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442 lines
12 KiB
Fortran
442 lines
12 KiB
Fortran
! Rotation matrix
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! *Build a rotation matrix from an antisymmetric matrix*
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! Compute a rotation matrix $\textbf{R}$ from an antisymmetric matrix $$\textbf{A}$$ such as :
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! $$
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! \textbf{R}=\exp(\textbf{A})
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! $$
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! So :
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! \begin{align*}
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! \textbf{R}=& \exp(\textbf{A}) \\
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! =& \sum_k^{\infty} \frac{1}{k!}\textbf{A}^k \\
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! =& \textbf{W} \cdot \cos(\tau) \cdot \textbf{W}^{\dagger} + \textbf{W} \cdot \tau^{-1} \cdot \sin(\tau) \cdot \textbf{W}^{\dagger} \cdot \textbf{A}
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! \end{align*}
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! With :
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! $\textbf{W}$ : eigenvectors of $\textbf{A}^2$
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! $\tau$ : $\sqrt{-x}$
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! $x$ : eigenvalues of $\textbf{A}^2$
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! Input:
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! | A(n,n) | double precision | antisymmetric matrix |
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! | n | integer | number of columns of the A matrix |
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! | LDA | integer | specifies the leading dimension of A, must be at least max(1,n) |
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! | LDR | integer | specifies the leading dimension of R, must be at least max(1,n) |
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! Output:
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! | R(n,n) | double precision | Rotation matrix |
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! | info | integer | if info = 0, the execution is successful |
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! | | | if info = k, the k-th parameter has an illegal value |
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! | | | if info = -k, the algorithm failed |
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! Internal:
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! | B(n,n) | double precision | B = A.A |
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! | work(lwork,n) | double precision | work matrix for dysev, dimension max(1,lwork) |
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! | lwork | integer | dimension of the syev work array >= max(1, 3n-1) |
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! | W(n,n) | double precision | eigenvectors of B |
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! | e_val(n) | double precision | eigenvalues of B |
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! | m_diag(n,n) | double precision | diagonal matrix with the eigenvalues of B |
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! | cos_tau(n,n) | double precision | diagonal matrix with cos(tau) values |
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! | sin_tau(n,n) | double precision | diagonal matrix with sin cos(tau) values |
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! | tau_m1(n,n) | double precision | diagonal matrix with (tau)^-1 values |
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! | part_1(n,n) | double precision | matrix W.cos_tau.W^t |
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! | part_1a(n,n) | double precision | matrix cos_tau.W^t |
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! | part_2(n,n) | double precision | matrix W.tau_m1.sin_tau.W^t.A |
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! | part_2a(n,n) | double precision | matrix W^t.A |
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! | part_2b(n,n) | double precision | matrix sin_tau.W^t.A |
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! | part_2c(n,n) | double precision | matrix tau_m1.sin_tau.W^t.A |
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! | RR_t(n,n) | double precision | R.R^t must be equal to the identity<=> R.R^t-1=0 <=> norm = 0 |
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! | norm | integer | norm of R.R^t-1, must be equal to 0 |
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! | i,j | integer | indexes |
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! Functions:
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! | dnrm2 | double precision | Lapack function, compute the norm of a matrix |
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! | disnan | logical | Lapack function, check if an element is NaN |
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subroutine rotation_matrix(A,LDA,R,LDR,n,info,enforce_step_cancellation)
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implicit none
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!BEGIN_DOC
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! Rotation matrix to rotate the molecular orbitals.
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! If the rotation is too large the transformation is not unitary and must be cancelled.
