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750 lines
25 KiB
Fortran
750 lines
25 KiB
Fortran
! Trust region
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! *Compute the next step with the trust region algorithm*
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! The Newton method is an iterative method to find a minimum of a given
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! function. It uses a Taylor series truncated at the second order of the
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! targeted function and gives its minimizer. The minimizer is taken as
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! the new position and the same thing is done. And by doing so
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! iteratively the method find a minimum, a local or global one depending
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! of the starting point and the convexity/nonconvexity of the targeted
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! function.
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! The goal of the trust region is to constrain the step size of the
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! Newton method in a certain area around the actual position, where the
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! Taylor series is a good approximation of the targeted function. This
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! area is called the "trust region".
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! In addition, in function of the agreement between the Taylor
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! development of the energy and the real energy, the size of the trust
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! region will be updated at each iteration. By doing so, the step sizes
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! are not too larges. In addition, since we add a criterion to cancel the
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! step if the energy increases (more precisely if rho < 0.1), so it's
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! impossible to diverge. \newline
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! References: \newline
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! Nocedal & Wright, Numerical Optimization, chapter 4 (1999), \newline
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! https://link.springer.com/book/10.1007/978-0-387-40065-5, \newline
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! ISBN: 978-0-387-40065-5 \newline
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! By using the first and the second derivatives, the Newton method gives
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! a step:
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! \begin{align*}
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! \textbf{x}_{(k+1)}^{\text{Newton}} = - \textbf{H}_{(k)}^{-1} \cdot
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! \textbf{g}_{(k)}
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! \end{align*}
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! which leads to the minimizer of the Taylor series.
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! !!! Warning: the Newton method gives the minimizer if and only if
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! $\textbf{H}$ is positive definite, else it leads to a saddle point !!!
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! But we want a step $\textbf{x}_{(k+1)}$ with a constraint on its (euclidian) norm:
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! \begin{align*}
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! ||\textbf{x}_{(k+1)}|| \leq \Delta_{(k+1)}
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! \end{align*}
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! which is equivalent to
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! \begin{align*}
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! \textbf{x}_{(k+1)}^T \cdot \textbf{x}_{(k+1)} \leq \Delta_{(k+1)}^2
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! \end{align*}
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! with: \newline
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! $\textbf{x}_{(k+1)}$ is the step for the k+1-th iteration (vector of
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! size n) \newline
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! $\textbf{H}_{(k)}$ is the hessian at the k-th iteration (n by n
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! matrix) \newline
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! $\textbf{g}_{(k)}$ is the gradient at the k-th iteration (vector of
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! size n) \newline
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! $\Delta_{(k+1)}$ is the trust radius for the (k+1)-th iteration
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! \newline
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! Thus we want to constrain the step size $\textbf{x}_{(k+1)}$ into a
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! hypersphere of radius $\Delta_{(k+1)}$.\newline
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! So, if $||\textbf{x}_{(k+1)}^{\text{Newton}}|| \leq \Delta_{(k)}$ and
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! $\textbf{H}$ is positive definite, the
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! solution is the step given by the Newton method
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! $\textbf{x}_{(k+1)} = \textbf{x}_{(k+1)}^{\text{Newton}}$.
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! Else we have to constrain the step size. For simplicity we will remove
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! the index $_{(k)}$ and $_{(k+1)}$. To restict the step size, we have
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! to put a constraint on $\textbf{x}$ with a Lagrange multiplier.
