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250 lines
8.6 KiB
Fortran
250 lines
8.6 KiB
Fortran
BEGIN_PROVIDER [integer, n_points_radial_grid]
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&BEGIN_PROVIDER [integer, n_points_integration_angular]
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implicit none
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BEGIN_DOC
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! n_points_radial_grid = number of radial grid points per atom
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!
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! n_points_integration_angular = number of angular grid points per atom
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!
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! These numbers are automatically set by setting the grid_type_sgn parameter
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END_DOC
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select case (grid_type_sgn)
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case(0)
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n_points_radial_grid = 23
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n_points_integration_angular = 170
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case(1)
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n_points_radial_grid = 50
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n_points_integration_angular = 194
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case(2)
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n_points_radial_grid = 75
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n_points_integration_angular = 302
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case(3)
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n_points_radial_grid = 99
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n_points_integration_angular = 590
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case default
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write(*,*) '!!! Quadrature grid not available !!!'
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stop
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end select
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END_PROVIDER
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BEGIN_PROVIDER [integer, n_points_grid_per_atom]
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implicit none
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BEGIN_DOC
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! Number of grid points per atom
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END_DOC
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n_points_grid_per_atom = n_points_integration_angular * n_points_radial_grid
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END_PROVIDER
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BEGIN_PROVIDER [double precision, angular_quadrature_points, (n_points_integration_angular,3) ]
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&BEGIN_PROVIDER [double precision, weights_angular_points, (n_points_integration_angular)]
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implicit none
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BEGIN_DOC
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! weights and grid points for the integration on the angular variables on
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! the unit sphere centered on (0,0,0)
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! According to the LEBEDEV scheme
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END_DOC
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include 'constants.include.F'
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integer :: i
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double precision :: accu
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double precision :: degre_rad
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double precision :: x(n_points_integration_angular)
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double precision :: y(n_points_integration_angular)
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double precision :: z(n_points_integration_angular)
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double precision :: w(n_points_integration_angular)
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degre_rad = pi/180.d0
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accu = 0.d0
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select case (n_points_integration_angular)
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case (5810)
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call LD5810(X,Y,Z,W,n_points_integration_angular)
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case (2030)
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call LD2030(X,Y,Z,W,n_points_integration_angular)
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case (1202)
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call LD1202(X,Y,Z,W,n_points_integration_angular)
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case (0590)
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call LD0590(X,Y,Z,W,n_points_integration_angular)
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case (302)
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call LD0302(X,Y,Z,W,n_points_integration_angular)
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case (266)
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call LD0266(X,Y,Z,W,n_points_integration_angular)
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case (194)
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call LD0194(X,Y,Z,W,n_points_integration_angular)
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case (170)
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call LD0170(X,Y,Z,W,n_points_integration_angular)
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case (74)
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call LD0074(X,Y,Z,W,n_points_integration_angular)
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case (50)
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call LD0050(X,Y,Z,W,n_points_integration_angular)
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case default
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print *, irp_here//': wrong n_points_integration_angular. Expected:'
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print *, '[ 50 | 74 | 170 | 194 | 266 | 302 | 590 | 1202 | 2030 | 5810 ]'
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stop -1
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end select
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do i = 1, n_points_integration_angular
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angular_quadrature_points(i,1) = x(i)
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angular_quadrature_points(i,2) = y(i)
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angular_quadrature_points(i,3) = z(i)
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weights_angular_points(i) = w(i) * 4.d0 * pi
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accu += w(i)
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enddo
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END_PROVIDER
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BEGIN_PROVIDER [integer , m_knowles]
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implicit none
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BEGIN_DOC
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! value of the "m" parameter in the equation (7) of the paper of Knowles (JCP, 104, 1996)
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END_DOC
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m_knowles = 3
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END_PROVIDER
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BEGIN_PROVIDER [double precision, grid_points_radial, (n_points_radial_grid)]
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&BEGIN_PROVIDER [double precision, dr_radial_integral]
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implicit none
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BEGIN_DOC
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! points in [0,1] to map the radial integral [0,\infty]
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END_DOC
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dr_radial_integral = 1.d0/dble(n_points_radial_grid-1)
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integer :: i
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do i = 1, n_points_radial_grid
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grid_points_radial(i) = dble(i-1) * dr_radial_integral
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enddo
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END_PROVIDER
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BEGIN_PROVIDER [double precision, grid_points_per_atom, (3,n_points_integration_angular,n_points_radial_grid,nucl_num)]
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BEGIN_DOC
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! x,y,z coordinates of grid points used for integration in 3d space
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END_DOC
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implicit none
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integer :: i,j,k
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double precision :: dr,x_ref,y_ref,z_ref
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double precision :: knowles_function
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do i = 1, nucl_num
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x_ref = nucl_coord(i,1)
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y_ref = nucl_coord(i,2)
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z_ref = nucl_coord(i,3)
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do j = 1, n_points_radial_grid-1
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double precision :: x,r
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! x value for the mapping of the [0, +\infty] to [0,1]
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x = grid_points_radial(j)
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! value of the radial coordinate for the integration
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r = knowles_function(alpha_knowles(grid_atomic_number(i)),m_knowles,x)
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! explicit values of the grid points centered around each atom
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do k = 1, n_points_integration_angular
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grid_points_per_atom(1,k,j,i) = &
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x_ref + angular_quadrature_points(k,1) * r
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grid_points_per_atom(2,k,j,i) = &
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y_ref + angular_quadrature_points(k,2) * r
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grid_points_per_atom(3,k,j,i) = &
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z_ref + angular_quadrature_points(k,3) * r
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enddo
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enddo
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enddo
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END_PROVIDER
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BEGIN_PROVIDER [double precision, weight_at_r, (n_points_integration_angular,n_points_radial_grid,nucl_num) ]
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BEGIN_DOC
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! Weight function at grid points : w_n(r) according to the equation (22)
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! of Becke original paper (JCP, 88, 1988)
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!