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!END_DOC
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include 'pi.h'
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! Variables
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! in
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integer, intent(in) :: n,LDA,LDR
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double precision, intent(inout) :: A(LDA,n)
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! out
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double precision, intent(out) :: R(LDR,n)
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integer, intent(out) :: info
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logical, intent(out) :: enforce_step_cancellation
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! internal
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double precision, allocatable :: B(:,:)
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double precision, allocatable :: work(:,:)
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double precision, allocatable :: W(:,:), e_val(:)
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double precision, allocatable :: m_diag(:,:),cos_tau(:,:),sin_tau(:,:),tau_m1(:,:)
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double precision, allocatable :: part_1(:,:),part_1a(:,:)
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double precision, allocatable :: part_2(:,:),part_2a(:,:),part_2b(:,:),part_2c(:,:)
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double precision, allocatable :: RR_t(:,:)
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integer :: i,j
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integer :: info2, lwork ! for dsyev
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double precision :: norm, max_elem, max_elem_A, t1,t2,t3
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! function
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double precision :: dnrm2
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logical :: disnan
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print*,''
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print*,'---rotation_matrix---'
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call wall_time(t1)
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! Allocation
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allocate(B(n,n))
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allocate(m_diag(n,n),cos_tau(n,n),sin_tau(n,n),tau_m1(n,n))
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allocate(W(n,n),e_val(n))
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allocate(part_1(n,n),part_1a(n,n))
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allocate(part_2(n,n),part_2a(n,n),part_2b(n,n),part_2c(n,n))
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allocate(RR_t(n,n))
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! Pre-conditions
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! Initialization
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info=0
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enforce_step_cancellation = .False.
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! Size of matrix A must be at least 1 by 1
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if (n<1) then
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info = 3
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print*, 'WARNING: invalid parameter 5'
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print*, 'n<1'
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return
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endif
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! Leading dimension of A must be >= n
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if (LDA < n) then
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info = 25
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print*, 'WARNING: invalid parameter 2 or 5'
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print*, 'LDA < n'
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return
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endif
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! Leading dimension of A must be >= n
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if (LDR < n) then
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info = 4
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print*, 'WARNING: invalid parameter 4'
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print*, 'LDR < n'
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return
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endif
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! Matrix elements of A must by non-NaN
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do j = 1, n
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do i = 1, n
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if (disnan(A(i,j))) then
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info=1
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print*, 'WARNING: invalid parameter 1'
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print*, 'NaN element in A matrix'
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return
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endif
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enddo
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enddo
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do i = 1, n
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if (A(i,i) /= 0d0) then
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print*, 'WARNING: matrix A is not antisymmetric'
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print*, 'Non 0 element on the diagonal', i, A(i,i)
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call ABORT
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endif
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enddo
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do j = 1, n
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do i = 1, n
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if (A(i,j)+A(j,i)>1d-16) then
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print*, 'WANRING: matrix A is not antisymmetric'
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print*, 'A(i,j) /= - A(j,i):', i,j,A(i,j), A(j,i)
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print*, 'diff:', A(i,j)+A(j,i)
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call ABORT
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endif
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enddo
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enddo
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! Fix for too big elements ! bad idea better to cancel if the error is too big
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!do j = 1, n
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! do i = 1, n
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! A(i,j) = mod(A(i,j),2d0*pi)
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! if (dabs(A(i,j)) > pi) then
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! A(i,j) = 0d0
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! endif
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! enddo
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!enddo
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max_elem_A = 0d0
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do j = 1, n
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do i = 1, n
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if (ABS(A(i,j)) > ABS(max_elem_A)) then
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max_elem_A = A(i,j)
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endif
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enddo
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enddo
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!print*,'max element in A', max_elem_A
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if (ABS(max_elem_A) > 2 * pi) then
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print*,''
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print*,'WARNING: ABS(max_elem_A) > 2 pi '
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print*,''
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endif
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! B=A.A
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! - Calculation of the matrix $\textbf{B} = \textbf{A}^2$
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! - Diagonalization of $\textbf{B}$
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! W, the eigenvectors
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! e_val, the eigenvalues
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! Compute B=A.A
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call dgemm('N','N',n,n,n,1d0,A,size(A,1),A,size(A,1),0d0,B,size(B,1))
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! Copy B in W, diagonalization will put the eigenvectors in W
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W=B
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! Diagonalization of B
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! Eigenvalues -> e_val
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! Eigenvectors -> W
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lwork = 3*n-1
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allocate(work(lwork,n))
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!print*,'Starting diagonalization ...'
