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179 lines
4.6 KiB
Fortran
179 lines
4.6 KiB
Fortran
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! ---
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subroutine non_hrmt_bieig(n, A, thr_d, thr_nd, leigvec, reigvec, n_real_eigv, eigval)
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BEGIN_DOC
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!
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! routine which returns the sorted REAL EIGENVALUES ONLY and corresponding LEFT/RIGHT eigenvetors
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! of a non hermitian matrix A(n,n)
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!
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! n_real_eigv is the number of real eigenvalues, which might be smaller than the dimension "n"
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!
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END_DOC
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implicit none
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integer, intent(in) :: n
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double precision, intent(in) :: A(n,n)
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double precision, intent(in) :: thr_d, thr_nd
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integer, intent(out) :: n_real_eigv
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double precision, intent(out) :: reigvec(n,n), leigvec(n,n), eigval(n)
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integer :: i, j,k
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integer :: n_good
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double precision :: thr, thr_cut, thr_diag, thr_norm
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double precision :: accu_d, accu_nd
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integer, allocatable :: list_good(:), iorder(:), deg_num(:)
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double precision, allocatable :: WR(:), WI(:), VL(:,:), VR(:,:)
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double precision, allocatable :: S(:,:)
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double precision, allocatable :: phi_1_tilde(:),phi_2_tilde(:),chi_1_tilde(:),chi_2_tilde(:)
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allocate(phi_1_tilde(n),phi_2_tilde(n),chi_1_tilde(n),chi_2_tilde(n))
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allocate(WR(n), WI(n), VL(n,n), VR(n,n))
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call lapack_diag_non_sym(n, A, WR, WI, VL, VR)
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thr_diag = 1d-06
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thr_norm = 1d+10
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! ---
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! track & sort the real eigenvalues
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n_good = 0
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thr = Im_thresh_tc
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do i = 1, n
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if(dabs(WI(i)) .lt. thr) then
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n_good += 1
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else
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print*, 'Found an imaginary component to eigenvalue on i = ', i
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print*, 'Re(i) + Im(i)', WR(i), WI(i)
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endif
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enddo
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if(n_good.ne.n) then
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print*,'there are some imaginary eigenvalues '
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thr_diag = 1d-03
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n_good = n
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endif
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allocate(list_good(n_good), iorder(n_good))
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n_good = 0
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do i = 1, n
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n_good += 1
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list_good(n_good) = i
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eigval(n_good) = WR(i)
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enddo
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deallocate( WR, WI )
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n_real_eigv = n_good
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do i = 1, n_good
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iorder(i) = i
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enddo
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call dsort(eigval, iorder, n_good)
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reigvec(:,:) = 0.d0
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leigvec(:,:) = 0.d0
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do i = 1, n_real_eigv
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do j = 1, n
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reigvec(j,i) = VR(j,list_good(iorder(i)))
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leigvec(j,i) = VL(j,list_good(iorder(i)))
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enddo
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enddo
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deallocate( list_good, iorder )
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deallocate( VL, VR )
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ASSERT(n==n_real_eigv)
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! ---
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! check bi-orthogonality
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thr_diag = 10.d0
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thr_norm = 1d+10
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allocate( S(n_real_eigv,n_real_eigv) )
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call check_biorthog(n, n_real_eigv, leigvec, reigvec, accu_d, accu_nd, S, thr_d, thr_nd, .false.)
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if( (accu_nd .lt. thr_nd) .and. (dabs(accu_d-dble(n_real_eigv))/dble(n_real_eigv) .lt. thr_d) ) then
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print *, ' lapack vectors are normalized and bi-orthogonalized'
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deallocate(S)
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return
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! accu_nd is modified after adding the normalization
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elseif( (accu_nd .lt. thr_nd) .and. (dabs(accu_d-dble(n_real_eigv))/dble(n_real_eigv) .gt. thr_d) ) then
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print *, ' lapack vectors are not normalized but bi-orthogonalized'
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call check_biorthog_binormalize(n, n_real_eigv, leigvec, reigvec, thr_d, thr_nd, .true.)
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call check_biorthog(n, n_real_eigv, leigvec, reigvec, accu_d, accu_nd, S, thr_d, thr_nd, .true.)
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call check_EIGVEC(n, n, A, eigval, leigvec, reigvec, thr_diag, thr_norm, .true.)
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deallocate(S)
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return
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else
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print *, ' lapack vectors are not normalized neither bi-orthogonalized'
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allocate(deg_num(n))
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call reorder_degen_eigvec(n, deg_num, eigval, leigvec, reigvec)
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call impose_biorthog_degen_eigvec(n, deg_num, eigval, leigvec, reigvec)
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deallocate(deg_num)
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call check_biorthog(n, n_real_eigv, leigvec, reigvec, accu_d, accu_nd, S, thr_d, thr_nd, .false.)
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if( (accu_nd .lt. thr_nd) .and. (dabs(accu_d-dble(n_real_eigv)) .gt. thr_d) ) then
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call check_biorthog_binormalize(n, n_real_eigv, leigvec, reigvec, thr_d, thr_nd, .true.)
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endif
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call check_biorthog(n, n_real_eigv, leigvec, reigvec, accu_d, accu_nd, S, thr_d, thr_nd, .true.)
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deallocate(S)
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endif
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return
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end
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! ---
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subroutine check_bi_ortho(reigvec, leigvec, n, S, accu_nd)
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BEGIN_DOC
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! retunrs the overlap matrix S = Leigvec^T Reigvec
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!
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! and the square root of the sum of the squared off-diagonal elements of S
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END_DOC
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implicit none
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integer, intent(in) :: n
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double precision, intent(in) :: reigvec(n,n), leigvec(n,n)
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double precision, intent(out) :: S(n,n), accu_nd
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integer :: i,j
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! S = VL x VR
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call dgemm( 'T', 'N', n, n, n, 1.d0 &
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, leigvec, size(leigvec, 1), reigvec, size(reigvec, 1) &
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, 0.d0, S, size(S, 1) )
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accu_nd = 0.d0
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do i = 1, n
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do j = 1, n
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if(i.ne.j) then
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accu_nd = accu_nd + S(j,i) * S(j,i)
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endif
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enddo
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enddo
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accu_nd = dsqrt(accu_nd)
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end
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