb,n_act_orb,n_act_orb,n_act_orb) ]
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integer(bit_kind), dimension(N_int,2) :: det_mu_ex1, det_mu_ex11, det_mu_ex12
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integer(bit_kind), dimension(N_int,2) :: det_mu_ex2, det_mu_ex21, det_mu_ex22
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write(6,*) ' providing density matrices D0 and P0 '
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if (bavard) then
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write(6,*) ' providing density matrix P0'
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endif
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P0tuvx = 0.d0
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@ -31,6 +31,8 @@ subroutine do_signed_mono_excitation(key1,key2,nu,ihole,ipart, &
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! get the number in the list
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found=.false.
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nu=0
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!TODO BOTTLENECK
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do while (.not.found)
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nu+=1
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if (nu.gt.N_det) then
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@ -50,13 +52,6 @@ subroutine do_signed_mono_excitation(key1,key2,nu,ihole,ipart, &
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end do
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end if
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end do
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! if (found) then
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! if (nu.eq.-1) then
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! write(6,*) ' image not found in the list, thus nu = ',nu
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! else
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! write(6,*) ' found in the list as No ',nu,' phase = ',phase
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! end if
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! end if
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end if
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!
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! we found the new string, the phase, and possibly the number in the list
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@ -1,32 +1,3 @@
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subroutine driver_optorb
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implicit none
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integer :: i,j
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write(6,*)
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! write(6,*) ' <0|H|0> (qp) = ',psi_energy_with_nucl_rep(1)
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write(6,*) ' energy improvement = ',energy_improvement
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! write(6,*) ' new energy = ',psi_energy_with_nucl_rep(1)+energy_improvement
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write(6,*)
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write(6,*)
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write(6,*) ' creating new orbitals '
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do i=1,mo_num
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write(6,*) ' Orbital No ',i
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write(6,'(5F14.6)') (NewOrbs(j,i),j=1,mo_num)
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write(6,*)
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end do
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mo_label = "Natural"
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do i=1,mo_num
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do j=1,ao_num
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mo_coef(j,i)=NewOrbs(j,i)
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end do
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end do
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call save_mos
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call map_deinit(mo_integrals_map)
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FREE mo_integrals_map mo_coef mo_two_e_integrals_in_map
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write(6,*)
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write(6,*) ' ... all done '
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end
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subroutine driver_optorb
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implicit none
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end
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@ -6,7 +6,6 @@ BEGIN_PROVIDER [ integer, nMonoEx ]
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END_DOC
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implicit none
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nMonoEx=n_core_orb*n_act_orb+n_core_orb*n_virt_orb+n_act_orb*n_virt_orb
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write(6,*) ' nMonoEx = ',nMonoEx
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END_PROVIDER
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BEGIN_PROVIDER [integer, excit, (2,nMonoEx)]
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@ -87,9 +86,11 @@ BEGIN_PROVIDER [real*8, gradvec, (nMonoEx)]
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norm_grad+=gradvec(indx)*gradvec(indx)
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end do
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norm_grad=sqrt(norm_grad)
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write(6,*)
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write(6,*) ' Norm of the orbital gradient (via <0|EH|0>) : ', norm_grad
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write(6,*)
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if (bavard) then
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write(6,*)
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write(6,*) ' Norm of the orbital gradient (via <0|EH|0>) : ', norm_grad
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write(6,*)
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endif
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END_PROVIDER
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@ -118,17 +119,11 @@ subroutine calc_grad_elem(ihole,ipart,res)
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call do_signed_mono_excitation(det_mu,det_mu_ex,nu &
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,ihole,ipart,ispin,phase,ierr)
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if (ierr.eq.1) then
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! write(6,*)
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! write(6,*) ' mu = ',mu
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! call print_det(det_mu,N_int)
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! write(6,*) ' generated nu = ',nu,' for excitation ',ihole,' -> ',ipart,' ierr = ',ierr,' phase = ',phase,' ispin = ',ispin
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! call print_det(det_mu_ex,N_int)
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call i_H_psi(det_mu_ex,psi_det,psi_coef,N_int &
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,N_det,N_det,N_states,i_H_psi_array)
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do istate=1,N_states
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res+=i_H_psi_array(istate)*psi_coef(mu,istate)*phase
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end do
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! write(6,*) ' contribution = ',i_H_psi_array(1)*psi_coef(mu,1)*phase,res
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end if
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end do
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end do
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@ -176,9 +171,11 @@ BEGIN_PROVIDER [real*8, gradvec2, (nMonoEx)]
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norm_grad+=gradvec2(indx)*gradvec2(indx)
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end do
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norm_grad=sqrt(norm_grad)
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write(6,*)