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call dsyev('V','U',n,W,size(W,1),e_val,work,lwork,info2)
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deallocate(work)
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if (info2 < 0) then
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print*, 'WARNING: error in the diagonalization'
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print*, 'Illegal value of the ', info2,'-th parameter'
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elseif (info2 >0) then
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print*, "WARNING: Diagonalization failed to converge"
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endif
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! Tau^-1, cos(tau), sin(tau)
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! $$\tau = \sqrt{-x}$$
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! - Calculation of $\cos(\tau)$ $\Leftrightarrow$ $\cos(\sqrt{-x})$
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! - Calculation of $\sin(\tau)$ $\Leftrightarrow$ $\sin(\sqrt{-x})$
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! - Calculation of $\tau^{-1}$ $\Leftrightarrow$ $(\sqrt{-x})^{-1}$
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! These matrices are diagonals
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! Diagonal matrix m_diag
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do j = 1, n
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if (e_val(j) >= -1d-12) then !0.d0) then !!! e_avl(i) must be < -1d-12 to avoid numerical problems
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e_val(j) = 0.d0
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else
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e_val(j) = - e_val(j)
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endif
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enddo
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m_diag = 0.d0
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do i = 1, n
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m_diag(i,i) = e_val(i)
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enddo
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! cos_tau
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do j = 1, n
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do i = 1, n
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if (i==j) then
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cos_tau(i,j) = dcos(dsqrt(e_val(i)))
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else
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cos_tau(i,j) = 0d0
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endif
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enddo
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enddo
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! sin_tau
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do j = 1, n
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do i = 1, n
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if (i==j) then
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sin_tau(i,j) = dsin(dsqrt(e_val(i)))
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else
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sin_tau(i,j) = 0d0
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endif
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enddo
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enddo
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! Debug, display the cos_tau and sin_tau matrix
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!if (debug) then
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! print*, 'cos_tau'
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! do i = 1, n
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! print*, cos_tau(i,:)
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! enddo
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! print*, 'sin_tau'
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! do i = 1, n
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! print*, sin_tau(i,:)
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! enddo
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!endif
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! tau^-1
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do j = 1, n
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do i = 1, n
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if ((i==j) .and. (e_val(i) > 1d-16)) then!0d0)) then !!! Convergence problem can come from here if the threshold is too big/small
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tau_m1(i,j) = 1d0/(dsqrt(e_val(i)))
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else
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tau_m1(i,j) = 0d0
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endif
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enddo
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enddo
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max_elem = 0d0
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do i = 1, n
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if (ABS(tau_m1(i,i)) > ABS(max_elem)) then
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max_elem = tau_m1(i,i)
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endif
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enddo
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!print*,'max elem tau^-1:', max_elem
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! Debug
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!print*,'eigenvalues:'
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!do i = 1, n
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! print*, e_val(i)
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!enddo
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!Debug, display tau^-1
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!if (debug) then
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! print*, 'tau^-1'
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! do i = 1, n
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! print*,tau_m1(i,:)
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! enddo
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!endif
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! Rotation matrix
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! \begin{align*}
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! \textbf{R} = \textbf{W} \cos(\tau) \textbf{W}^{\dagger} + \textbf{W} \tau^{-1} \sin(\tau) \textbf{W}^{\dagger} \textbf{A}
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! \end{align*}
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! \begin{align*}
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! \textbf{Part1} = \textbf{W} \cos(\tau) \textbf{W}^{\dagger}
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! \end{align*}
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! \begin{align*}
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! \textbf{Part2} = \textbf{W} \tau^{-1} \sin(\tau) \textbf{W}^{\dagger} \textbf{A}
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! \end{align*}
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! First:
