QuantumPackage/src/dressing/selection_weight.irp.f

BEGIN_PROVIDER [ double precision, pt2_match_weight, (N_states) ]
 implicit none
 BEGIN_DOC
 ! Weights adjusted along the selection to make the PT2 contributions
 ! of each state coincide.
 END_DOC
 pt2_match_weight(:) = 1.d0
END_PROVIDER


BEGIN_PROVIDER [ double precision, variance_match_weight, (N_states) ]
 implicit none
 BEGIN_DOC
 ! Weights adjusted along the selection to make the variances
 ! of each state coincide.
 END_DOC
 variance_match_weight(:) = 1.d0
END_PROVIDER


subroutine update_pt2_and_variance_weights(pt2_data, N_st)
  implicit none
  use selection_types
  BEGIN_DOC
! Updates the PT2- and Variance- matching weights.
  END_DOC
  integer, intent(in)          :: N_st
  type(pt2_type), intent(in)   :: pt2_data
  double precision             :: pt2(N_st)
  double precision             :: variance(N_st)

  double precision :: avg, element, dt, x
  integer          :: k
  integer, save    :: i_iter=0
  integer, parameter :: i_itermax = 1
  double precision, allocatable, save :: memo_variance(:,:), memo_pt2(:,:)

  pt2(:)      = pt2_data % pt2(:)
  variance(:) = pt2_data % variance(:)

  if (i_iter == 0) then
    allocate(memo_variance(N_st,i_itermax), memo_pt2(N_st,i_itermax))
    memo_pt2(:,:) = 1.d0
    memo_variance(:,:) = 1.d0
  endif

  i_iter = i_iter+1
  if (i_iter > i_itermax) then
    i_iter = 1
  endif

  dt = 2.0d0

  avg = sum(pt2(1:N_st)) / dble(N_st) - 1.d-32 ! Avoid future division by zero
  do k=1,N_st
    element = exp(dt*(pt2(k)/avg -1.d0))
    element = min(2.0d0 , element)
    element = max(0.5d0 , element)
    memo_pt2(k,i_iter) = element
    pt2_match_weight(k) *= product(memo_pt2(k,:))
  enddo


  avg = sum(variance(1:N_st)) / dble(N_st) + 1.d-32 ! Avoid future division by zero
  do k=1,N_st
    element = exp(dt*(variance(k)/avg -1.d0))
    element = min(2.0d0 , element)
    element = max(0.5d0 , element)
    memo_variance(k,i_iter) = element
    variance_match_weight(k) *= product(memo_variance(k,:))
  enddo

  if (N_det < 100) then
    ! For tiny wave functions, weights are 1.d0
    pt2_match_weight(:) = 1.d0
    variance_match_weight(:) = 1.d0
  endif

  threshold_davidson_pt2 = min(1.d-6, &
     max(threshold_davidson, 1.e-1 * PT2_relative_error * minval(abs(pt2(1:N_states)))) )

  SOFT_TOUCH pt2_match_weight variance_match_weight threshold_davidson_pt2
end


BEGIN_PROVIDER [ double precision, selection_weight, (N_states) ]
   implicit none
   BEGIN_DOC
   ! Weights used in the selection criterion
   END_DOC
   select case (weight_selection)

     case (0)
      print *,  'Using input weights in selection'
      selection_weight(1:N_states) = c0_weight(1:N_states) * state_average_weight(1:N_states)

     case (1)
      print *,  'Using 1/c_max^2 weight in selection'
      selection_weight(1:N_states) = c0_weight(1:N_states)

     case (2)
      print *,  'Using pt2-matching weight in selection'
      selection_weight(1:N_states) = c0_weight(1:N_states) * pt2_match_weight(1:N_states)
      print *, '# PT2 weight ', real(pt2_match_weight(:),4)

     case (3)
      print *,  'Using variance-matching weight in selection'
      selection_weight(1:N_states) = c0_weight(1:N_states) * variance_match_weight(1:N_states)
      print *, '# var weight ', real(variance_match_weight(:),4)