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write(6,*) ' Norm of the orbital gradient (via D, P and integrals): ', norm_grad
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write(6,*)
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if (bavard) then
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write(6,*)
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write(6,*) ' Norm of the orbital gradient (via D, P and integrals): ', norm_grad
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write(6,*)
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endif
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END_PROVIDER
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@ -14,8 +14,10 @@ BEGIN_PROVIDER [real*8, hessmat, (nMonoEx,nMonoEx)]
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character*3 :: iexc,jexc
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real*8 :: res
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write(6,*) ' providing Hessian matrix hessmat '
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write(6,*) ' nMonoEx = ',nMonoEx
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if (bavard) then
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write(6,*) ' providing Hessian matrix hessmat '
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write(6,*) ' nMonoEx = ',nMonoEx
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endif
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do indx=1,nMonoEx
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do jndx=1,nMonoEx
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@ -32,8 +34,6 @@ BEGIN_PROVIDER [real*8, hessmat, (nMonoEx,nMonoEx)]
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jpart=excit(2,jndx)
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jexc=excit_class(jndx)
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call calc_hess_elem(ihole,ipart,jhole,jpart,res)
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! write(6,*) ' Hessian ',ihole,'->',ipart &
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! ,' (',iexc,')',jhole,'->',jpart,' (',jexc,')',res
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hessmat(indx,jndx)=res
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hessmat(jndx,indx)=res
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end do
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@ -198,8 +198,10 @@ BEGIN_PROVIDER [real*8, hessmat2, (nMonoEx,nMonoEx)]
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real*8 :: hessmat_iatb
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real*8 :: hessmat_taub
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write(6,*) ' providing Hessian matrix hessmat2 '
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write(6,*) ' nMonoEx = ',nMonoEx
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if (bavard) then
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write(6,*) ' providing Hessian matrix hessmat2 '
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write(6,*) ' nMonoEx = ',nMonoEx
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endif
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indx=1
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do i=1,n_core_orb
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@ -214,7 +216,6 @@ BEGIN_PROVIDER [real*8, hessmat2, (nMonoEx,nMonoEx)]
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do u=ustart,n_act_orb
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hessmat2(indx,jndx)=hessmat_itju(i,t,j,u)
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hessmat2(jndx,indx)=hessmat2(indx,jndx)
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! write(6,*) ' result I :',i,t,j,u,indx,jndx,hessmat(indx,jndx),hessmat2(indx,jndx)
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jndx+=1
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end do
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end do
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@ -294,7 +295,6 @@ real*8 function hessmat_itju(i,t,j,u)
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integer :: i,t,j,u,ii,tt,uu,v,vv,x,xx,y,jj
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real*8 :: term,t2
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! write(6,*) ' hessmat_itju ',i,t,j,u
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ii=list_core(i)
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tt=list_act(t)
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if (i.eq.j) then
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@ -340,8 +340,6 @@ real*8 function hessmat_itju(i,t,j,u)
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end do
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end do
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end do
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!!! write(6,*) ' direct diff ',i,t,j,u,term,term2
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!!! term=term2
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end if
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else
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! it/ju
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@ -382,7 +380,6 @@ real*8 function hessmat_itja(i,t,j,a)
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integer :: i,t,j,a,ii,tt,jj,aa,v,vv,x,y
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real*8 :: term
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! write(6,*) ' hessmat_itja ',i,t,j,a
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! it/ja
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ii=list_core(i)
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tt=list_act(t)
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@ -416,7 +413,6 @@ real*8 function hessmat_itua(i,t,u,a)
|
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integer :: i,t,u,a,ii,tt,uu,aa,v,vv,x,xx,u3,t3,v3
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real*8 :: term
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! write(6,*) ' hessmat_itua ',i,t,u,a
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ii=list_core(i)
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tt=list_act(t)
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t3=t+n_core_orb
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@ -457,7 +453,6 @@ real*8 function hessmat_iajb(i,a,j,b)
|
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implicit none
|
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integer :: i,a,j,b,ii,aa,jj,bb
|
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real*8 :: term
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! write(6,*) ' hessmat_iajb ',i,a,j,b
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|
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ii=list_core(i)
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aa=list_virt(a)
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||||
@ -495,7 +490,6 @@ real*8 function hessmat_iatb(i,a,t,b)
|
||||
integer :: i,a,t,b,ii,aa,tt,bb,v,vv,x,y,v3,t3
|
||||
real*8 :: term
|
||||
|
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! write(6,*) ' hessmat_iatb ',i,a,t,b
|
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ii=list_core(i)
|
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aa=list_virt(a)
|
||||
tt=list_act(t)
|
||||
@ -552,7 +546,6 @@ real*8 function hessmat_taub(t,a,u,b)
|
||||
end do
|
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end do
|
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term=t1+t2+t3
|
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! write(6,*) ' Hess taub ',t,a,t1,t2,t3
|
||||
else
|
||||
bb=list_virt(b)
|
||||
! ta/tb b/=a
|
||||
|
@ -14,10 +14,12 @@
|
||||
occnum(list_act(i))=occ_act(n_act_orb-i+1)
|
||||
end do
|
||||
|
||||
write(6,*) ' occupation numbers '
|
||||
do i=1,mo_num
|
||||
write(6,*) i,occnum(i)
|
||||
end do
|
||||
if (bavard) then
|
||||
write(6,*) ' occupation numbers '
|
||||
do i=1,mo_num
|
||||
write(6,*) i,occnum(i)
|
||||
end do
|
||||
endif
|
||||
|
||||
END_PROVIDER
|
||||
|
||||
@ -32,14 +34,12 @@ END_PROVIDER
|
||||
|
||||
call lapack_diag(occ_act,natorbsCI,D0tu,n_act_orb,n_act_orb)
|
||||
|
||||
write(6,*) ' found occupation numbers as '
|
||||
do i=1,n_act_orb
|
||||
write(6,*) i,occ_act(i)
|
||||
end do
|
||||
|
||||
if (bavard) then
|
||||
!
