QuantumPackage/plugins/local/tc_scf/rh_tcscf_simple.irp.f

! ---

subroutine rh_tcscf_simple()

  implicit none
  integer                       :: i, j, it, dim_DIIS
  double precision              :: t0, t1
  double precision              :: e_save, e_delta, rho_delta
  double precision              :: etc_tot, etc_1e, etc_2e, etc_3e, tc_grad
  double precision              :: er_DIIS
  double precision, allocatable :: rho_old(:,:), rho_new(:,:)

  allocate(rho_old(ao_num,ao_num), rho_new(ao_num,ao_num))

  it       = 0
  e_save   = 0.d0
  dim_DIIS = 0

  ! ---

  if(.not. bi_ortho) then
   print *, ' grad_hermit = ', grad_hermit
   call save_good_hermit_tc_eigvectors
   TOUCH mo_coef 
   call save_mos
  endif

  ! ---

  if(bi_ortho) then

    PROVIDE level_shift_tcscf
    PROVIDE mo_l_coef mo_r_coef

    write(6, '(A4,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A4, 1X, A8)')              &
      '====', '================', '================', '================', '================', '================' &
            , '================', '================', '================', '====', '========'

    write(6, '(A4,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A4, 1X, A8)')              &
      ' it ', '  SCF TC Energy ', '      E(1e)     ', '      E(2e)     ', '      E(3e)     ', '   energy diff  ' &
            , '    gradient    ', '    DIIS error  ', '  level shift   ', 'DIIS', '  WT (m)'

    write(6, '(A4,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A4, 1X, A8)')              &
      '====', '================', '================', '================', '================', '================' &
            , '================', '================', '================', '====', '========'


    ! first iteration (HF orbitals)
    call wall_time(t0)

    etc_tot = TC_HF_energy
    etc_1e  = TC_HF_one_e_energy
    etc_2e  = TC_HF_two_e_energy
    etc_3e  = 0.d0
    if(three_body_h_tc) then
      etc_3e = diag_three_elem_hf
    endif
    tc_grad = grad_non_hermit
    er_DIIS = maxval(abs(FQS_SQF_mo))
    e_delta = dabs(etc_tot - e_save)
    e_save  = etc_tot

    call wall_time(t1)
    write(6, '(I4,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, I4,1X, F8.2)')  &
      it, etc_tot, etc_1e, etc_2e, etc_3e, e_delta, tc_grad, er_DIIS, level_shift_tcscf, dim_DIIS, (t1-t0)/60.d0

    do while(tc_grad .gt. dsqrt(thresh_tcscf))
      call wall_time(t0)

      it += 1
      if(it > n_it_tcscf_max) then
        print *, ' max of TCSCF iterations is reached ', n_it_TCSCF_max
        stop
      endif

      mo_l_coef = fock_tc_leigvec_ao
      mo_r_coef = fock_tc_reigvec_ao
      call ezfio_set_bi_ortho_mos_mo_l_coef(mo_l_coef)
      call ezfio_set_bi_ortho_mos_mo_r_coef(mo_r_coef)
      TOUCH mo_l_coef mo_r_coef

      etc_tot = TC_HF_energy
      etc_1e  = TC_HF_one_e_energy
      etc_2e  = TC_HF_two_e_energy
      etc_3e  = 0.d0
      if(three_body_h_tc) then
        etc_3e = diag_three_elem_hf
      endif
      tc_grad = grad_non_hermit
      er_DIIS = maxval(abs(FQS_SQF_mo))
      e_delta = dabs(etc_tot - e_save)
      e_save  = etc_tot

      call ezfio_set_tc_scf_bitc_energy(etc_tot)

      call wall_time(t1)
      write(6, '(I4,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, I4,1X, F8.2)')  &
        it, etc_tot, etc_1e, etc_2e, etc_3e, e_delta, tc_grad, er_DIIS, level_shift_tcscf, dim_DIIS, (t1-t0)/60.d0
    enddo

  else

   do while( (grad_hermit.gt.dsqrt(thresh_tcscf)) .and. (it.lt.n_it_tcscf_max) )
      print*,'grad_hermit = ',grad_hermit
      it += 1
      print *, 'iteration = ', it
      print *, '***'
      print *, 'TC HF total energy = ', TC_HF_energy
      print *, 'TC HF 1 e   energy = ', TC_HF_one_e_energy
      print *, 'TC HF 2 e   energy = ', TC_HF_two_e_energy
      print *, 'TC HF 3 body       = ', diag_three_elem_hf
      print *, '***'
      print *, ''
      call save_good_hermit_tc_eigvectors
      TOUCH mo_coef 
      call save_mos
    enddo

  endif

  print *, ' TCSCF Simple converged !'
  !call print_energy_and_mos(good_angles)

  deallocate(rho_old, rho_new)

end

! ---
tc_scf compiles and gives good energy for Ne. Added a test in test_Ne.sh 2023-02-06 19:26:58 +01:00			`! ---`