     case (4)
      print *,  'Using variance- and pt2-matching weights in selection'
      selection_weight(1:N_states) = c0_weight(1:N_states) * sqrt(variance_match_weight(1:N_states) * pt2_match_weight(1:N_states))
      print *, '# PT2 weight ', real(pt2_match_weight(:),4)
      print *, '# var weight ', real(variance_match_weight(:),4)

     case (5)
      print *,  'Using variance-matching weight in selection'
      selection_weight(1:N_states) = c0_weight(1:N_states) * variance_match_weight(1:N_states)
      print *, '# var weight ', real(variance_match_weight(:),4)

     case (6)
      print *,  'Using CI coefficient-based selection'
      selection_weight(1:N_states) = c0_weight(1:N_states)

     case (7)
      print *,  'Input weights multiplied by variance- and pt2-matching'
      selection_weight(1:N_states) = c0_weight(1:N_states) * sqrt(variance_match_weight(1:N_states) * pt2_match_weight(1:N_states)) * state_average_weight(1:N_states)
      print *, '# PT2 weight ', real(pt2_match_weight(:),4)
      print *, '# var weight ', real(variance_match_weight(:),4)

     case (8)
      print *,  'Input weights multiplied by pt2-matching'
      selection_weight(1:N_states) = c0_weight(1:N_states) * pt2_match_weight(1:N_states) * state_average_weight(1:N_states)
      print *, '# PT2 weight ', real(pt2_match_weight(:),4)

     case (9)
      print *,  'Input weights multiplied by variance-matching'
      selection_weight(1:N_states) = c0_weight(1:N_states) * variance_match_weight(1:N_states) * state_average_weight(1:N_states)
      print *, '# var weight ', real(variance_match_weight(:),4)

    end select
     print *, '# Total weight ', real(selection_weight(:),4)

END_PROVIDER
Moved selection_weight 2020-12-23 02:42:38 +01:00			`BEGIN_PROVIDER [ double precision, pt2_match_weight, (N_states) ]`
			`implicit none`
			`BEGIN_DOC`
			`! Weights adjusted along the selection to make the PT2 contributions`
			`! of each state coincide.`
			`END_DOC`
			`pt2_match_weight(:) = 1.d0`
			`END_PROVIDER`



			`BEGIN_PROVIDER [ double precision, variance_match_weight, (N_states) ]`
			`implicit none`
			`BEGIN_DOC`
			`! Weights adjusted along the selection to make the variances`
			`! of each state coincide.`
			`END_DOC`
			`variance_match_weight(:) = 1.d0`
			`END_PROVIDER`



			`subroutine update_pt2_and_variance_weights(pt2_data, N_st)`
			`implicit none`
			`use selection_types`
			`BEGIN_DOC`
			`! Updates the PT2- and Variance- matching weights.`
			`END_DOC`
			`integer, intent(in) :: N_st`
			`type(pt2_type), intent(in) :: pt2_data`
			`double precision :: pt2(N_st)`
			`double precision :: variance(N_st)`

			`double precision :: avg, element, dt, x`
			`integer :: k`
			`integer, save :: i_iter=0`
			`integer, parameter :: i_itermax = 1`
			`double precision, allocatable, save :: memo_variance(:,:), memo_pt2(:,:)`

			`pt2(:) = pt2_data % pt2(:)`
			`variance(:) = pt2_data % variance(:)`

			`if (i_iter == 0) then`
			`allocate(memo_variance(N_st,i_itermax), memo_pt2(N_st,i_itermax))`
			`memo_pt2(:,:) = 1.d0`
			`memo_variance(:,:) = 1.d0`
			`endif`

			`i_iter = i_iter+1`
			`if (i_iter > i_itermax) then`
			`i_iter = 1`
			`endif`

			`dt = 2.0d0`

			`avg = sum(pt2(1:N_st)) / dble(N_st) - 1.d-32 ! Avoid future division by zero`
			`do k=1,N_st`
			`element = exp(dt*(pt2(k)/avg -1.d0))`
			`element = min(2.0d0 , element)`
			`element = max(0.5d0 , element)`
			`memo_pt2(k,i_iter) = element`
			`pt2_match_weight(k) *= product(memo_pt2(k,:))`
			`enddo`