|
||||
|
||||
write(6,*) ' found occupation numbers as '
|
||||
do i=1,n_act_orb
|
||||
write(6,*) i,occ_act(i)
|
||||
end do
|
||||
|
||||
integer :: nmx
|
||||
real*8 :: xmx
|
||||
do i=1,n_act_orb
|
||||
@ -152,7 +152,6 @@ BEGIN_PROVIDER [real*8, P0tuvx_no, (n_act_orb,n_act_orb,n_act_orb,n_act_orb)]
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
write(6,*) ' transformed P0tuvx '
|
||||
|
||||
END_PROVIDER
|
||||
|
||||
@ -198,7 +197,6 @@ BEGIN_PROVIDER [real*8, one_ints_no, (mo_num,mo_num)]
|
||||
one_ints_no(j,list_act(p))=d(p)
|
||||
end do
|
||||
end do
|
||||
write(6,*) ' transformed one_ints '
|
||||
END_PROVIDER
|
||||
|
||||
|
||||
@ -226,148 +224,5 @@ BEGIN_PROVIDER [real*8, NatOrbsFCI, (ao_num,mo_num)]
|
||||
NatOrbsFCI(j,list_act(p))=d(p)
|
||||
end do
|
||||
end do
|
||||
write(6,*) ' transformed orbitals '
|
||||
END_PROVIDER
|
||||
|
||||
|
||||
|
||||
|
||||
|
||||
|
||||
subroutine trf_to_natorb()
|
||||
implicit none
|
||||
BEGIN_DOC
|
||||
! save the diagonal somewhere, in inverse order
|
||||
! 4-index-transform the 2-particle density matrix over active orbitals
|
||||
! correct the bielectronic integrals
|
||||
! correct the monoelectronic integrals
|
||||
! put integrals on file, as well orbitals, and the density matrices
|
||||
!
|
||||
END_DOC
|
||||
integer :: i,j,k,l,t,u,p,q,pp
|
||||
real*8 :: d(n_act_orb),d1(n_act_orb),d2(n_act_orb)
|
||||
|
||||
! we recalculate total energies
|
||||
write(6,*)
|
||||
write(6,*) ' recalculating energies after the transformation '
|
||||
write(6,*)
|
||||
write(6,*)
|
||||
real*8 :: e_one_all
|
||||
real*8 :: e_two_all
|
||||
integer :: ii
|
||||
integer :: jj
|
||||
integer :: t3
|
||||
integer :: tt
|
||||
integer :: u3
|
||||
integer :: uu
|
||||
integer :: v
|
||||
integer :: v3
|
||||
integer :: vv
|
||||
integer :: x
|
||||
integer :: x3
|
||||
integer :: xx
|
||||
|
||||
e_one_all=0.D0
|
||||
e_two_all=0.D0
|
||||
do i=1,n_core_orb
|
||||
ii=list_core(i)
|
||||
e_one_all+=2.D0*one_ints_no(ii,ii)
|
||||
do j=1,n_core_orb
|
||||
jj=list_core(j)
|
||||
e_two_all+=2.D0*bielec_PQxx_no(ii,ii,j,j)-bielec_PQxx_no(ii,jj,j,i)
|
||||
end do
|
||||
do t=1,n_act_orb
|
||||
tt=list_act(t)
|
||||
t3=t+n_core_orb
|
||||
e_two_all += occnum(list_act(t)) * &
|
||||
(2.d0*bielec_PQxx_no(tt,tt,i,i) - bielec_PQxx_no(tt,ii,i,t3))
|
||||
end do
|
||||
end do
|
||||
|
||||
|
||||
|
||||
do t=1,n_act_orb
|
||||
tt=list_act(t)
|
||||
e_one_all += occnum(list_act(t))*one_ints_no(tt,tt)
|
||||
do u=1,n_act_orb
|
||||
uu=list_act(u)
|
||||
do v=1,n_act_orb
|
||||
v3=v+n_core_orb
|
||||
do x=1,n_act_orb
|
||||
x3=x+n_core_orb
|
||||
e_two_all +=P0tuvx_no(t,u,v,x)*bielec_PQxx_no(tt,uu,v3,x3)