			`subroutine rh_tcscf_simple()`

			`implicit none`
			`integer :: i, j, it, dim_DIIS`
			`double precision :: t0, t1`
			`double precision :: e_save, e_delta, rho_delta`
			`double precision :: etc_tot, etc_1e, etc_2e, etc_3e, tc_grad`
			`double precision :: er_DIIS`
			`double precision, allocatable :: rho_old(:,:), rho_new(:,:)`

			`allocate(rho_old(ao_num,ao_num), rho_new(ao_num,ao_num))`

			`it = 0`
			`e_save = 0.d0`
			`dim_DIIS = 0`

			`! ---`

			`if(.not. bi_ortho) then`
			`print *, ' grad_hermit = ', grad_hermit`
			`call save_good_hermit_tc_eigvectors`
			`TOUCH mo_coef`
			`call save_mos`
			`endif`

			`! ---`

			`if(bi_ortho) then`

			`PROVIDE level_shift_tcscf`
			`PROVIDE mo_l_coef mo_r_coef`

			`write(6, '(A4,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A4, 1X, A8)') &`
			`'====', '================', '================', '================', '================', '================' &`
			`, '================', '================', '================', '====', '========'`

			`write(6, '(A4,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A4, 1X, A8)') &`
			`' it ', ' SCF TC Energy ', ' E(1e) ', ' E(2e) ', ' E(3e) ', ' energy diff ' &`
			`, ' gradient ', ' DIIS error ', ' level shift ', 'DIIS', ' WT (m)'`

			`write(6, '(A4,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A16,1X, A4, 1X, A8)') &`
			`'====', '================', '================', '================', '================', '================' &`
			`, '================', '================', '================', '====', '========'`


			`! first iteration (HF orbitals)`
			`call wall_time(t0)`

			`etc_tot = TC_HF_energy`
			`etc_1e = TC_HF_one_e_energy`
			`etc_2e = TC_HF_two_e_energy`
			`etc_3e = 0.d0`
			`if(three_body_h_tc) then`
			`etc_3e = diag_three_elem_hf`
			`endif`
			`tc_grad = grad_non_hermit`
			`er_DIIS = maxval(abs(FQS_SQF_mo))`
			`e_delta = dabs(etc_tot - e_save)`
			`e_save = etc_tot`

			`call wall_time(t1)`
			`write(6, '(I4,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, I4,1X, F8.2)') &`
			`it, etc_tot, etc_1e, etc_2e, etc_3e, e_delta, tc_grad, er_DIIS, level_shift_tcscf, dim_DIIS, (t1-t0)/60.d0`

			`do while(tc_grad .gt. dsqrt(thresh_tcscf))`
			`call wall_time(t0)`

			`it += 1`
			`if(it > n_it_tcscf_max) then`
			`print *, ' max of TCSCF iterations is reached ', n_it_TCSCF_max`
			`stop`
			`endif`

			`mo_l_coef = fock_tc_leigvec_ao`
			`mo_r_coef = fock_tc_reigvec_ao`
			`call ezfio_set_bi_ortho_mos_mo_l_coef(mo_l_coef)`
			`call ezfio_set_bi_ortho_mos_mo_r_coef(mo_r_coef)`
			`TOUCH mo_l_coef mo_r_coef`

			`etc_tot = TC_HF_energy`
			`etc_1e = TC_HF_one_e_energy`
			`etc_2e = TC_HF_two_e_energy`
			`etc_3e = 0.d0`
			`if(three_body_h_tc) then`
			`etc_3e = diag_three_elem_hf`
			`endif`
			`tc_grad = grad_non_hermit`
			`er_DIIS = maxval(abs(FQS_SQF_mo))`
			`e_delta = dabs(etc_tot - e_save)`
			`e_save = etc_tot`

			`call ezfio_set_tc_scf_bitc_energy(etc_tot)`

			`call wall_time(t1)`
			`write(6, '(I4,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, F16.10,1X, I4,1X, F8.2)') &`
			`it, etc_tot, etc_1e, etc_2e, etc_3e, e_delta, tc_grad, er_DIIS, level_shift_tcscf, dim_DIIS, (t1-t0)/60.d0`
			`enddo`

			`else`

			`do while( (grad_hermit.gt.dsqrt(thresh_tcscf)) .and. (it.lt.n_it_tcscf_max) )`
			`print*,'grad_hermit = ',grad_hermit`
			`it += 1`
			`print *, 'iteration = ', it`
			`print , '**'`
			`print *, 'TC HF total energy = ', TC_HF_energy`
			`print *, 'TC HF 1 e energy = ', TC_HF_one_e_energy`
			`print *, 'TC HF 2 e energy = ', TC_HF_two_e_energy`
			`print *, 'TC HF 3 body = ', diag_three_elem_hf`
			`print , '**'`
			`print *, ''`
			`call save_good_hermit_tc_eigvectors`
			`TOUCH mo_coef`
			`call save_mos`
			`enddo`

			`endif`

			`print *, ' TCSCF Simple converged !'`
TC-SCF: no rotations for good angles 2023-05-18 20:57:55 +02:00			`!call print_energy_and_mos(good_angles)`
tc_scf compiles and gives good energy for Ne. Added a test in test_Ne.sh 2023-02-06 19:26:58 +01:00
			`deallocate(rho_old, rho_new)`

			`end`

			`! ---`