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1652 lines
54 KiB
Fortran
1652 lines
54 KiB
Fortran
! Newton's method to find the optimal lambda
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! *Compute the lambda value for the trust region*
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! This subroutine uses the Newton method in order to find the optimal
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! lambda. This constant is added on the diagonal of the hessian to shift
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! the eiganvalues. It has a double role:
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! - ensure that the resulting hessian is positive definite for the
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! Newton method
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! - constrain the step in the trust region, i.e.,
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! $||\textbf{x}(\lambda)|| \leq \Delta$, where $\Delta$ is the radius
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! of the trust region.
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! We search $\lambda$ which minimizes
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! \begin{align*}
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! f(\lambda) = (||\textbf{x}_{(k+1)}(\lambda)||^2 -\Delta^2)^2
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! \end{align*}
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! or
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! \begin{align*}
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! \tilde{f}(\lambda) = (\frac{1}{||\textbf{x}_{(k+1)}(\lambda)||^2}-\frac{1}{\Delta^2})^2
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! \end{align*}
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! and gives obviously 0 in both cases. \newline
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! There are several cases:
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! - If $\textbf{H}$ is positive definite the interval containing the
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! solution is $\lambda \in (0, \infty)$ (and $-h_1 < 0$).
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! - If $\textbf{H}$ is indefinite ($h_1 < 0$) and $\textbf{w}_1^T \cdot
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! \textbf{g} \neq 0$ then the interval containing
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! the solution is $\lambda \in (-h_1, \infty)$.
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! - If $\textbf{H}$ is indefinite ($h_1 < 0$) and $\textbf{w}_1^T \cdot
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! \textbf{g} = 0$ then the interval containing the solution is
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! $\lambda \in (-h_1, \infty)$. The terms where $|h_i - \lambda| <
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! 10^{-12}$ are not computed, so the term where $i = 1$ is
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! automatically removed and this case becomes similar to the previous one.
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! So to avoid numerical problems (cf. trust_region) we start the
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! algorithm at $\lambda=\max(0 + \epsilon,-h_1 + \epsilon)$,
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! with $\epsilon$ a little constant.
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! The research must be restricted to the interval containing the
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! solution. For that reason a little trust region in 1D is used.
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! The Newton method to find the optimal $\lambda$ is :
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! \begin{align*}
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! \lambda_{(l+1)} &= \lambda_{(l)} - f^{''}(\lambda)_{(l)}^{-1} f^{'}(\lambda)_{(l)}^{} \\
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! \end{align*}
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! $f^{'}(\lambda)_{(l)}$: the first derivative of $f$ with respect to
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! $\lambda$ at the l-th iteration,
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! $f^{''}(\lambda)_{(l)}$: the second derivative of $f$ with respect to
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! $\lambda$ at the l-th iteration.\newline
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! Noting the Newton step $y = - f^{''}(\lambda)_{(l)}^{-1}
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! f^{'}(\lambda)_{(l)}^{}$ we constrain $y$ such as
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! \begin{align*}
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! y \leq \alpha
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! \end{align*}
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! with $\alpha$ a scalar representing the trust length (trust region in
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! 1D) where the function $f$ or $\tilde{f}$ is correctly describe by the
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! Taylor series truncated at the second order. Thus, if $y > \alpha$,
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! the constraint is applied as
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! \begin{align*}
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! y^* = \alpha \frac{y}{|y|}
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! \end{align*}
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! with $y^*$ the solution in the trust region.
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! The size of the trust region evolves in function of $\rho$ as for the
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! trust region seen previously cf. trust_region, rho_model.
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! The prediction of the value of $f$ or $\tilde{f}$ is done using the
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! Taylor series truncated at the second order cf. "trust_region",
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! "trust_e_model".
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! The first and second derivatives of $f(\lambda) = (||\textbf{x}(\lambda)||^2 -
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! \Delta^2)^2$ with respect to $\lambda$ are:
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! \begin{align*}
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! \frac{\partial }{\partial \lambda} (||\textbf{x}(\lambda)||^2 - \Delta^2)^2
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! = 2 \left(\sum_{i=1}^n \frac{-2(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \right)
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! \left( - \Delta^2 + \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i+ \lambda)^2} \right)
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! \end{align*}
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! \begin{align*}
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! \frac{\partial^2}{\partial \lambda^2} (||\textbf{x}(\lambda)||^2 - \Delta^2)^2
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! = 2 \left[ \left( \sum_{i=1}^n 6 \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^4} \right) \left( - \Delta^2 + \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \right) + \left( \sum_{i=1}^n -2 \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \right)^2 \right]
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! \end{align*}
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! The first and second derivatives of $\tilde{f}(\lambda) = (1/||\textbf{x}(\lambda)||^2 -
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! 1/\Delta^2)^2$ with respect to $\lambda$ are:
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! \begin{align*}
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! \frac{\partial}{\partial \lambda} (1/||\textbf{x}(\lambda)||^2 - 1/\Delta^2)^2
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! &= 4 \frac{\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3}}
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! {(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
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! - \frac{4}{\Delta^2} \frac{\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3)}}
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! {(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \\
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! &= 4 \sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3}
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! \left( \frac{1}{(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
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! - \frac{1}{\Delta^2 (\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \right)
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! \end{align*}
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! \begin{align*}
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! \frac{\partial^2}{\partial \lambda^2} (1/||\textbf{x}(\lambda)||^2 - 1/\Delta^2)^2
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! &= 4 \left[ \frac{(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3)})^2}
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! {(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^4}
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! - 3 \frac{\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^4}}
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! {(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3} \right] \\
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! &- \frac{4}{\Delta^2} \left[ \frac{(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}
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! {(h_i + \lambda)^3)})^2}{(\sum_ {i=1}^n\frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
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! - 3 \frac{\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^4}}
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! {(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \right]
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! \end{align*}
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! Provided in qp_edit:
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! | thresh_rho_2 |
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! | thresh_cc |
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! | nb_it_max_lambda |
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! | version_lambda_search |
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! | nb_it_max_pre_search |
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! see qp_edit for more details
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! Input:
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! | n | integer | m*(m-1)/2 |
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! | e_val(n) | double precision | eigenvalues of the hessian |
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! | tmp_wtg(n) | double precision | w_i^T.v_grad(i) |