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
write(6,*) ' e_one_all = ',e_one_all
|
||||
write(6,*) ' e_two_all = ',e_two_all
|
||||
ecore =nuclear_repulsion
|
||||
ecore_bis=nuclear_repulsion
|
||||
do i=1,n_core_orb
|
||||
ii=list_core(i)
|
||||
ecore +=2.D0*one_ints_no(ii,ii)
|
||||
ecore_bis+=2.D0*one_ints_no(ii,ii)
|
||||
do j=1,n_core_orb
|
||||
jj=list_core(j)
|
||||
ecore +=2.D0*bielec_PQxx_no(ii,ii,j,j)-bielec_PQxx_no(ii,jj,j,i)
|
||||
ecore_bis+=2.D0*bielec_PxxQ_no(ii,i,j,jj)-bielec_PxxQ_no(ii,j,j,ii)
|
||||
end do
|
||||
end do
|
||||
eone =0.D0
|
||||
eone_bis=0.D0
|
||||
etwo =0.D0
|
||||
etwo_bis=0.D0
|
||||
etwo_ter=0.D0
|
||||
do t=1,n_act_orb
|
||||
tt=list_act(t)
|
||||
t3=t+n_core_orb
|
||||
eone += occnum(list_act(t))*one_ints_no(tt,tt)
|
||||
eone_bis += occnum(list_act(t))*one_ints_no(tt,tt)
|
||||
do i=1,n_core_orb
|
||||
ii=list_core(i)
|
||||
eone += occnum(list_act(t)) * &
|
||||
(2.D0*bielec_PQxx_no(tt,tt,i,i ) - bielec_PQxx_no(tt,ii,i,t3))
|
||||
eone_bis += occnum(list_act(t)) * &
|
||||
(2.D0*bielec_PxxQ_no(tt,t3,i,ii) - bielec_PxxQ_no(tt,i ,i,tt))
|
||||
end do
|
||||
do u=1,n_act_orb
|
||||
uu=list_act(u)
|
||||
u3=u+n_core_orb
|
||||
do v=1,n_act_orb
|
||||
vv=list_act(v)
|
||||
v3=v+n_core_orb
|
||||
do x=1,n_act_orb
|
||||
xx=list_act(x)
|
||||
x3=x+n_core_orb
|
||||
real*8 :: h1,h2,h3
|
||||
h1=bielec_PQxx_no(tt,uu,v3,x3)
|
||||
h2=bielec_PxxQ_no(tt,u3,v3,xx)
|
||||
h3=bielecCI_no(t,u,v,xx)
|
||||
etwo +=P0tuvx_no(t,u,v,x)*h1
|
||||
etwo_bis+=P0tuvx_no(t,u,v,x)*h2
|
||||
etwo_ter+=P0tuvx_no(t,u,v,x)*h3
|
||||
if ((abs(h1-h2).gt.1.D-14).or.(abs(h1-h3).gt.1.D-14)) then
|
||||
write(6,9901) t,u,v,x,h1,h2,h3
|
||||
9901 format('aie: ',4I4,3E20.12)
|
||||
end if
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
|
||||
write(6,*) ' energy contributions '
|
||||
write(6,*) ' core energy = ',ecore,' using PQxx integrals '
|
||||
write(6,*) ' core energy (bis) = ',ecore,' using PxxQ integrals '
|
||||
write(6,*) ' 1el energy = ',eone ,' using PQxx integrals '
|
||||
write(6,*) ' 1el energy (bis) = ',eone ,' using PxxQ integrals '
|
||||
write(6,*) ' 2el energy = ',etwo ,' using PQxx integrals '
|
||||
write(6,*) ' 2el energy (bis) = ',etwo_bis,' using PxxQ integrals '
|
||||
write(6,*) ' 2el energy (ter) = ',etwo_ter,' using tuvP integrals '
|
||||
write(6,*) ' ----------------------------------------- '
|
||||
write(6,*) ' sum of all = ',eone+etwo+ecore
|
||||
write(6,*)
|
||||
SOFT_TOUCH ecore ecore_bis eone eone_bis etwo etwo_bis etwo_ter
|
||||
|
||||
end subroutine trf_to_natorb
|
||||
|
||||
|
@ -1,222 +1,178 @@
|
||||
! -*- F90 -*-
|
||||
BEGIN_PROVIDER [real*8, SXmatrix, (nMonoEx+1,nMonoEx+1)]
