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347 lines
9.1 KiB
Fortran
347 lines
9.1 KiB
Fortran
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! Gradient
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! The gradient of the CI energy with respects to the orbital rotation
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! is:
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! (C-c C-x C-l)
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! $$
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! G(p,q) = \mathcal{P}_{pq} \left[ \sum_r (h_p^r \gamma_r^q - h_r^q \gamma_p^r) +
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! \sum_{rst}(v_{pt}^{rs} \Gamma_{rs}^{qt} - v_{rs}^{qt} \Gamma_{pt}^{rs})
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! \right]
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! $$
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! $$
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! \mathcal{P}_{pq}= 1 - (p \leftrightarrow q)
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! $$
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! $$
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! G(p,q) = \left[
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! \sum_r (h_p^r \gamma_r^q - h_r^q \gamma_p^r) +
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! \sum_{rst}(v_{pt}^{rs} \Gamma_{rs}^{qt} - v_{rs}^{qt} \Gamma_{pt}^{rs})
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! \right] -
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! \left[
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! \sum_r (h_q^r \gamma_r^p - h_r^p \gamma_q^r) +
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! \sum_{rst}(v_{qt}^{rs} \Gamma_{rs}^{pt} - v_{rs}^{pt}
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! \Gamma_{qt}^{rs})
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! \right]
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! $$
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! Where p,q,r,s,t are general spatial orbitals
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! mo_num : the number of molecular orbitals
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! $$h$$ : One electron integrals
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! $$\gamma$$ : One body density matrix (state average in our case)
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! $$v$$ : Two electron integrals
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! $$\Gamma$$ : Two body density matrice (state average in our case)
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! The gradient is a mo_num by mo_num matrix, p,q,r,s,t take all the
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! values between 1 and mo_num (1 and mo_num include).
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! To do that we compute $$G(p,q)$$ for all the pairs (p,q).
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! Source :
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! Seniority-based coupled cluster theory
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! J. Chem. Phys. 141, 244104 (2014); https://doi.org/10.1063/1.4904384
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! Thomas M. Henderson, Ireneusz W. Bulik, Tamar Stein, and Gustavo
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! E. Scuseria
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! *Compute the gradient of energy with respects to orbital rotations*
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! Provided:
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! | mo_num | integer | number of MOs |
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! | mo_one_e_integrals(mo_num,mo_num) | double precision | mono_electronic integrals |
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! | one_e_dm_mo(mo_num,mo_num) | double precision | one e- density matrix |
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! | two_e_dm_mo(mo_num,mo_num,mo_num,mo_num) | double precision | two e- density matrix |
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! Input:
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! | n | integer | mo_num*(mo_num-1)/2 |
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! Output:
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! | v_grad(n) | double precision | the gradient |
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! | max_elem | double precision | maximum element of the gradient |
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! Internal:
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! | grad(mo_num,mo_num) | double precison | gradient before the tranformation in a vector |
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! | A((mo_num,mo_num) | doubre precision | gradient after the permutations |
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! | norm | double precision | norm of the gradient |
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! | p, q | integer | indexes of the element in the matrix grad |
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! | i | integer | index for the tranformation in a vector |
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! | r, s, t | integer | indexes dor the sums |
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! | t1, t2, t3 | double precision | t3 = t2 - t1, time to compute the gradient |
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! | t4, t5, t6 | double precission | t6 = t5 - t4, time to compute each element |
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! | tmp_bi_int_3(mo_num,mo_num,mo_num) | double precision | 3 indexes temporary array for the bi-electronic integrals |
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! | tmp_2rdm_3(mo_num,mo_num,mo_num) | double precision | 3 indexes temporary array for the two e- density matrix |
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! | tmp_accu(mo_num,mo_num) | double precision | temporary array |
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! Function:
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! | get_two_e_integral | double precision | bi-electronic integrals |
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! | dnrm2 | double precision | (Lapack) norm |
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subroutine gradient_opt(n,v_grad,max_elem)
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use omp_lib
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include 'constants.h'
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implicit none
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! Variables
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! in
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integer, intent(in) :: n
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! out
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double precision, intent(out) :: v_grad(n), max_elem
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! internal
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double precision, allocatable :: grad(:,:),A(:,:)
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double precision :: norm
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integer :: i,p,q,r,s,t
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double precision :: t1,t2,t3,t4,t5,t6
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double precision, allocatable :: tmp_accu(:,:)
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double precision, allocatable :: tmp_bi_int_3(:,:,:), tmp_2rdm_3(:,:,:)
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! Functions
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double precision :: get_two_e_integral, dnrm2
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print*,''
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print*,'---gradient---'
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! Allocation of shared arrays
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allocate(grad(mo_num,mo_num),A(mo_num,mo_num))
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! Initialization omp
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call omp_set_max_active_levels(1)
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!$OMP PARALLEL &
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!$OMP PRIVATE( &
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!$OMP p,q,r,s,t, &
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!$OMP tmp_accu, tmp_bi_int_3, tmp_2rdm_3) &
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!$OMP SHARED(grad, one_e_dm_mo, mo_num,mo_one_e_integrals, &
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!$OMP mo_integrals_map,t4,t5,t6) &
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!$OMP DEFAULT(SHARED)
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! Allocation of private arrays
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allocate(tmp_accu(mo_num,mo_num))
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allocate(tmp_bi_int_3(mo_num,mo_num,mo_num))
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allocate(tmp_2rdm_3(mo_num,mo_num,mo_num))
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! Initialization
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!$OMP DO
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do q = 1, mo_num
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do p = 1,mo_num
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grad(p,q) = 0d0
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enddo
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enddo
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!$OMP END DO
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! Term 1
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! Without optimization the term 1 is :
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! do p = 1, mo_num
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! do q = 1, mo_num
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! do r = 1, mo_num
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! grad(p,q) = grad(p,q) &
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! + mo_one_e_integrals(p,r) * one_e_dm_mo(r,q) &
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! - mo_one_e_integrals(r,q) * one_e_dm_mo(p,r)
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! enddo
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! enddo
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! enddo
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! Since the matrix multiplication A.B is defined like :
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! \begin{equation}
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! c_{ij} = \sum_k a_{ik}.b_{kj}
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! \end{equation}