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! | delta | double precision | delta for the trust region |
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! Output:
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! | lambda | double precision | Lagrange multiplier to constrain the norm of the size of the Newton step |
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! | | | lambda > 0 |
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! Internal:
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! | d1_N | double precision | value of d1_norm_trust_region |
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! | d2_N | double precision | value of d2_norm_trust_region |
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! | f_N | double precision | value of f_norm_trust_region |
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! | prev_f_N | double precision | previous value of f_norm_trust_region |
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! | f_R | double precision | (norm(x)^2 - delta^2)^2 or (1/norm(x)^2 - 1/delta^2)^2 |
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! | prev_f_R | double precision | previous value of f_R |
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! | model | double precision | predicted value of f_R from prev_f_R and y |
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! | d_1 | double precision | value of the first derivative |
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! | d_2 | double precision | value of the second derivative |
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! | y | double precision | Newton's step, y = -f''^-1 . f' = lambda - prev_lambda |
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! | prev_lambda | double precision | previous value of lambda |
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! | t1,t2,t3 | double precision | wall time |
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! | i | integer | index |
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! | epsilon | double precision | little constant to avoid numerical problem |
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! | rho_2 | double precision | (prev_f_R - f_R)/(prev_f_R - model), agreement between model and f_R |
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! | version | integer | version of the root finding method |
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! Function:
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! | d1_norm_trust_region | double precision | first derivative with respect to lambda of (norm(x)^2 - Delta^2)^2 |
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! | d2_norm_trust_region | double precision | first derivative with respect to lambda of (norm(x)^2 - Delta^2)^2 |
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! | d1_norm_inverse_trust_region | double precision | first derivative with respect to lambda of (1/norm(x)^2 - 1/Delta^2)^2 |
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! | d2_norm_inverse_trust_region | double precision | second derivative with respect to lambda of (1/norm(x)^2 - 1/Delta^2)^2 |
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! | f_norm_trust_region | double precision | value of norm(x)^2 |
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subroutine trust_region_optimal_lambda(n,e_val,tmp_wtg,delta,lambda)
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include 'pi.h'
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!BEGIN_DOC
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! Research the optimal lambda to constrain the step size in the trust region
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!END_DOC
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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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double precision, intent(inout) :: e_val(n)
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double precision, intent(in) :: delta
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double precision, intent(in) :: tmp_wtg(n)
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! out
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double precision, intent(out) :: lambda
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! Internal
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double precision :: d1_N, d2_N, f_N, prev_f_N
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double precision :: prev_f_R, f_R
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double precision :: model
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double precision :: d_1, d_2
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double precision :: t1,t2,t3
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integer :: i
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double precision :: epsilon
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double precision :: y
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double precision :: prev_lambda
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double precision :: rho_2
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double precision :: alpha
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integer :: version
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! Functions
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double precision :: d1_norm_trust_region,d1_norm_trust_region_omp
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double precision :: d2_norm_trust_region, d2_norm_trust_region_omp
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double precision :: f_norm_trust_region, f_norm_trust_region_omp
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double precision :: d1_norm_inverse_trust_region
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double precision :: d2_norm_inverse_trust_region
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double precision :: d1_norm_inverse_trust_region_omp
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double precision :: d2_norm_inverse_trust_region_omp
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print*,''
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print*,'---Trust_newton---'
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call wall_time(t1)
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! version_lambda_search
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! 1 -> ||x||^2 - delta^2 = 0,
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! 2 -> 1/||x||^2 - 1/delta^2 = 0 (better)
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!if (version_lambda_search == 1) then
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! print*, 'Research of the optimal lambda by solving ||x||^2 - delta^2 = 0'
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!else
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! print*, 'Research of the optimal lambda by solving 1/||x||^2 - 1/delta^2 = 0'
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!endif
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! Version 2 is normally better
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! Resolution with the Newton method:
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! Initialization
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epsilon = 1d-4
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lambda = max(0d0, -e_val(1))
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! Pre research of lambda to start near the optimal lambda
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! by adding a constant epsilon and changing the constant to
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! have ||x(lambda + epsilon)|| ~ delta, before setting
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! lambda = lambda + epsilon
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!print*, 'Pre research of lambda:'
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!print*,'Initial lambda =', lambda
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f_N = f_norm_trust_region_omp(n,e_val,tmp_wtg,lambda + epsilon)
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!print*,'||x(lambda)||=', dsqrt(f_N),'delta=',delta
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i = 1
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! To increase lambda
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if (f_N > delta**2) then
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!print*,'Increasing lambda...'
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do while (f_N > delta**2 .and. i <= nb_it_max_pre_search)
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! Update the previous norm
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prev_f_N = f_N
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! New epsilon
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epsilon = epsilon * 2d0
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! New norm
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f_N = f_norm_trust_region_omp(n,e_val,tmp_wtg,lambda + epsilon)
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!print*, 'lambda', lambda + epsilon, '||x||', dsqrt(f_N), 'delta', delta
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! Security
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if (prev_f_N < f_N) then
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print*,'WARNING, error: prev_f_N < f_N, exit'
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epsilon = epsilon * 0.5d0
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i = nb_it_max_pre_search + 1
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endif
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i = i + 1
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enddo
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! To reduce lambda
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else
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!print*,'Reducing lambda...'
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do while (f_N < delta**2 .and. i <= nb_it_max_pre_search)
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! Update the previous norm
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prev_f_N = f_N
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! New epsilon
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epsilon = epsilon * 0.5d0
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! New norm
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f_N = f_norm_trust_region_omp(n,e_val,tmp_wtg,lambda + epsilon)
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!print*, 'lambda', lambda + epsilon, '||x||', dsqrt(f_N), 'delta', delta
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! Security
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if (prev_f_N > f_N) then
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print*,'WARNING, error: prev_f_N > f_N, exit'
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epsilon = epsilon * 2d0
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i = nb_it_max_pre_search + 1