|
||||
implicit none
|
||||
integer :: i,j
|
||||
do i=1,nMonoEx+1
|
||||
do j=1,nMonoEx+1
|
||||
SXmatrix(i,j)=0.D0
|
||||
end do
|
||||
end do
|
||||
|
||||
do i=1,nMonoEx
|
||||
SXmatrix(1,i+1)=gradvec2(i)
|
||||
SXmatrix(1+i,1)=gradvec2(i)
|
||||
end do
|
||||
|
||||
do i=1,nMonoEx
|
||||
do j=1,nMonoEx
|
||||
SXmatrix(i+1,j+1)=hessmat2(i,j)
|
||||
SXmatrix(j+1,i+1)=hessmat2(i,j)
|
||||
end do
|
||||
end do
|
||||
|
||||
if (bavard) then
|
||||
do i=2,nMonoEx+1
|
||||
write(6,*) ' diagonal of the Hessian : ',i,hessmat2(i,i)
|
||||
end do
|
||||
end if
|
||||
|
||||
|
||||
implicit none
|
||||
BEGIN_DOC
|
||||
! Single-excitation matrix
|
||||
END_DOC
|
||||
|
||||
integer :: i,j
|
||||
|
||||
do i=1,nMonoEx+1
|
||||
do j=1,nMonoEx+1
|
||||
SXmatrix(i,j)=0.D0
|
||||
end do
|
||||
end do
|
||||
|
||||
do i=1,nMonoEx
|
||||
SXmatrix(1,i+1)=gradvec2(i)
|
||||
SXmatrix(1+i,1)=gradvec2(i)
|
||||
end do
|
||||
|
||||
do i=1,nMonoEx
|
||||
do j=1,nMonoEx
|
||||
SXmatrix(i+1,j+1)=hessmat2(i,j)
|
||||
SXmatrix(j+1,i+1)=hessmat2(i,j)
|
||||
end do
|
||||
end do
|
||||
|
||||
if (bavard) then
|
||||
do i=2,nMonoEx+1
|
||||
write(6,*) ' diagonal of the Hessian : ',i,hessmat2(i,i)
|
||||
end do
|
||||
end if
|
||||
|
||||
|
||||
END_PROVIDER
|
||||
|
||||
BEGIN_PROVIDER [real*8, SXeigenvec, (nMonoEx+1,nMonoEx+1)]
|
||||
&BEGIN_PROVIDER [real*8, SXeigenval, (nMonoEx+1)]
|
||||
END_PROVIDER
|
||||
implicit none
|
||||
BEGIN_DOC
|
||||
! Eigenvectors/eigenvalues of the single-excitation matrix
|
||||
END_DOC
|
||||
call lapack_diag(SXeigenval,SXeigenvec,SXmatrix,nMonoEx+1,nMonoEx+1)
|
||||
END_PROVIDER
|
||||
|
||||
BEGIN_PROVIDER [real*8, SXvector, (nMonoEx+1)]
|
||||
&BEGIN_PROVIDER [real*8, energy_improvement]
|
||||
implicit none
|
||||
integer :: ierr,matz,i
|
||||
real*8 :: c0
|
||||
implicit none
|
||||
BEGIN_DOC
|
||||
! Best eigenvector of the single-excitation matrix
|
||||
END_DOC
|
||||
integer :: ierr,matz,i
|
||||
real*8 :: c0
|
||||
|
||||
if (bavard) then
|
||||
write(6,*) ' SXdiag : lowest 5 eigenvalues '
|
||||
write(6,*) ' 1 - ',SXeigenval(1),SXeigenvec(1,1)
|
||||
write(6,*) ' 2 - ',SXeigenval(2),SXeigenvec(1,2)
|
||||
write(6,*) ' 3 - ',SXeigenval(3),SXeigenvec(1,3)
|
||||
write(6,*) ' 4 - ',SXeigenval(4),SXeigenvec(1,4)
|
||||
write(6,*) ' 5 - ',SXeigenval(5),SXeigenvec(1,5)
|
||||
write(6,*)
|
||||
write(6,*) ' SXdiag : lowest eigenvalue = ',SXeigenval(1)
|
||||
endif
|
||||
energy_improvement = SXeigenval(1)
|
||||
|
||||
integer :: best_vector
|
||||
real*8 :: best_overlap
|
||||
best_overlap=0.D0
|
||||
do i=1,nMonoEx+1
|
||||
if (SXeigenval(i).lt.0.D0) then
|
||||
if (abs(SXeigenvec(1,i)).gt.best_overlap) then
|
||||
