qp2/src/becke_numerical_grid/grid_becke_vector.irp.f


BEGIN_PROVIDER [integer, n_points_final_grid]
  implicit none
  BEGIN_DOC
  ! Number of points which are non zero
  END_DOC
  integer                        :: i,j,k,l
  n_points_final_grid = 0
  do j = 1, nucl_num
    do i = 1, n_points_radial_grid -1
      do k = 1, n_points_integration_angular
        if(dabs(final_weight_at_r(k,i,j)) < thresh_grid)then
          cycle
        endif
        n_points_final_grid += 1
      enddo
    enddo
  enddo
  print*,'n_points_final_grid = ',n_points_final_grid
  print*,'n max point         = ',n_points_integration_angular*(n_points_radial_grid*nucl_num - 1)
END_PROVIDER

 BEGIN_PROVIDER [double precision, final_grid_points, (3,n_points_final_grid)]
&BEGIN_PROVIDER [double precision, final_weight_at_r_vector, (n_points_final_grid) ]
&BEGIN_PROVIDER [integer, index_final_points, (3,n_points_final_grid) ]
&BEGIN_PROVIDER [integer, index_final_points_reverse, (n_points_integration_angular,n_points_radial_grid,nucl_num) ]
  implicit none
  BEGIN_DOC
!  final_grid_points(1:3,j) = (/ x, y, z /) of the jth grid point
!
! final_weight_at_r_vector(i) = Total weight function of the ith grid point which contains the Lebedev, Voronoi and radial weights contributions
!
! index_final_points(1:3,i) = gives the angular, radial and atomic indices associated to the ith grid point
!
! index_final_points_reverse(i,j,k) = index of the grid point having i as angular, j as radial and l as atomic indices
  END_DOC
  integer                        :: i,j,k,l,i_count
  double precision               :: r(3)
  i_count = 0
  do j = 1, nucl_num
    do i = 1, n_points_radial_grid -1
      do k = 1, n_points_integration_angular
        if(dabs(final_weight_at_r(k,i,j)) < thresh_grid)then
          cycle
        endif
        i_count += 1
        final_grid_points(1,i_count) = grid_points_per_atom(1,k,i,j)
        final_grid_points(2,i_count) = grid_points_per_atom(2,k,i,j)
        final_grid_points(3,i_count) = grid_points_per_atom(3,k,i,j)
        final_weight_at_r_vector(i_count) = final_weight_at_r(k,i,j)
        index_final_points(1,i_count) = k
        index_final_points(2,i_count) = i
        index_final_points(3,i_count) = j
        index_final_points_reverse(k,i,j) = i_count
      enddo
    enddo
  enddo

END_PROVIDER
Initial commit 2019-01-25 11:39:31 +01:00
			`BEGIN_PROVIDER [integer, n_points_final_grid]`
fixed bugs with dummy atom and becke grid 2019-05-28 18:49:21 +02:00			`implicit none`
Initial commit 2019-01-25 11:39:31 +01:00			`BEGIN_DOC`
			`! Number of points which are non zero`
			`END_DOC`
			`integer :: i,j,k,l`
			`n_points_final_grid = 0`
			`do j = 1, nucl_num`
			`do i = 1, n_points_radial_grid -1`
			`do k = 1, n_points_integration_angular`
fixed bugs with dummy atom and becke grid 2019-05-28 18:49:21 +02:00			`if(dabs(final_weight_at_r(k,i,j)) < thresh_grid)then`
added some stuffs for getting the bielec integrals 2019-05-20 08:54:39 +02:00			`cycle`
			`endif`
Initial commit 2019-01-25 11:39:31 +01:00			`n_points_final_grid += 1`
			`enddo`
			`enddo`
			`enddo`
			`print*,'n_points_final_grid = ',n_points_final_grid`
			`print,'n max point = ',n_points_integration_angular(n_points_radial_grid*nucl_num - 1)`
			`END_PROVIDER`

			`BEGIN_PROVIDER [double precision, final_grid_points, (3,n_points_final_grid)]`
			`&BEGIN_PROVIDER [double precision, final_weight_at_r_vector, (n_points_final_grid) ]`
			`&BEGIN_PROVIDER [integer, index_final_points, (3,n_points_final_grid) ]`
			`&BEGIN_PROVIDER [integer, index_final_points_reverse, (n_points_integration_angular,n_points_radial_grid,nucl_num) ]`
			`implicit none`
			`BEGIN_DOC`
			`! final_grid_points(1:3,j) = (/ x, y, z /) of the jth grid point`
			`!`
			`! final_weight_at_r_vector(i) = Total weight function of the ith grid point which contains the Lebedev, Voronoi and radial weights contributions`
			`!`
			`! index_final_points(1:3,i) = gives the angular, radial and atomic indices associated to the ith grid point`
			`!`
			`! index_final_points_reverse(i,j,k) = index of the grid point having i as angular, j as radial and l as atomic indices`
			`END_DOC`
			`integer :: i,j,k,l,i_count`
			`double precision :: r(3)`
			`i_count = 0`
			`do j = 1, nucl_num`
			`do i = 1, n_points_radial_grid -1`
			`do k = 1, n_points_integration_angular`
added some stuffs for getting the bielec integrals 2019-05-20 08:54:39 +02:00			`if(dabs(final_weight_at_r(k,i,j)) < thresh_grid)then`
			`cycle`
			`endif`
Initial commit 2019-01-25 11:39:31 +01:00			`i_count += 1`
			`final_grid_points(1,i_count) = grid_points_per_atom(1,k,i,j)`
			`final_grid_points(2,i_count) = grid_points_per_atom(2,k,i,j)`
			`final_grid_points(3,i_count) = grid_points_per_atom(3,k,i,j)`
			`final_weight_at_r_vector(i_count) = final_weight_at_r(k,i,j)`
			`index_final_points(1,i_count) = k`
			`index_final_points(2,i_count) = i`
			`index_final_points(3,i_count) = j`
			`index_final_points_reverse(k,i,j) = i_count`
			`enddo`
			`enddo`
			`enddo`

			`END_PROVIDER`