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! part_1 = dgemm(W, dgemm(cos_tau, W^t))
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! part_1a = dgemm(cos_tau, W^t)
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! part_1 = dgemm(W, part_1a)
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! And:
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! part_2= dgemm(W, dgemm(tau_m1, dgemm(sin_tau, dgemm(W^t, A))))
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! part_2a = dgemm(W^t, A)
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! part_2b = dgemm(sin_tau, part_2a)
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! part_2c = dgemm(tau_m1, part_2b)
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! part_2 = dgemm(W, part_2c)
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! Finally:
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! Rotation matrix, R = part_1+part_2
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! If $R$ is a rotation matrix:
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! $R.R^T=R^T.R=\textbf{1}$
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! part_1
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call dgemm('N','T',n,n,n,1d0,cos_tau,size(cos_tau,1),W,size(W,1),0d0,part_1a,size(part_1a,1))
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call dgemm('N','N',n,n,n,1d0,W,size(W,1),part_1a,size(part_1a,1),0d0,part_1,size(part_1,1))
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! part_2
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call dgemm('T','N',n,n,n,1d0,W,size(W,1),A,size(A,1),0d0,part_2a,size(part_2a,1))
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call dgemm('N','N',n,n,n,1d0,sin_tau,size(sin_tau,1),part_2a,size(part_2a,1),0d0,part_2b,size(part_2b,1))
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call dgemm('N','N',n,n,n,1d0,tau_m1,size(tau_m1,1),part_2b,size(part_2b,1),0d0,part_2c,size(part_2c,1))
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call dgemm('N','N',n,n,n,1d0,W,size(W,1),part_2c,size(part_2c,1),0d0,part_2,size(part_2,1))
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! Rotation matrix R
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R = part_1 + part_2
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! Matrix check
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! R.R^t and R^t.R must be equal to identity matrix
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do j = 1, n
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do i=1,n
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if (i==j) then
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RR_t(i,j) = 1d0
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else
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RR_t(i,j) = 0d0
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endif
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enddo
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enddo
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call dgemm('N','T',n,n,n,1d0,R,size(R,1),R,size(R,1),-1d0,RR_t,size(RR_t,1))
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norm = dnrm2(n*n,RR_t,1)
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!print*, 'Rotation matrix check, norm R.R^T = ', norm
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! Debug
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!if (debug) then
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! print*, 'RR_t'
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! do i = 1, n
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! print*, RR_t(i,:)
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! enddo
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!endif
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! Post conditions
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! Check if R.R^T=1
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max_elem = 0d0
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do j = 1, n
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do i = 1, n
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if (ABS(RR_t(i,j)) > ABS(max_elem)) then
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max_elem = RR_t(i,j)
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endif
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enddo
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enddo
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print*, 'Max error in R.R^T:', max_elem
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!print*, 'e_val(1):', e_val(1)
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!print*, 'e_val(n):', e_val(n)
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!print*, 'max elem in A:', max_elem_A
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if (ABS(max_elem) > 1d-12) then
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print*, 'WARNING: max error in R.R^T > 1d-12'
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print*, 'Enforce the step cancellation'
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enforce_step_cancellation = .True.
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endif
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! Matrix elements of R must by non-NaN
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do j = 1,n
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do i = 1,LDR
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if (disnan(R(i,j))) then
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info = 666
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print*, 'NaN in rotation matrix'
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call ABORT
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endif
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enddo
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enddo
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! Display
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!if (debug) then
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! print*,'Rotation matrix :'
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! do i = 1, n
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! write(*,'(100(F10.5))') R(i,:)
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! enddo
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!endif
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! Deallocation, end
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deallocate(B)
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deallocate(m_diag,cos_tau,sin_tau,tau_m1)
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deallocate(W,e_val)
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deallocate(part_1,part_1a)
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deallocate(part_2,part_2a,part_2b,part_2c)
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deallocate(RR_t)
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call wall_time(t2)
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t3 = t2-t1
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print*,'Time in rotation matrix:', t3
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print*,'---End rotation_matrix---'
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end subroutine
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