best_overlap=abs(SXeigenvec(1,i))
|
||||
best_vector=i
|
||||
end if
|
||||
end if
|
||||
end do
|
||||
|
||||
energy_improvement = SXeigenval(best_vector)
|
||||
|
||||
if (bavard) then
|
||||
write(6,*) ' SXdiag : eigenvalue for best overlap with '
|
||||
write(6,*) ' previous orbitals = ',SXeigenval(best_vector)
|
||||
write(6,*) ' weight of the 1st element ',c0
|
||||
endif
|
||||
|
||||
call lapack_diag(SXeigenval,SXeigenvec,SXmatrix,nMonoEx+1,nMonoEx+1)
|
||||
write(6,*) ' SXdiag : lowest 5 eigenvalues '
|
||||
write(6,*) ' 1 - ',SXeigenval(1),SXeigenvec(1,1)
|
||||
write(6,*) ' 2 - ',SXeigenval(2),SXeigenvec(1,2)
|
||||
write(6,*) ' 3 - ',SXeigenval(3),SXeigenvec(1,3)
|
||||
write(6,*) ' 4 - ',SXeigenval(4),SXeigenvec(1,4)
|
||||
write(6,*) ' 5 - ',SXeigenval(5),SXeigenvec(1,5)
|
||||
write(6,*)
|
||||
write(6,*) ' SXdiag : lowest eigenvalue = ',SXeigenval(1)
|
||||
energy_improvement = SXeigenval(1)
|
||||
c0=SXeigenvec(1,best_vector)
|
||||
|
||||
integer :: best_vector
|
||||
real*8 :: best_overlap
|
||||
best_overlap=0.D0
|
||||
do i=1,nMonoEx+1
|
||||
if (SXeigenval(i).lt.0.D0) then
|
||||
if (abs(SXeigenvec(1,i)).gt.best_overlap) then
|
||||
best_overlap=abs(SXeigenvec(1,i))
|
||||
best_vector=i
|
||||
end if
|
||||
end if
|
||||
end do
|
||||
|
||||
write(6,*) ' SXdiag : eigenvalue for best overlap with '
|
||||
write(6,*) ' previous orbitals = ',SXeigenval(best_vector)
|
||||
energy_improvement = SXeigenval(best_vector)
|
||||
|
||||
c0=SXeigenvec(1,best_vector)
|
||||
write(6,*) ' weight of the 1st element ',c0
|
||||
do i=1,nMonoEx+1
|
||||
SXvector(i)=SXeigenvec(i,best_vector)/c0
|
||||
! write(6,*) ' component No ',i,' : ',SXvector(i)
|
||||
end do
|
||||
do i=1,nMonoEx+1
|
||||
SXvector(i)=SXeigenvec(i,best_vector)/c0
|
||||
end do
|
||||
|
||||
|
||||
END_PROVIDER
|
||||
|
||||
|
||||
BEGIN_PROVIDER [real*8, NewOrbs, (ao_num,mo_num) ]
|
||||
implicit none
|
||||
integer :: i,j,ialph
|
||||
|
||||
! form the exponential of the Orbital rotations
|
||||
call get_orbrotmat
|
||||
! form the new orbitals
|
||||
do i=1,ao_num
|
||||
do j=1,mo_num
|
||||
NewOrbs(i,j)=0.D0
|
||||
end do
|
||||
end do
|
||||
|
||||
do ialph=1,ao_num
|
||||
do i=1,mo_num
|
||||
wrkline(i)=mo_coef(ialph,i)
|
||||
end do
|
||||
do i=1,mo_num
|
||||
do j=1,mo_num
|
||||
NewOrbs(ialph,i)+=Umat(i,j)*wrkline(j)
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
|
||||
implicit none
|
||||
BEGIN_DOC
|
||||
! Updated orbitals
|
||||
END_DOC
|
||||
integer :: i,j,ialph
|
||||
|
||||
call dgemm('N','T', ao_num,mo_num,mo_num,1.d0, &
|
||||
NatOrbsFCI, size(NatOrbsFCI,1), &
|
||||
Umat, size(Umat,1), 0.d0, &
|
||||
NewOrbs, size(NewOrbs,1))
|
||||
|
||||
