BEGIN_PROVIDER [ double precision, factor_een ] implicit none BEGIN_DOC ! ElectronE-electron-nuclei contribution to Jastrow factor ! ! 5436.20340250000 END_DOC integer :: i, j, a, p, k, l, lmax, m, n double precision :: cn, accu2, accu ! factor_een = factor_een_blas ! return factor_een = 0.0d0 do p = 2, ncord do k = 0, p - 1 if (k /= 0) then lmax = p - k else lmax = p - k - 2 endif do l = 0, lmax if ( iand(p - k - l, 1) == 1) cycle m = (p - k - l) / 2 do a = 1, nnuc accu2 = 0.d0 cn = cord_vect_lkp(l, k, p, typenuc_arr(a)) do j = 1, nelec accu = 0.d0 do i = 1, nelec accu = accu + & rescale_een_e(i,j,k) * & rescale_een_n(i,a,m) enddo accu2 = accu2 + accu*rescale_een_n(j,a,m+l) enddo factor_een = factor_een + accu2 * cn enddo enddo enddo enddo END_PROVIDER BEGIN_PROVIDER [ double precision, factor_een_deriv_e, (4, nelec) ] implicit none integer :: i, j, a, p, k, l, lmax, m, n double precision :: cn, accu, accu2, daccu(1:4), daccu2(1:4) factor_een_deriv_e(1:4,1:nelec) = 0.0d0 do p = 2, ncord do k = 0, p - 1 if (k /= 0) then lmax = p - k else lmax = p - k - 2 endif do l = 0, lmax if ( iand(p - k - l, 1) == 1) cycle m = (p - k - l) / 2 do a = 1, nnuc cn = cord_vect_lkp(l, k, p, typenuc_arr(a)) do j = 1, nelec accu=0.d0 accu2 = 0.d0 daccu (1:4) = 0.d0 daccu2(1:4) = 0.d0 do i = 1, nelec accu = accu + & rescale_een_e(i,j,k) * & rescale_een_n(i,a,m) accu2 = accu2 + & rescale_een_e(i,j,k) * & rescale_een_n(i,a,m+l) daccu(1:4) = daccu(1:4) + & rescale_een_e_deriv_e(1:4,j,i,k) * & rescale_een_n(i,a,m) daccu2(1:4) = daccu2(1:4) + & rescale_een_e_deriv_e(1:4,j,i,k) * & rescale_een_n(i,a,m+l) enddo factor_een_deriv_e(1:4,j) = factor_een_deriv_e(1:4,j) + & (accu * rescale_een_n_deriv_e(1:4,j,a,m+l) + daccu(1:4) * rescale_een_n(j,a,m+l) + & daccu2(1:4)* rescale_een_n(j,a,m) + accu2*rescale_een_n_deriv_e(1:4,j,a,m)) * cn factor_een_deriv_e(4,j) = factor_een_deriv_e(4,j) + 2.d0*( & daccu (1) * rescale_een_n_deriv_e(1,j,a,m+l) + & daccu (2) * rescale_een_n_deriv_e(2,j,a,m+l) + & daccu (3) * rescale_een_n_deriv_e(3,j,a,m+l) + & daccu2(1) * rescale_een_n_deriv_e(1,j,a,m ) + & daccu2(2) * rescale_een_n_deriv_e(2,j,a,m ) + & daccu2(3) * rescale_een_n_deriv_e(3,j,a,m ) )*cn enddo enddo enddo enddo enddo END_PROVIDER BEGIN_PROVIDER [ double precision, factor_een_deriv_e_ref, (4, nelec) ] implicit none BEGIN_DOC ! Dimensions 1-3 : dx, dy, dz ! Dimension 4 : d2x + d2y + d2z END_DOC integer :: i, ii, j, a, p, k, l, lmax, m double precision :: riam, rjam_cn, rial, rjal, rijk double precision, dimension(4) :: driam, drjam_cn, drial, drjal, drijk double precision :: cn, v1, v2, d1, d2, lap1, lap2 factor_een_deriv_e_ref = 0.0d0 do p = 2, ncord do k = 0 , p - 1 if (k /= 0) then lmax = p - k else lmax = p - k - 2 endif do l = 0, lmax if ( iand(p - k - l, 1) == 1) cycle m = (p - k - l) / 2 do a = 1, nnuc cn = cord_vect_lkp(l, k, p, typenuc_arr(a)) do j = 1, nelec rjal = rescale_een_n(j, a, l) rjam_cn = rescale_een_n(j, a, m) * cn do ii = 1, 4 drjal(ii) = rescale_een_n_deriv_e(ii, j, a, l) drjam_cn(ii) = rescale_een_n_deriv_e(ii, j, a, m) * cn enddo do i = 1, nelec rial = rescale_een_n(i, a, l) + rjal riam = rescale_een_n(i, a, m) rijk = rescale_een_e(i, j, k) do ii = 1, 4 drijk(ii) = rescale_een_e_deriv_e(ii, j, i, k) enddo v1 = rijk * rial ! v(x) v2 = rjam_cn * riam ! u(x) lap1 = 0.0d0 lap2 = 0.0d0 do ii = 1, 3 d1 = drijk(ii) * rial + rijk * drjal(ii) d2 = drjam_cn(ii) * riam lap1 = lap1 + d1 * d2 lap2 = lap2 + drijk(ii) * drjal(ii) factor_een_deriv_e_ref(ii, j) = factor_een_deriv_e_ref(ii, j) + v1 * d2 + d1 * v2 enddo ! v(x) u''(x) + 2 * u'(x) v'(x) + u(x) v''(x) ii = 4 d1 = drijk(ii) * rial + rijk * drjal(ii) + lap2 + lap2 d2 = drjam_cn(ii) * riam factor_een_deriv_e_ref(ii, j) = factor_een_deriv_e_ref(ii, j) + v1 * d2 + d1 * v2 + lap1 + lap1 enddo enddo enddo enddo enddo enddo END_PROVIDER