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endif
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i = i + 1
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enddo
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endif
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!print*,'End of the pre research of lambda'
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! New value of lambda
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lambda = lambda + epsilon
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!print*, 'e_val(1):', e_val(1)
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!print*, 'Staring point, lambda =', lambda
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! thresh_cc, threshold for the research of the optimal lambda
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! Leaves the loop when ABS(1d0-||x||^2/delta^2) > thresh_cc
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! thresh_rho_2, threshold to cancel the step in the research
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! of the optimal lambda, the step is cancelled if rho_2 < thresh_rho_2
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!print*,'Threshold for the CC:', thresh_cc
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!print*,'Threshold for rho_2:', thresh_rho_2
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!print*, 'w_1^T . g =', tmp_wtg(1)
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! Debug
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!print*, 'Iteration rho_2 lambda delta ||x|| |1-(||x||^2/delta^2)|'
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! Initialization
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i = 1
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f_N = f_norm_trust_region_omp(n,e_val,tmp_wtg,lambda) ! Value of the ||x(lambda)||^2
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model = 0d0 ! predicted value of (||x||^2 - delta^2)^2
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prev_f_N = 0d0 ! previous value of ||x||^2
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prev_f_R = 0d0 ! previous value of (||x||^2 - delta^2)^2
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f_R = 0d0 ! value of (||x||^2 - delta^2)^2
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rho_2 = 0d0 ! (prev_f_R - f_R)/(prev_f_R - m)
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y = 0d0 ! step size
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prev_lambda = 0d0 ! previous lambda
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! Derivatives
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if (version_lambda_search == 1) then
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d_1 = d1_norm_trust_region_omp(n,e_val,tmp_wtg,lambda,delta) ! first derivative of (||x(lambda)||^2 - delta^2)^2
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d_2 = d2_norm_trust_region_omp(n,e_val,tmp_wtg,lambda,delta) ! second derivative of (||x(lambda)||^2 - delta^2)^2
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else
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d_1 = d1_norm_inverse_trust_region_omp(n,e_val,tmp_wtg,lambda,delta) ! first derivative of (1/||x(lambda)||^2 - 1/delta^2)^2
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d_2 = d2_norm_inverse_trust_region_omp(n,e_val,tmp_wtg,lambda,delta) ! second derivative of (1/||x(lambda)||^2 - 1/delta^2)^2
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endif
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! Trust length
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alpha = DABS((1d0/d_2)*d_1)
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! Newton's method
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do while (i <= 100 .and. DABS(1d0-f_N/delta**2) > thresh_cc)
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!print*,'--------------------------------------'
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!print*,'Research of lambda, iteration:', i
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!print*,'--------------------------------------'
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! Update of f_N, f_R and the derivatives
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prev_f_N = f_N
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if (version_lambda_search == 1) then
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prev_f_R = (prev_f_N - delta**2)**2
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d_1 = d1_norm_trust_region_omp(n,e_val,tmp_wtg,lambda,delta) ! first derivative of (||x(lambda)||^2 - delta^2)^2
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d_2 = d2_norm_trust_region_omp(n,e_val,tmp_wtg,lambda,delta) ! second derivative of (||x(lambda)||^2 - delta^2)^2
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else
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prev_f_R = (1d0/prev_f_N - 1d0/delta**2)**2
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d_1 = d1_norm_inverse_trust_region_omp(n,e_val,tmp_wtg,lambda,delta) ! first derivative of (1/||x(lambda)||^2 - 1/delta^2)^2
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d_2 = d2_norm_inverse_trust_region_omp(n,e_val,tmp_wtg,lambda,delta) ! second derivative of (1/||x(lambda)||^2 - 1/delta^2)^2
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endif
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!write(*,'(a,ES12.5,a,ES12.5)') ' 1st and 2nd derivative: ', d_1,', ', d_2
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! Newton's step
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y = -(1d0/DABS(d_2))*d_1
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! Constraint on y (the newton step)
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if (DABS(y) > alpha) then
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y = alpha * (y/DABS(y)) ! preservation of the sign of y
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endif
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!write(*,'(a,ES12.5)') ' Step length: ', y
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! Predicted value of (||x(lambda)||^2 - delta^2)^2, Taylor series
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model = prev_f_R + d_1 * y + 0.5d0 * d_2 * y**2
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! Updates lambda
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prev_lambda = lambda
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lambda = prev_lambda + y
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!print*,'prev lambda:', prev_lambda
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!print*,'new lambda:', lambda
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! Checks if lambda is in (-h_1, \infty)
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if (lambda > MAX(0d0, -e_val(1))) then
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! New value of ||x(lambda)||^2
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f_N = f_norm_trust_region_omp(n,e_val,tmp_wtg,lambda)
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! New f_R
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if (version_lambda_search == 1) then
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f_R = (f_N - delta**2)**2 ! new value of (||x(lambda)||^2 - delta^2)^2
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else
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f_R = (1d0/f_N - 1d0/delta**2)**2 ! new value of (1/||x(lambda)||^2 -1/delta^2)^2
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endif
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!if (version_lambda_search == 1) then
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! print*,'Previous value of (||x(lambda)||^2 - delta^2)^2:', prev_f_R
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! print*,'Actual value of (||x(lambda)||^2 - delta^2)^2:', f_R
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! print*,'Predicted value of (||x(lambda)||^2 - delta^2)^2:', model
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!else
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! print*,'Previous value of (1/||x(lambda)||^2 - 1/delta^2)^2:', prev_f_R
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! print*,'Actual value of (1/||x(lambda)||^2 - 1/delta^2)^2:', f_R
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! print*,'Predicted value of (1/||x(lambda)||^2 - 1/delta^2)^2:', model
|
|
!endif
|
|
|
|
!print*,'previous - actual:', prev_f_R - f_R
|
|
!print*,'previous - model:', prev_f_R - model
|
|
|
|
! Check the gain
|
|
if (DABS(prev_f_R - model) < thresh_model_2) then
|
|
print*,''
|
|
print*,'WARNING: ABS(previous - model) <', thresh_model_2, 'rho_2 will tend toward infinity'
|
|
print*,''
|
|
endif
|
|
|
|
! Will be deleted
|
|
!if (prev_f_R - f_R <= 1d-16 .or. prev_f_R - model <= 1d-16) then
|
|
! print*,''
|
|
! print*,'WARNING: ABS(previous - model) <= 1d-16, exit'
|
|
! print*,''
|
|
! exit
|
|
!endif
|
|
|
|
! Computes rho_2
|
|
rho_2 = (prev_f_R - f_R)/(prev_f_R - model)
|
|
!print*,'rho_2:', rho_2
|
|
else
|
|
rho_2 = 0d0 ! in order to reduce the size of the trust region, alpha, until lambda is in (-h_1, \infty)
|
|
!print*,'lambda < -e_val(1) ===> rho_2 = 0'
|
|
endif
|
|
|
|
! Evolution of the trust length, alpha
|
|
if (rho_2 >= 0.75d0) then
|
|
alpha = 2d0 * alpha
|
|
elseif (rho_2 >= 0.5d0) then
|
|
alpha = alpha
|
|
elseif (rho_2 >= 0.25d0) then
|
|
alpha = 0.5d0 * alpha
|
|
else
|
|
alpha = 0.25d0 * alpha
|
|
endif
|
|
!write(*,'(a,ES12.5)') ' New trust length alpha: ', alpha
|
|
|
|
! cancellaion of the step if rho < 0.1
|
|
if (rho_2 < thresh_rho_2) then !0.1d0) then
|
|
lambda = prev_lambda
|
|
f_N = prev_f_N
|
|
!print*,'Rho_2 <', thresh_rho_2,', cancellation of the step: lambda = prev_lambda'
|
|
endif
|
|
|
|
!print*,''
|
|
!print*,'lambda, ||x||, delta:'
|
|
!print*, lambda, dsqrt(f_N), delta
|
|
!print*,'CC:', DABS(1d0 - f_N/delta**2)
|
|
!print*,''
|
|
|
|
i = i + 1
|
|
enddo
|
|
|
|
! if trust newton failed
|
|
if (i > nb_it_max_lambda) then
|
|
print*,''
|
|
print*,'######################################################'
|
|
print*,'WARNING: i >', nb_it_max_lambda,'for the trust Newton'
|
|
print*,'The research of the optimal lambda has failed'
|
|
print*,'######################################################'
|
|
print*,''
|
|
endif
|
|
|
|
print*,'Number of iterations:', i
|
|
print*,'Value of lambda:', lambda
|
|
!print*,'Error on the trust region (1d0-f_N/delta**2) (Convergence criterion) :', 1d0-f_N/delta**2
|
|
print*,'Convergence criterion:', 1d0-f_N/delta**2
|
|
!print*,'Error on the trust region (||x||^2 - delta^2)^2):', (f_N - delta**2)**2
|
|
!print*,'Error on the trust region (1/||x||^2 - 1/delta^2)^2)', (1d0/f_N - 1d0/delta**2)**2
|
|
|
|
! Time
|
|
call wall_time(t2)
|
|
t3 = t2 - t1
|
|
print*,'Time in trust_newton:', t3
|
|
|
|
print*,'---End trust_newton---'
|
|
|
|
end subroutine
|
|
|
|
! OMP: First derivative of (||x||^2 - Delta^2)^2
|
|
|
|
! *Function to compute the first derivative of (||x||^2 - Delta^2)^2*
|
|
|
|
! This function computes the first derivative of (||x||^2 - Delta^2)^2
|
|
! with respect to lambda.