END_PROVIDER
|
||||
|
||||
BEGIN_PROVIDER [real*8, Tpotmat, (mo_num,mo_num) ]
|
||||
&BEGIN_PROVIDER [real*8, Umat, (mo_num,mo_num) ]
|
||||
&BEGIN_PROVIDER [real*8, wrkline, (mo_num) ]
|
||||
&BEGIN_PROVIDER [real*8, Tmat, (mo_num,mo_num) ]
|
||||
END_PROVIDER
|
||||
|
||||
subroutine get_orbrotmat
|
||||
implicit none
|
||||
integer :: i,j,indx,k,iter,t,a,ii,tt,aa
|
||||
real*8 :: sum
|
||||
logical :: converged
|
||||
|
||||
|
||||
! the orbital rotation matrix T
|
||||
do i=1,mo_num
|
||||
do j=1,mo_num
|
||||
Tmat(i,j)=0.D0
|
||||
Umat(i,j)=0.D0
|
||||
Tpotmat(i,j)=0.D0
|
||||
end do
|
||||
Tpotmat(i,i)=1.D0
|
||||
end do
|
||||
|
||||
indx=1
|
||||
do i=1,n_core_orb
|
||||
ii=list_core(i)
|
||||
do t=1,n_act_orb
|
||||
tt=list_act(t)
|
||||
indx+=1
|
||||
Tmat(ii,tt)= SXvector(indx)
|
||||
Tmat(tt,ii)=-SXvector(indx)
|
||||
end do
|
||||
end do
|
||||
do i=1,n_core_orb
|
||||
ii=list_core(i)
|
||||
do a=1,n_virt_orb
|
||||
aa=list_virt(a)
|
||||
indx+=1
|
||||
Tmat(ii,aa)= SXvector(indx)
|
||||
Tmat(aa,ii)=-SXvector(indx)
|
||||
end do
|
||||
end do
|
||||
do t=1,n_act_orb
|
||||
tt=list_act(t)
|
||||
do a=1,n_virt_orb
|
||||
aa=list_virt(a)
|
||||
indx+=1
|
||||
Tmat(tt,aa)= SXvector(indx)
|
||||
Tmat(aa,tt)=-SXvector(indx)
|
||||
end do
|
||||
end do
|
||||
|
||||
write(6,*) ' the T matrix '
|
||||
do indx=1,nMonoEx
|
||||
i=excit(1,indx)
|
||||
j=excit(2,indx)
|
||||
! if (abs(Tmat(i,j)).gt.1.D0) then
|
||||
! write(6,*) ' setting matrix element ',i,j,' of ',Tmat(i,j),' to ' &
|
||||
! , sign(1.D0,Tmat(i,j))
|
||||
! Tmat(i,j)=sign(1.D0,Tmat(i,j))
|
||||
! Tmat(j,i)=-Tmat(i,j)
|
||||
! end if
|
||||
if (abs(Tmat(i,j)).gt.1.D-9) write(6,9901) i,j,excit_class(indx),Tmat(i,j)
|
||||
9901 format(' ',i4,' -> ',i4,' (',A3,') : ',E14.6)
|
||||
end do
|
||||
|
||||
write(6,*)
|
||||
write(6,*) ' forming the matrix exponential '
|
||||
write(6,*)
|
||||
! form the exponential
|
||||
iter=0
|
||||
converged=.false.
|
||||
do while (.not.converged)
|
||||
iter+=1
|
||||
! add the next term
|
||||
do i=1,mo_num
|
||||
do j=1,mo_num
|
||||
Umat(i,j)+=Tpotmat(i,j)
|
||||
end do
|
||||
end do
|
||||
! next power of T, we multiply Tpotmat with Tmat/iter
|
||||
do i=1,mo_num
|
||||
do j=1,mo_num
|
||||
wrkline(j)=Tpotmat(i,j)/dble(iter)
|
||||
Tpotmat(i,j)=0.D0
|
||||
end do
|
||||
do j=1,mo_num
|
||||
do k=1,mo_num
|
||||
Tpotmat(i,j)+=wrkline(k)*Tmat(k,j)
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
! Convergence test
|
||||
sum=0.D0
|
||||
do i=1,mo_num
|
||||
do j=1,mo_num
|
||||
sum+=abs(Tpotmat(i,j))
|
||||
end do
|
||||
end do
|
||||
write(6,*) ' Iteration No ',iter,' Sum = ',sum
|
||||
if (sum.lt.1.D-6) then
|
||||
converged=.true.