			`avg = sum(variance(1:N_st)) / dble(N_st) + 1.d-32 ! Avoid future division by zero`
			`do k=1,N_st`
			`element = exp(dt*(variance(k)/avg -1.d0))`
			`element = min(2.0d0 , element)`
			`element = max(0.5d0 , element)`
			`memo_variance(k,i_iter) = element`
			`variance_match_weight(k) *= product(memo_variance(k,:))`
			`enddo`

			`if (N_det < 100) then`
			`! For tiny wave functions, weights are 1.d0`
			`pt2_match_weight(:) = 1.d0`
			`variance_match_weight(:) = 1.d0`
			`endif`

			`threshold_davidson_pt2 = min(1.d-6, &`
			`max(threshold_davidson, 1.e-1 * PT2_relative_error * minval(abs(pt2(1:N_states)))) )`

			`SOFT_TOUCH pt2_match_weight variance_match_weight threshold_davidson_pt2`
			`end`




			`BEGIN_PROVIDER [ double precision, selection_weight, (N_states) ]`
			`implicit none`
			`BEGIN_DOC`
			`! Weights used in the selection criterion`
			`END_DOC`
			`select case (weight_selection)`

			`case (0)`
			`print *, 'Using input weights in selection'`
			`selection_weight(1:N_states) = c0_weight(1:N_states) * state_average_weight(1:N_states)`

			`case (1)`
			`print *, 'Using 1/c_max^2 weight in selection'`
			`selection_weight(1:N_states) = c0_weight(1:N_states)`

			`case (2)`
			`print *, 'Using pt2-matching weight in selection'`
			`selection_weight(1:N_states) = c0_weight(1:N_states) * pt2_match_weight(1:N_states)`
			`print *, '# PT2 weight ', real(pt2_match_weight(:),4)`

			`case (3)`
			`print *, 'Using variance-matching weight in selection'`
			`selection_weight(1:N_states) = c0_weight(1:N_states) * variance_match_weight(1:N_states)`
			`print *, '# var weight ', real(variance_match_weight(:),4)`

			`case (4)`
			`print *, 'Using variance- and pt2-matching weights in selection'`
			`selection_weight(1:N_states) = c0_weight(1:N_states) * sqrt(variance_match_weight(1:N_states) * pt2_match_weight(1:N_states))`
			`print *, '# PT2 weight ', real(pt2_match_weight(:),4)`
			`print *, '# var weight ', real(variance_match_weight(:),4)`

			`case (5)`
			`print *, 'Using variance-matching weight in selection'`
			`selection_weight(1:N_states) = c0_weight(1:N_states) * variance_match_weight(1:N_states)`
			`print *, '# var weight ', real(variance_match_weight(:),4)`

			`case (6)`
			`print *, 'Using CI coefficient-based selection'`
			`selection_weight(1:N_states) = c0_weight(1:N_states)`

			`case (7)`
			`print *, 'Input weights multiplied by variance- and pt2-matching'`
			`selection_weight(1:N_states) = c0_weight(1:N_states) * sqrt(variance_match_weight(1:N_states) * pt2_match_weight(1:N_states)) * state_average_weight(1:N_states)`
			`print *, '# PT2 weight ', real(pt2_match_weight(:),4)`
			`print *, '# var weight ', real(variance_match_weight(:),4)`

			`case (8)`
			`print *, 'Input weights multiplied by pt2-matching'`
			`selection_weight(1:N_states) = c0_weight(1:N_states) * pt2_match_weight(1:N_states) * state_average_weight(1:N_states)`
			`print *, '# PT2 weight ', real(pt2_match_weight(:),4)`

			`case (9)`
			`print *, 'Input weights multiplied by variance-matching'`
			`selection_weight(1:N_states) = c0_weight(1:N_states) * variance_match_weight(1:N_states) * state_average_weight(1:N_states)`
			`print *, '# var weight ', real(variance_match_weight(:),4)`

			`end select`
			`print *, '# Total weight ', real(selection_weight(:),4)`

			`END_PROVIDER`