|
|
|
|
! \begin{align*}
|
|
! \frac{\partial }{\partial \lambda} (||\textbf{x}(\lambda)||^2 - \Delta^2)^2
|
|
! = -4 \left(\sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3} \right)
|
|
! \left( - \Delta^2 + \sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i+ \lambda)^2} \right)
|
|
! \end{align*}
|
|
|
|
! \begin{align*}
|
|
! \text{accu1} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2} \\
|
|
! \text{accu2} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3}
|
|
! \end{align*}
|
|
|
|
! Provided:
|
|
! | mo_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
! | delta | double precision | Delta of the trust region |
|
|
|
|
! Internal:
|
|
! | accu1 | double precision | first sum of the formula |
|
|
! | accu2 | double precision | second sum of the formula |
|
|
! | tmp_accu1 | double precision | temporary array for the first sum |
|
|
! | tmp_accu2 | double precision | temporary array for the second sum |
|
|
! | tmp_wtg(n) | double precision | temporary array for W^t.v_grad |
|
|
! | i,j | integer | indexes |
|
|
|
|
! Function:
|
|
! | d1_norm_trust_region | double precision | first derivative with respect to lambda of (norm(x)^2 - Delta^2)^2 |
|
|
|
|
|
|
function d1_norm_trust_region_omp(n,e_val,tmp_wtg,lambda,delta)
|
|
|
|
use omp_lib
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute the first derivative with respect to lambda of (||x(lambda)||^2 - Delta^2)^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: tmp_wtg(n)
|
|
double precision, intent(in) :: lambda
|
|
double precision, intent(in) :: delta
|
|
|
|
! Internal
|
|
double precision :: wtg,accu1,accu2
|
|
integer :: i,j
|
|
double precision, allocatable :: tmp_accu1(:), tmp_accu2(:)
|
|
|
|
! Functions
|
|
double precision :: d1_norm_trust_region_omp
|
|
|
|
! Allocation
|
|
allocate(tmp_accu1(n), tmp_accu2(n))
|
|
|
|
! OMP
|
|
call omp_set_max_active_levels(1)
|
|
|
|
! OMP
|
|
!$OMP PARALLEL &
|
|
!$OMP PRIVATE(i,j) &
|
|
!$OMP SHARED(n,lambda, e_val, thresh_eig,&
|
|
!$OMP tmp_accu1, tmp_accu2, tmp_wtg, accu1,accu2) &
|
|
!$OMP DEFAULT(NONE)
|
|
|
|
!$OMP MASTER
|
|
accu1 = 0d0
|
|
accu2 = 0d0
|
|
!$OMP END MASTER
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
tmp_accu1(i) = 0d0
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
tmp_accu2(i) = 0d0
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
if (ABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
tmp_accu1(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**2
|
|
endif
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP MASTER
|
|
do i = 1, n
|
|
accu1 = accu1 + tmp_accu1(i)
|
|
enddo
|
|
!$OMP END MASTER
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
if (ABS(e_val(i)) > thresh_eig) then
|
|
tmp_accu2(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**3
|
|
endif
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP MASTER
|
|
do i = 1, n
|
|
accu2 = accu2 + tmp_accu2(i)
|
|
enddo
|
|
!$OMP END MASTER
|
|
|
|
!$OMP END PARALLEL
|
|
|
|
call omp_set_max_active_levels(4)
|
|
|
|
d1_norm_trust_region_omp = -4d0 * accu2 * (accu1 - delta**2)
|
|
|
|
deallocate(tmp_accu1, tmp_accu2)
|
|
|
|
end function
|
|
|
|
! OMP: Second derivative of (||x||^2 - Delta^2)^2
|
|
|
|
! *Function to compute the second derivative of (||x||^2 - Delta^2)^2*
|
|
|
|
! This function computes the second derivative of (||x||^2 - Delta^2)^2
|
|
! with respect to lambda.
|
|
! \begin{align*}
|
|
! \frac{\partial^2 }{\partial \lambda^2} (||\textbf{x}(\lambda)||^2 - \Delta^2)^2
|
|
! = 2 \left[ \left( \sum_{i=1}^n 6 \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^4} \right) \left( - \Delta^2 + \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \right) + \left( \sum_{i=1}^n -2 \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \right)^2 \right]
|
|
! \end{align*}
|
|
|
|
! \begin{align*}
|
|
! \text{accu1} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \\
|
|
! \text{accu2} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \\
|
|
! \text{accu3} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^4}
|
|
! \end{align*}
|
|
|
|
! Provided:
|
|
! | m_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
! | delta | double precision | Delta of the trust region |
|
|
|
|
! Internal:
|
|
! | accu1 | double precision | first sum of the formula |
|
|
! | accu2 | double precision | second sum of the formula |
|
|
! | accu3 | double precision | third sum of the formula |
|
|
! | tmp_accu1 | double precision | temporary array for the first sum |
|
|
! | tmp_accu2 | double precision | temporary array for the second sum |
|
|
! | tmp_accu2 | double precision | temporary array for the third sum |
|
|
! | tmp_wtg(n) | double precision | temporary array for W^t.v_grad |
|
|
! | i,j | integer | indexes |
|
|
|
|
! Function:
|
|
! | d2_norm_trust_region | double precision | second derivative with respect to lambda of (norm(x)^2 - Delta^2)^2 |
|
|
|
|
|
|
function d2_norm_trust_region_omp(n,e_val,tmp_wtg,lambda,delta)
|
|
|
|
use omp_lib
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute the second derivative with respect to lambda of (||x(lambda)||^2 - Delta^2)^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! Variables
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: tmp_wtg(n)
|
|
double precision, intent(in) :: lambda
|
|
double precision, intent(in) :: delta
|
|
|
|
! Functions
|
|
double precision :: d2_norm_trust_region_omp
|
|
double precision :: ddot
|
|
|
|
! Internal
|
|
double precision :: accu1,accu2,accu3
|
|
double precision, allocatable :: tmp_accu1(:), tmp_accu2(:), tmp_accu3(:)
|
|
integer :: i, j
|
|
|
|
! Allocation
|
|
allocate(tmp_accu1(n), tmp_accu2(n), tmp_accu3(n))
|
|
|
|
call omp_set_max_active_levels(1)
|
|
|
|
! OMP
|
|
!$OMP PARALLEL &
|
|
!$OMP PRIVATE(i,j) &
|
|
!$OMP SHARED(n,lambda, e_val, thresh_eig,&
|
|
!$OMP tmp_accu1, tmp_accu2, tmp_accu3, tmp_wtg, &
|
|
!$OMP accu1, accu2, accu3) &
|
|
!$OMP DEFAULT(NONE)
|
|
|
|
! Initialization
|
|
|
|
!$OMP MASTER
|
|
accu1 = 0d0
|
|
accu2 = 0d0
|
|
accu3 = 0d0
|
|
!$OMP END MASTER
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
tmp_accu1(i) = 0d0
|
|
enddo
|
|
!$OMP END DO
|
|
!$OMP DO
|
|
do i = 1, n
|
|
tmp_accu2(i) = 0d0
|
|
enddo
|
|
!$OMP END DO
|
|
!$OMP DO
|
|
do i = 1, n
|
|
tmp_accu3(i) = 0d0
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
! Calculations
|
|
|
|
! accu1
|
|
!$OMP DO
|
|
do i = 1, n
|
|
if (ABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
tmp_accu1(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**2
|
|
endif
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP MASTER
|
|
do i = 1, n
|
|
accu1 = accu1 + tmp_accu1(i)
|
|
enddo
|
|
!$OMP END MASTER
|
|
|
|
! accu2
|
|
!$OMP DO
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
tmp_accu2(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**3
|
|
endif
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
! accu3
|
|
!$OMP MASTER
|
|
do i = 1, n
|
|
accu2 = accu2 + tmp_accu2(i)
|
|
enddo
|
|
!$OMP END MASTER
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
tmp_accu3(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**4
|
|
endif
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP MASTER
|
|
do i = 1, n
|
|
accu3 = accu3 + tmp_accu3(i)
|
|
enddo
|
|
!$OMP END MASTER
|
|
|
|
!$OMP END PARALLEL
|
|
|
|
d2_norm_trust_region_omp = 2d0 * (6d0 * accu3 * (- delta**2 + accu1) + (-2d0 * accu2)**2)