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! The previous equation can be rewritten as a matrix multplication
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!****************
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! Opt first term
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!****************
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!$OMP MASTER
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CALL wall_TIME(t4)
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!$OMP END MASTER
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call dgemm('N','N',mo_num,mo_num,mo_num,1d0,mo_one_e_integrals,&
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mo_num,one_e_dm_mo,mo_num,0d0,tmp_accu,mo_num)
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!$OMP DO
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do q = 1, mo_num
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do p = 1, mo_num
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grad(p,q) = grad(p,q) + (tmp_accu(p,q) - tmp_accu(q,p))
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enddo
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enddo
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!$OMP END DO
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!$OMP MASTER
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CALL wall_TIME(t5)
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t6 = t5-t4
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print*,'Gradient, first term (s) :', t6
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!$OMP END MASTER
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! Term 2
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! Without optimization the second term is :
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! do p = 1, mo_num
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! do q = 1, mo_num
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! do r = 1, mo_num
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! do s = 1, mo_num
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! do t= 1, mo_num
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! grad(p,q) = grad(p,q) &
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! + get_two_e_integral(p,t,r,s,mo_integrals_map) * two_e_dm_mo(r,s,q,t) &
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! - get_two_e_integral(r,s,q,t,mo_integrals_map) * two_e_dm_mo(p,t,r,s)
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! enddo
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! enddo
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! enddo
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! enddo
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! enddo
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! Using the bielectronic integral properties :
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! get_two_e_integral(p,t,r,s,mo_integrals_map) = get_two_e_integral(r,s,p,t,mo_integrals_map)
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! Using the two body matrix properties :
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! two_e_dm_mo(p,t,r,s) = two_e_dm_mo(r,s,p,t)
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! t is one the right, we can put it on the external loop and create 3
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! indexes temporary array
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! r,s can be seen as one index
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! By doing so, a matrix multiplication appears
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!*****************
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! Opt second term
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!*****************
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!$OMP MASTER
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CALL wall_TIME(t4)
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!$OMP END MASTER
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!$OMP DO
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do t = 1, mo_num
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do p = 1, mo_num
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do s = 1, mo_num
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do r = 1, mo_num
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tmp_bi_int_3(r,s,p) = get_two_e_integral(r,s,p,t,mo_integrals_map)
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enddo
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enddo
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enddo
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do q = 1, mo_num
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do s = 1, mo_num
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do r = 1, mo_num
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tmp_2rdm_3(r,s,q) = two_e_dm_mo(r,s,q,t)
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enddo
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enddo
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enddo
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call dgemm('T','N',mo_num,mo_num,mo_num*mo_num,1d0,tmp_bi_int_3,&
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mo_num*mo_num,tmp_2rdm_3,mo_num*mo_num,0d0,tmp_accu,mo_num)
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!$OMP CRITICAL
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do q = 1, mo_num
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do p = 1, mo_num
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grad(p,q) = grad(p,q) + tmp_accu(p,q) - tmp_accu(q,p)
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enddo
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enddo
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!$OMP END CRITICAL
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enddo
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!$OMP END DO
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!$OMP MASTER
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CALL wall_TIME(t5)
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t6 = t5-t4
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print*,'Gradient second term (s) : ', t6
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!$OMP END MASTER
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! Deallocation of private arrays
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deallocate(tmp_bi_int_3,tmp_2rdm_3,tmp_accu)
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!$OMP END PARALLEL
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call omp_set_max_active_levels(4)
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! Permutation, 2D matrix -> vector, transformation
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! In addition there is a permutation in the gradient formula :
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! \begin{equation}
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! P_{pq} = 1 - (p <-> q)
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! \end{equation}
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! We need a vector to use the gradient. Here the gradient is a
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! antisymetric matrix so we can transform it in a vector of length
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! mo_num*(mo_num-1)/2.
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! Here we do these two things at the same time.
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do i=1,n
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call vec_to_mat_index(i,p,q)
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v_grad(i)=(grad(p,q) - grad(q,p))
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enddo
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! Debug, diplay the vector containing the gradient elements
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if (debug) then
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print*,'Vector containing the gradient :'
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write(*,'(100(F10.5))') v_grad(1:n)
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endif
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! Norm of the gradient
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! The norm can be useful.
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norm = dnrm2(n,v_grad,1)
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print*, 'Gradient norm : ', norm
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! Maximum element in the gradient
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! The maximum element in the gradient is very important for the
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! convergence criterion of the Newton method.
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! Max element of the gradient
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max_elem = 0d0
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do i = 1, n
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if (ABS(v_grad(i)) > ABS(max_elem)) then
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max_elem = v_grad(i)
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endif
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enddo
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print*,'Max element in the gradient :', max_elem
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! Debug, display the matrix containting the gradient elements
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if (debug) then
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! Matrix gradient
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A = 0d0
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do q=1,mo_num
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do p=1,mo_num
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A(p,q) = grad(p,q) - grad(q,p)
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enddo
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enddo
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print*,'Matrix containing the gradient :'
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do i = 1, mo_num
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write(*,'(100(F10.5))') A(i,1:mo_num)
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enddo
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endif
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! Deallocation of shared arrays and end
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deallocate(grad,A)
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print*,'---End gradient---'
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end subroutine
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