|
||||
end if
|
||||
if (iter.ge.NItExpMax) then
|
||||
stop ' no convergence '
|
||||
end if
|
||||
end do
|
||||
write(6,*)
|
||||
write(6,*) ' Converged ! '
|
||||
write(6,*)
|
||||
|
||||
end subroutine get_orbrotmat
|
||||
|
||||
BEGIN_PROVIDER [integer, NItExpMax]
|
||||
NItExpMax=100
|
||||
BEGIN_PROVIDER [real*8, Umat, (mo_num,mo_num) ]
|
||||
implicit none
|
||||
BEGIN_DOC
|
||||
! Orbital rotation matrix
|
||||
END_DOC
|
||||
integer :: i,j,indx,k,iter,t,a,ii,tt,aa
|
||||
logical :: converged
|
||||
|
||||
real*8 :: Tpotmat (mo_num,mo_num), Tpotmat2 (mo_num,mo_num)
|
||||
real*8 :: Tmat(mo_num,mo_num)
|
||||
real*8 :: f
|
||||
|
||||
! the orbital rotation matrix T
|
||||
Tmat(:,:)=0.D0
|
||||
indx=1
|
||||
do i=1,n_core_orb
|
||||
ii=list_core(i)
|
||||
do t=1,n_act_orb
|
||||
tt=list_act(t)
|
||||
indx+=1
|
||||
Tmat(ii,tt)= SXvector(indx)
|
||||
Tmat(tt,ii)=-SXvector(indx)
|
||||
end do
|
||||
end do
|
||||
do i=1,n_core_orb
|
||||
ii=list_core(i)
|
||||
do a=1,n_virt_orb
|
||||
aa=list_virt(a)
|
||||
indx+=1
|
||||
Tmat(ii,aa)= SXvector(indx)
|
||||
Tmat(aa,ii)=-SXvector(indx)
|
||||
end do
|
||||
end do
|
||||
do t=1,n_act_orb
|
||||
tt=list_act(t)
|
||||
do a=1,n_virt_orb
|
||||
aa=list_virt(a)
|
||||
indx+=1
|
||||
Tmat(tt,aa)= SXvector(indx)
|
||||
Tmat(aa,tt)=-SXvector(indx)
|
||||
end do
|
||||
end do
|
||||
|
||||
! Form the exponential
|
||||
|
||||
Tpotmat(:,:)=0.D0
|
||||
Umat(:,:) =0.D0
|
||||
do i=1,mo_num
|
||||
Tpotmat(i,i)=1.D0
|
||||
Umat(i,i) =1.d0
|
||||
end do
|
||||
iter=0
|
||||
converged=.false.
|
||||
do while (.not.converged)
|
||||
iter+=1
|
||||
f = 1.d0 / dble(iter)
|
||||
Tpotmat2(:,:) = Tpotmat(:,:) * f
|
||||
call dgemm('N','N', mo_num,mo_num,mo_num,1.d0, &
|
||||
Tpotmat2, size(Tpotmat2,1), &
|
||||
Tmat, size(Tmat,1), 0.d0, &
|
||||
Tpotmat, size(Tpotmat,1))
|
||||
Umat(:,:) = Umat(:,:) + Tpotmat(:,:)
|
||||
|
||||
converged = ( sum(abs(Tpotmat(:,:))) < 1.d-6).or.(iter>30)
|
||||
end do
|
||||
END_PROVIDER
|
||||
|
||||
|
||||
|
||||
|
@ -42,8 +42,6 @@
|
||||
end do
|
||||
end do
|
||||
end do
|
||||
write(6,*) ' e_one_all = ',e_one_all
|
||||
write(6,*) ' e_two_all = ',e_two_all
|
||||
ecore =nuclear_repulsion
|
||||
ecore_bis=nuclear_repulsion
|
||||
do i=1,n_core_orb
|
||||
@ -98,24 +96,6 @@
|
||||
end do
|
||||
end do
|
||||
|
||||
write(6,*) ' energy contributions '
|
||||
write(6,*) ' core energy = ',ecore,' using PQxx integrals '
|
||||
write(6,*) ' core energy (bis) = ',ecore,' using PxxQ integrals '
|
||||
write(6,*) ' 1el energy = ',eone ,' using PQxx integrals '
|
||||
write(6,*) ' 1el energy (bis) = ',eone ,' using PxxQ integrals '
|
||||
write(6,*) ' 2el energy = ',etwo ,' using PQxx integrals '
|
||||
write(6,*) ' 2el energy (bis) = ',etwo_bis,' using PxxQ integrals '
|
||||
write(6,*) ' 2el energy (ter) = ',etwo_ter,' using tuvP integrals '
|
||||
write(6,*) ' ----------------------------------------- '
|
||||
write(6,*) ' sum of all = ',eone+etwo+ecore
|
||||
write(6,*)
|
||||
write(6,*) ' nuclear (qp) = ',nuclear_repulsion
|
||||
write(6,*) ' core energy (qp) = ',core_energy
|
||||
write(6,*) ' 1el energy (qp) = ',psi_energy_h_core(1)
|
||||
write(6,*) ' 2el energy (qp) = ',psi_energy_two_e(1)
|
||||
write(6,*) ' nuc + 1 + 2 (qp) = ',nuclear_repulsion+psi_energy_h_core(1)+psi_energy_two_e(1)
|
||||
write(6,*) ' <0|H|0> (qp) = ',psi_energy_with_nucl_rep(1)
|
||||
|
||||
END_PROVIDER
|
||||
|
||||
|
||||
|
Loading…
Reference in New Issue
Block a user