|
|
|
|
deallocate(tmp_accu1, tmp_accu2, tmp_accu3)
|
|
|
|
end function
|
|
|
|
! OMP: Function value of ||x||^2
|
|
|
|
! *Compute the value of ||x||^2*
|
|
|
|
! This function computes the value of ||x(lambda)||^2
|
|
|
|
! \begin{align*}
|
|
! ||\textbf{x}(\lambda)||^2 = \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2}
|
|
! \end{align*}
|
|
|
|
! Provided:
|
|
! | m_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
|
|
! Internal:
|
|
! | tmp_wtg(n) | double precision | temporary array for W^T.v_grad |
|
|
! | tmp_fN | double precision | temporary array for the function |
|
|
! | i,j | integer | indexes |
|
|
|
|
|
|
function f_norm_trust_region_omp(n,e_val,tmp_wtg,lambda)
|
|
|
|
use omp_lib
|
|
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute ||x(lambda)||^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! Variables
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: tmp_wtg(n)
|
|
double precision, intent(in) :: lambda
|
|
|
|
! functions
|
|
double precision :: f_norm_trust_region_omp
|
|
|
|
! internal
|
|
double precision, allocatable :: tmp_fN(:)
|
|
integer :: i,j
|
|
|
|
! Allocation
|
|
allocate(tmp_fN(n))
|
|
|
|
call omp_set_max_active_levels(1)
|
|
|
|
! OMP
|
|
!$OMP PARALLEL &
|
|
!$OMP PRIVATE(i,j) &
|
|
!$OMP SHARED(n,lambda, e_val, thresh_eig,&
|
|
!$OMP tmp_fN, tmp_wtg, f_norm_trust_region_omp) &
|
|
!$OMP DEFAULT(NONE)
|
|
|
|
! Initialization
|
|
|
|
!$OMP MASTER
|
|
f_norm_trust_region_omp = 0d0
|
|
!$OMP END MASTER
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
tmp_fN(i) = 0d0
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
! Calculations
|
|
!$OMP DO
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
tmp_fN(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**2
|
|
endif
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP MASTER
|
|
do i = 1, n
|
|
f_norm_trust_region_omp = f_norm_trust_region_omp + tmp_fN(i)
|
|
enddo
|
|
!$OMP END MASTER
|
|
|
|
!$OMP END PARALLEL
|
|
|
|
deallocate(tmp_fN)
|
|
|
|
end function
|
|
|
|
! First derivative of (||x||^2 - Delta^2)^2
|
|
! Version without omp
|
|
|
|
! *Function to compute the first derivative of ||x||^2 - Delta*
|
|
|
|
! This function computes the first derivative of (||x||^2 - Delta^2)^2
|
|
! with respect to lambda.
|
|
|
|
! \begin{align*}
|
|
! \frac{\partial }{\partial \lambda} (||\textbf{x}(\lambda)||^2 - \Delta^2)^2
|
|
! = 2 \left(-2\sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \right)
|
|
! \left( - \Delta^2 + \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i+ \lambda)^2} \right)
|
|
! \end{align*}
|
|
|
|
! \begin{align*}
|
|
! \text{accu1} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \\
|
|
! \text{accu2} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3}
|
|
! \end{align*}
|
|
|
|
! Provided:
|
|
! | m_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
! | delta | double precision | Delta of the trust region |
|
|
|
|
! Internal:
|
|
! | accu1 | double precision | first sum of the formula |
|
|
! | accu2 | double precision | second sum of the formula |
|
|
! | wtg | double precision | temporary variable to store W^T.v_grad |
|
|
! | i,j | integer | indexes |
|
|
|
|
! Function:
|
|
! | d1_norm_trust_region | double precision | first derivative with respect to lambda of (norm(x)^2 - Delta^2)^2 |
|
|
! | ddot | double precision | blas dot product |
|
|
|
|
|
|
function d1_norm_trust_region(n,e_val,w,v_grad,lambda,delta)
|
|
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute the first derivative with respect to lambda of (||x(lambda)||^2 - Delta^2)^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! Variables
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: w(n,n)
|
|
double precision, intent(in) :: v_grad(n)
|
|
double precision, intent(in) :: lambda
|
|
double precision, intent(in) :: delta
|
|
|
|
! Internal
|
|
double precision :: wtg, accu1, accu2
|
|
integer :: i, j
|
|
|
|
! Functions
|
|
double precision :: d1_norm_trust_region
|
|
double precision :: ddot
|
|
|
|
! Initialization
|
|
accu1 = 0d0
|
|
accu2 = 0d0
|
|
|
|
do i = 1, n
|
|
wtg = 0d0
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
!wtg = ddot(n,w(:,i),1,v_grad,1)
|
|
accu1 = accu1 + wtg**2 / (e_val(i) + lambda)**2
|
|
endif
|
|
enddo
|
|
|
|
do i = 1, n
|
|
wtg = 0d0
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
!wtg = ddot(n,w(:,i),1,v_grad,1)
|
|
accu2 = accu2 - 2d0 * wtg**2 / (e_val(i) + lambda)**3
|
|
endif
|
|
enddo
|
|
|
|
d1_norm_trust_region = 2d0 * accu2 * (accu1 - delta**2)
|
|
|
|
end function
|
|
|
|
! Second derivative of (||x||^2 - Delta^2)^2
|
|
! Version without OMP
|
|
|
|
! *Function to compute the second derivative of ||x||^2 - Delta*
|
|
|
|
|
|
! \begin{equation}
|
|
! \frac{\partial^2 }{\partial \lambda^2} (||\textbf{x}(\lambda)||^2 - \Delta^2)^2
|
|
! = 2 \left[ \left( \sum_{i=1}^n 6 \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^4} \right) \left( - \Delta^2 + \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \right) + \left( \sum_{i=1}^n -2 \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \right)^2 \right]
|
|
! \end{equation}
|
|
|
|
! \begin{align*}
|
|
! \text{accu1} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \\
|
|
! \text{accu2} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \\
|
|
! \text{accu3} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^4}
|
|
! \end{align*}
|
|
! Provided:
|
|
! | m_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
! | delta | double precision | Delta of the trust region |
|
|
|
|
! Internal:
|
|
! | accu1 | double precision | first sum of the formula |
|
|
! | accu2 | double precision | second sum of the formula |
|
|
! | accu3 | double precision | third sum of the formula |
|
|
! | wtg | double precision | temporary variable to store W^T.v_grad |
|
|
! | i,j | integer | indexes |
|
|
|
|
! Function:
|
|
! | d2_norm_trust_region | double precision | second derivative with respect to lambda of norm(x)^2 - Delta^2 |
|
|
! | ddot | double precision | blas dot product |
|
|
|
|
|
|
function d2_norm_trust_region(n,e_val,w,v_grad,lambda,delta)
|
|
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute the second derivative with respect to lambda of (||x(lambda)||^2 - Delta^2)^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! Variables
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: w(n,n)
|
|
double precision, intent(in) :: v_grad(n)
|
|
double precision, intent(in) :: lambda
|
|
double precision, intent(in) :: delta
|
|
|
|
! Functions
|
|
double precision :: d2_norm_trust_region
|
|
double precision :: ddot
|
|
|
|
! Internal
|
|
double precision :: wtg,accu1,accu2,accu3
|
|
integer :: i, j
|
|
|
|
! Initialization
|
|
accu1 = 0d0
|
|
accu2 = 0d0
|
|
accu3 = 0d0
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
wtg = 0d0
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
!wtg = ddot(n,w(:,i),1,v_grad,1)
|
|
accu1 = accu1 + wtg**2 / (e_val(i) + lambda)**2 !4
|
|
endif
|
|
enddo
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
wtg = 0d0
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
!wtg = ddot(n,w(:,i),1,v_grad,1)
|
|
accu2 = accu2 - 2d0 * wtg**2 / (e_val(i) + lambda)**3 !2
|
|
endif
|
|
enddo
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
wtg = 0d0
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
!wtg = ddot(n,w(:,i),1,v_grad,1)
|
|