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! The "n" discrete variable represents the nucleis which in this array is
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! represented by the last dimension and the points are labelled by the
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! other dimensions.
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END_DOC
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implicit none
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integer :: i,j,k,l,m
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double precision :: r(3)
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double precision :: accu,cell_function_becke
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double precision :: tmp_array(nucl_num)
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! run over all points in space
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! that are referred to each atom
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do j = 1, nucl_num
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!for each radial grid attached to the "jth" atom
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do k = 1, n_points_radial_grid -1
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! for each angular point attached to the "jth" atom
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do l = 1, n_points_integration_angular
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r(1) = grid_points_per_atom(1,l,k,j)
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r(2) = grid_points_per_atom(2,l,k,j)
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r(3) = grid_points_per_atom(3,l,k,j)
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accu = 0.d0
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! For each of these points in space, ou need to evaluate the P_n(r)
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do i = 1, nucl_num
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! function defined for each atom "i" by equation (13) and (21) with k == 3
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tmp_array(i) = cell_function_becke(r,i) ! P_n(r)
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! Then you compute the summ the P_n(r) function for each of the "r" points
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accu += tmp_array(i)
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enddo
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accu = 1.d0/accu
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weight_at_r(l,k,j) = tmp_array(j) * accu
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if(isnan(weight_at_r(l,k,j)))then
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print*,'isnan(weight_at_r(l,k,j))'
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print*,l,k,j
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accu = 0.d0
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do i = 1, nucl_num
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! function defined for each atom "i" by equation (13) and (21) with k == 3
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tmp_array(i) = cell_function_becke(r,i) ! P_n(r)
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print*,i,tmp_array(i)
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! Then you compute the summ the P_n(r) function for each of the "r" points
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accu += tmp_array(i)
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enddo
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write(*,'(100(F16.10,X))')tmp_array(j) , accu
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stop
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endif
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enddo
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enddo
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enddo
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END_PROVIDER
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BEGIN_PROVIDER [double precision, final_weight_at_r, (n_points_integration_angular,n_points_radial_grid,nucl_num) ]
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BEGIN_DOC
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! Total weight on each grid point which takes into account all Lebedev, Voronoi and radial weights.
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END_DOC
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implicit none
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integer :: i,j,k,l,m
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double precision :: r(3)
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double precision :: accu,cell_function_becke
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double precision :: tmp_array(nucl_num)
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double precision :: contrib_integration,x
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double precision :: derivative_knowles_function,knowles_function
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! run over all points in space
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do j = 1, nucl_num ! that are referred to each atom
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do i = 1, n_points_radial_grid -1 !for each radial grid attached to the "jth" atom
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x = grid_points_radial(i) ! x value for the mapping of the [0, +\infty] to [0,1]
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do k = 1, n_points_integration_angular ! for each angular point attached to the "jth" atom
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contrib_integration = derivative_knowles_function(alpha_knowles(grid_atomic_number(j)),m_knowles,x)&
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*knowles_function(alpha_knowles(grid_atomic_number(j)),m_knowles,x)**2
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final_weight_at_r(k,i,j) = weights_angular_points(k) * weight_at_r(k,i,j) * contrib_integration * dr_radial_integral
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if(isnan(final_weight_at_r(k,i,j)))then
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print*,'isnan(final_weight_at_r(k,i,j))'
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print*,k,i,j
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write(*,'(100(F16.10,X))')weights_angular_points(k) , weight_at_r(k,i,j) , contrib_integration , dr_radial_integral
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stop
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endif
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enddo
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enddo
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enddo
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END_PROVIDER
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