accu3 = accu3 + 6d0 * wtg**2 / (e_val(i) + lambda)**4 !3
|
|
endif
|
|
enddo
|
|
|
|
d2_norm_trust_region = 2d0 * (accu3 * (- delta**2 + accu1) + accu2**2)
|
|
|
|
end function
|
|
|
|
! Function value of ||x||^2
|
|
! Version without OMP
|
|
|
|
! *Compute the value of ||x||^2*
|
|
|
|
! This function computes the value of ||x(lambda)||^2
|
|
|
|
! \begin{align*}
|
|
! ||\textbf{x}(\lambda)||^2 = \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2}
|
|
! \end{align*}
|
|
|
|
! Provided:
|
|
! | m_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
! | delta | double precision | Delta of the trust region |
|
|
|
|
! Internal:
|
|
! | wtg | double precision | temporary variable to store W^T.v_grad |
|
|
! | i,j | integer | indexes |
|
|
|
|
! Function:
|
|
! | f_norm_trust_region | double precision | value of norm(x)^2 |
|
|
! | ddot | double precision | blas dot product |
|
|
|
|
|
|
|
|
function f_norm_trust_region(n,e_val,tmp_wtg,lambda)
|
|
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute ||x(lambda)||^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! Variables
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: tmp_wtg(n)
|
|
double precision, intent(in) :: lambda
|
|
|
|
! function
|
|
double precision :: f_norm_trust_region
|
|
double precision :: ddot
|
|
|
|
! internal
|
|
integer :: i,j
|
|
|
|
! Initialization
|
|
f_norm_trust_region = 0d0
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
f_norm_trust_region = f_norm_trust_region + tmp_wtg(i)**2 / (e_val(i) + lambda)**2
|
|
endif
|
|
enddo
|
|
|
|
end function
|
|
|
|
! OMP: First derivative of (1/||x||^2 - 1/Delta^2)^2
|
|
! Version with OMP
|
|
|
|
! *Compute the first derivative of (1/||x||^2 - 1/Delta^2)^2*
|
|
|
|
! This function computes the value of (1/||x(lambda)||^2 - 1/Delta^2)^2
|
|
|
|
! \begin{align*}
|
|
! \frac{\partial}{\partial \lambda} (1/||\textbf{x}(\lambda)||^2 - 1/\Delta^2)^2
|
|
! &= 4 \frac{\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3}}
|
|
! {(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
|
|
! - \frac{4}{\Delta^2} \frac{\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3)}}
|
|
! {(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \\
|
|
! &= 4 \sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3}
|
|
! \left( \frac{1}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
|
|
! - \frac{1}{\Delta^2 (\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \right)
|
|
! \end{align*}
|
|
|
|
! \begin{align*}
|
|
! \text{accu1} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \\
|
|
! \text{accu2} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3}
|
|
! \end{align*}
|
|
|
|
! Provided:
|
|
! | m_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
! | delta | double precision | Delta of the trust region |
|
|
|
|
! Internal:
|
|
! | wtg | double precision | temporary variable to store W^T.v_grad |
|
|
! | tmp_accu1 | double precision | temporary array for the first sum |
|
|
! | tmp_accu2 | double precision | temporary array for the second sum |
|
|
! | tmp_wtg(n) | double precision | temporary array for W^t.v_grad |
|
|
! | i,j | integer | indexes |
|
|
|
|
! Function:
|
|
! | d1_norm_inverse_trust_region | double precision | value of the first derivative |
|
|
|
|
|
|
function d1_norm_inverse_trust_region_omp(n,e_val,tmp_wtg,lambda,delta)
|
|
|
|
use omp_lib
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute the first derivative of (1/||x||^2 - 1/Delta^2)^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! Variables
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: tmp_wtg(n)
|
|
double precision, intent(in) :: lambda
|
|
double precision, intent(in) :: delta
|
|
|
|
! Internal
|
|
double precision :: accu1, accu2
|
|
integer :: i,j
|
|
double precision, allocatable :: tmp_accu1(:), tmp_accu2(:)
|
|
|
|
! Functions
|
|
double precision :: d1_norm_inverse_trust_region_omp
|
|
|
|
! Allocation
|
|
allocate(tmp_accu1(n), tmp_accu2(n))
|
|
|
|
! OMP
|
|
call omp_set_max_active_levels(1)
|
|
|
|
! OMP
|
|
!$OMP PARALLEL &
|
|
!$OMP PRIVATE(i,j) &
|
|
!$OMP SHARED(n,lambda, e_val, thresh_eig,&
|
|
!$OMP tmp_accu1, tmp_accu2, tmp_wtg, accu1, accu2) &
|
|
!$OMP DEFAULT(NONE)
|
|
|
|
!$OMP MASTER
|
|
accu1 = 0d0
|
|
accu2 = 0d0
|
|
!$OMP END MASTER
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
tmp_accu1(i) = 0d0
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
tmp_accu2(i) = 0d0
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
! !$OMP MASTER
|
|
! do i = 1, n
|
|
! if (ABS(e_val(i)+lambda) > 1d-12) then
|
|
! tmp_accu1(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**2
|
|
! endif
|
|
! enddo
|
|
! !$OMP END MASTER
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
tmp_accu1(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**2
|
|
endif
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP MASTER
|
|
do i = 1, n
|
|
accu1 = accu1 + tmp_accu1(i)
|
|
enddo
|
|
!$OMP END MASTER
|
|
|
|
! !$OMP MASTER
|
|
! do i = 1, n
|
|
! if (ABS(e_val(i)+lambda) > 1d-12) then
|
|
! tmp_accu2(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**3
|
|
! endif
|
|
! enddo
|
|
! !$OMP END MASTER
|
|
|
|
!$OMP DO
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
tmp_accu2(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**3
|
|
endif
|
|
enddo
|
|
!$OMP END DO
|
|
|
|
!$OMP MASTER
|
|
do i = 1, n
|
|
accu2 = accu2 + tmp_accu2(i)
|
|
enddo
|
|
!$OMP END MASTER
|
|
|
|
!$OMP END PARALLEL
|
|
|
|
call omp_set_max_active_levels(4)
|
|
|
|
d1_norm_inverse_trust_region_omp = 4d0 * accu2 * (1d0/accu1**3 - 1d0/(delta**2 * accu1**2))
|
|
|
|
deallocate(tmp_accu1, tmp_accu2)
|
|
|
|
end
|
|
|
|
! OMP: Second derivative of (1/||x||^2 - 1/Delta^2)^2
|
|
! Version with OMP
|
|
|
|
! *Compute the first derivative of (1/||x||^2 - 1/Delta^2)^2*
|
|
|
|
! This function computes the value of (1/||x(lambda)||^2 - 1/Delta^2)^2
|
|
|
|
! \begin{align*}
|
|
! \frac{\partial^2}{\partial \lambda^2} (1/||\textbf{x}(\lambda)||^2 - 1/\Delta^2)^2
|
|
! &= 4 \left[ \frac{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3)})^2}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^4}
|
|
! - 3 \frac{\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^4}}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3} \right] \\
|
|
! &- \frac{4}{\Delta^2} \left[ \frac{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3)})^2}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
|
|
! - 3 \frac{\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^4}}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \right]
|
|
! \end{align*}
|
|
|
|
|
|
! \begin{align*}
|
|
! \text{accu1} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \\
|
|
! \text{accu2} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \\
|
|
! \text{accu3} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^4}
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! \end{align*}
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! Provided:
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! | m_num | integer | number of MOs |
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|
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! Input:
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! | n | integer | mo_num*(mo_num-1)/2 |
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! | e_val(n) | double precision | eigenvalues of the hessian |
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! | W(n,n) | double precision | eigenvectors of the hessian |
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! | v_grad(n) | double precision | gradient |
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! | lambda | double precision | Lagrange multiplier |
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! | delta | double precision | Delta of the trust region |
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|
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! Internal:
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! | wtg | double precision | temporary variable to store W^T.v_grad |
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! | tmp_accu1 | double precision | temporary array for the first sum |
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! | tmp_accu2 | double precision | temporary array for the second sum |
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! | tmp_wtg(n) | double precision | temporary array for W^t.v_grad |
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! | i,j | integer | indexes |
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! Function:
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! | d1_norm_inverse_trust_region | double precision | value of the first derivative |
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function d2_norm_inverse_trust_region_omp(n,e_val,tmp_wtg,lambda,delta)
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use omp_lib
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include 'pi.h'
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!BEGIN_DOC
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! Compute the second derivative of (1/||x||^2 - 1/Delta^2)^2
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!END_DOC
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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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double precision, intent(in) :: e_val(n)
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double precision, intent(in) :: tmp_wtg(n)
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double precision, intent(in) :: lambda
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double precision, intent(in) :: delta
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! Internal
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double precision :: accu1, accu2, accu3
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integer :: i,j
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double precision, allocatable :: tmp_accu1(:), tmp_accu2(:), tmp_accu3(:)
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! Functions
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double precision :: d2_norm_inverse_trust_region_omp
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! Allocation
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allocate(tmp_accu1(n), tmp_accu2(n), tmp_accu3(n))
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! OMP
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call omp_set_max_active_levels(1)
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! OMP
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!$OMP PARALLEL &
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!$OMP PRIVATE(i,j) &
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!$OMP SHARED(n,lambda, e_val, thresh_eig,&
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!$OMP tmp_accu1, tmp_accu2, tmp_accu3, tmp_wtg, &
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!$OMP accu1, accu2, accu3) &
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!$OMP DEFAULT(NONE)
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!$OMP MASTER
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accu1 = 0d0
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accu2 = 0d0
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accu3 = 0d0
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!$OMP END MASTER
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!$OMP DO
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do i = 1, n
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tmp_accu1(i) = 0d0
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enddo
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!$OMP END DO
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!$OMP DO
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do i = 1, n
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tmp_accu2(i) = 0d0
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enddo
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!$OMP END DO
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!$OMP DO
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do i = 1, n
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tmp_accu3(i) = 0d0
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enddo
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!$OMP END DO
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!$OMP DO
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do i = 1, n
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if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
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tmp_accu1(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**2
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endif
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enddo
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!$OMP END DO
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!$OMP MASTER
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do i = 1, n
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accu1 = accu1 + tmp_accu1(i)
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enddo
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!$OMP END MASTER
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!$OMP DO
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do i = 1, n
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if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
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tmp_accu2(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**3
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endif
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enddo
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!$OMP END DO
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!$OMP MASTER
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do i = 1, n
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accu2 = accu2 + tmp_accu2(i)
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enddo
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!$OMP END MASTER
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!$OMP DO
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do i = 1, n
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if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
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tmp_accu3(i) = tmp_wtg(i)**2 / (e_val(i) + lambda)**4
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endif
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enddo
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!$OMP END DO
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!$OMP MASTER
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do i = 1, n
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accu3 = accu3 + tmp_accu3(i)
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|
enddo
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!$OMP END MASTER
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!$OMP END PARALLEL
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call omp_set_max_active_levels(4)
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d2_norm_inverse_trust_region_omp = 4d0 * (6d0 * accu2**2/accu1**4 - 3d0 * accu3/accu1**3) &
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|
- 4d0/delta**2 * (4d0 * accu2**2/accu1**3 - 3d0 * accu3/accu1**2)
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deallocate(tmp_accu1,tmp_accu2,tmp_accu3)
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|
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end
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! First derivative of (1/||x||^2 - 1/Delta^2)^2
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|
! Version without OMP
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|
|
|
! *Compute the first derivative of (1/||x||^2 - 1/Delta^2)^2*
|
|
|
|
! This function computes the value of (1/||x(lambda)||^2 - 1/Delta^2)^2
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|
|
|
! \begin{align*}
|
|
! \frac{\partial}{\partial \lambda} (1/||\textbf{x}(\lambda)||^2 - 1/\Delta^2)^2
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|
! &= 4 \frac{\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3}}
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! {(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
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! - \frac{4}{\Delta^2} \frac{\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3)}}
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! {(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \\
|
|
! &= 4 \sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3}
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! \left( \frac{1}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
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! - \frac{1}{\Delta^2 (\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \right)
|
|
! \end{align*}
|
|
! \begin{align*}
|
|
! \text{accu1} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \\
|
|
! \text{accu2} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3}
|
|
! \end{align*}
|
|
! Provided:
|
|
! | m_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
! | delta | double precision | Delta of the trust region |
|
|
|
|
! Internal:
|
|
! | wtg | double precision | temporary variable to store W^T.v_grad |
|
|
! | i,j | integer | indexes |
|
|
|
|
! Function:
|
|
! | d1_norm_inverse_trust_region | double precision | value of the first derivative |
|
|
|
|
|
|
function d1_norm_inverse_trust_region(n,e_val,w,v_grad,lambda,delta)
|
|
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute the first derivative of (1/||x||^2 - 1/Delta^2)^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! Variables
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: w(n,n)
|
|
double precision, intent(in) :: v_grad(n)
|
|
double precision, intent(in) :: lambda
|
|
double precision, intent(in) :: delta
|
|
|
|
! Internal
|
|
double precision :: wtg, accu1, accu2
|
|
integer :: i,j
|
|
|
|
! Functions
|
|
double precision :: d1_norm_inverse_trust_region
|
|
|
|
accu1 = 0d0
|
|
accu2 = 0d0
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
wtg = 0d0
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
accu1 = accu1 + wtg**2 / (e_val(i) + lambda)**2
|
|
endif
|
|
enddo
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
wtg = 0d0
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
accu2 = accu2 + wtg**2 / (e_val(i) + lambda)**3
|
|
endif
|
|
enddo
|
|
|
|
d1_norm_inverse_trust_region = 4d0 * accu2 * (1d0/accu1**3 - 1d0/(delta**2 * accu1**2))
|
|
|
|
end
|
|
|
|
! Second derivative of (1/||x||^2 - 1/Delta^2)^2
|
|
! Version without OMP
|
|
|
|
! *Compute the second derivative of (1/||x||^2 - 1/Delta^2)^2*
|
|
|
|
! This function computes the value of (1/||x(lambda)||^2 - 1/Delta^2)^2
|
|
|
|
! \begin{align*}
|
|
! \frac{\partial^2}{\partial \lambda^2} (1/||\textbf{x}(\lambda)||^2 - 1/\Delta^2)^2
|
|
! &= 4 \left[ \frac{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3)})^2}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^4}
|
|
! - 3 \frac{\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^4}}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3} \right] \\
|
|
! &- \frac{4}{\Delta^2} \left[ \frac{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^3)})^2}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^3}
|
|
! - 3 \frac{\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^4}}{(\sum_i \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2})^2} \right]
|
|
! \end{align*}
|
|
|
|
! \begin{align*}
|
|
! \text{accu1} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^2} \\
|
|
! \text{accu2} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^3} \\
|
|
! \text{accu3} &= \sum_{i=1}^n \frac{(\textbf{w}_i^T \textbf{g})^2}{(h_i + \lambda)^4}
|
|
! \end{align*}
|
|
|
|
! Provided:
|
|
! | m_num | integer | number of MOs |
|
|
|
|
! Input:
|
|
! | n | integer | mo_num*(mo_num-1)/2 |
|
|
! | e_val(n) | double precision | eigenvalues of the hessian |
|
|
! | W(n,n) | double precision | eigenvectors of the hessian |
|
|
! | v_grad(n) | double precision | gradient |
|
|
! | lambda | double precision | Lagrange multiplier |
|
|
! | delta | double precision | Delta of the trust region |
|
|
|
|
! Internal:
|
|
! | wtg | double precision | temporary variable to store W^T.v_grad |
|
|
! | i,j | integer | indexes |
|
|
|
|
! Function:
|
|
! | d2_norm_inverse_trust_region | double precision | value of the first derivative |
|
|
|
|
|
|
function d2_norm_inverse_trust_region(n,e_val,w,v_grad,lambda,delta)
|
|
|
|
include 'pi.h'
|
|
|
|
!BEGIN_DOC
|
|
! Compute the second derivative of (1/||x||^2 - 1/Delta^2)^2
|
|
!END_DOC
|
|
|
|
implicit none
|
|
|
|
! Variables
|
|
|
|
! in
|
|
integer, intent(in) :: n
|
|
double precision, intent(in) :: e_val(n)
|
|
double precision, intent(in) :: w(n,n)
|
|
double precision, intent(in) :: v_grad(n)
|
|
double precision, intent(in) :: lambda
|
|
double precision, intent(in) :: delta
|
|
|
|
! Internal
|
|
double precision :: wtg, accu1, accu2, accu3
|
|
integer :: i,j
|
|
|
|
! Functions
|
|
double precision :: d2_norm_inverse_trust_region
|
|
|
|
accu1 = 0d0
|
|
accu2 = 0d0
|
|
accu3 = 0d0
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
wtg = 0d0
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
accu1 = accu1 + wtg**2 / (e_val(i) + lambda)**2
|
|
endif
|
|
enddo
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
wtg = 0d0
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
accu2 = accu2 + wtg**2 / (e_val(i) + lambda)**3
|
|
endif
|
|
enddo
|
|
|
|
do i = 1, n
|
|
if (DABS(e_val(i)) > thresh_eig .and. DABS(e_val(i)+lambda) > thresh_eig) then
|
|
wtg = 0d0
|
|
do j = 1, n
|
|
wtg = wtg + w(j,i) * v_grad(j)
|
|
enddo
|
|
accu3 = accu3 + wtg**2 / (e_val(i) + lambda)**4
|
|
endif
|
|
enddo
|
|
|
|
d2_norm_inverse_trust_region = 4d0 * (6d0 * accu2**2/accu1**4 - 3d0 * accu3/accu1**3) &
|
|
- 4d0/delta**2 * (4d0 * accu2**2/accu1**3 - 3d0 * accu3/accu1**2)
|
|
|
|
end
|