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! Starting from the Taylor series of a function E (here, the energy)
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! truncated at the 2nd order, we have:
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! \begin{align*}
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! E(\textbf{x}) = E +\textbf{g}^T \cdot \textbf{x} + \frac{1}{2}
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! \cdot \textbf{x}^T \cdot \textbf{H} \cdot \textbf{x} +
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! \mathcal{O}(\textbf{x}^2)
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! \end{align*}
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! With the constraint on the norm of $\textbf{x}$ we can write the
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! Lagrangian
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! \begin{align*}
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! \mathcal{L}(\textbf{x},\lambda) = E + \textbf{g}^T \cdot \textbf{x}
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! + \frac{1}{2} \cdot \textbf{x}^T \cdot \textbf{H} \cdot \textbf{x}
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! + \frac{1}{2} \lambda (\textbf{x}^T \cdot \textbf{x} - \Delta^2)
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! \end{align*}
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! Where: \newline
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! $\lambda$ is the Lagrange multiplier \newline
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! $E$ is the energy at the k-th iteration $\Leftrightarrow
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! E(\textbf{x} = \textbf{0})$ \newline
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! To solve this equation, we search a stationary point where the first
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! derivative of $\mathcal{L}$ with respect to $\textbf{x}$ becomes 0, i.e.
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! \begin{align*}
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! \frac{\partial \mathcal{L}(\textbf{x},\lambda)}{\partial \textbf{x}}=0
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! \end{align*}
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! The derivative is:
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! \begin{align*}
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! \frac{\partial \mathcal{L}(\textbf{x},\lambda)}{\partial \textbf{x}}
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! = \textbf{g} + \textbf{H} \cdot \textbf{x} + \lambda \cdot \textbf{x}
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! \end{align*}
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! So, we search $\textbf{x}$ such as:
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! \begin{align*}
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! \frac{\partial \mathcal{L}(\textbf{x},\lambda)}{\partial \textbf{x}}
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! = \textbf{g} + \textbf{H} \cdot \textbf{x} + \lambda \cdot \textbf{x} = 0
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! \end{align*}
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! We can rewrite that as:
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! \begin{align*}
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! \textbf{g} + \textbf{H} \cdot \textbf{x} + \lambda \cdot \textbf{x}
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! = \textbf{g} + (\textbf{H} +\textbf{I} \lambda) \cdot \textbf{x} = 0
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! \end{align*}
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! with $\textbf{I}$ is the identity matrix.
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! By doing so, the solution is:
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! \begin{align*}
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! (\textbf{H} +\textbf{I} \lambda) \cdot \textbf{x}= -\textbf{g}
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! \end{align*}
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! \begin{align*}
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! \textbf{x}= - (\textbf{H} + \textbf{I} \lambda)^{-1} \cdot \textbf{g}
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! \end{align*}
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! with $\textbf{x}^T \textbf{x} = \Delta^2$.
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! We have to solve this previous equation to find this $\textbf{x}$ in the
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! trust region, i.e. $||\textbf{x}|| = \Delta$. Now, this problem is
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! just a one dimension problem because we can express $\textbf{x}$ as a
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! function of $\lambda$:
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! \begin{align*}
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! \textbf{x}(\lambda) = - (\textbf{H} + \textbf{I} \lambda)^{-1} \cdot \textbf{g}
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! \end{align*}
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! We start from the fact that the hessian is diagonalizable. So we have:
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! \begin{align*}
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! \textbf{H} = \textbf{W} \cdot \textbf{h} \cdot \textbf{W}^T
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! \end{align*}
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! with: \newline
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! $\textbf{H}$, the hessian matrix \newline
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! $\textbf{W}$, the matrix containing the eigenvectors \newline
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! $\textbf{w}_i$, the i-th eigenvector, i.e. i-th column of $\textbf{W}$ \newline
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! $\textbf{h}$, the matrix containing the eigenvalues in ascending order \newline
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! $h_i$, the i-th eigenvalue in ascending order \newline
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! Now we use the fact that adding a constant on the diagonal just shifts
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! the eigenvalues:
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! \begin{align*}
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! \textbf{H} + \textbf{I} \lambda = \textbf{W} \cdot (\textbf{h}
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! +\textbf{I} \lambda) \cdot \textbf{W}^T
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! \end{align*}
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! By doing so we can express $\textbf{x}$ as a function of $\lambda$
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! \begin{align*}
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! \textbf{x}(\lambda) = - \sum_{i=1}^n \frac{\textbf{w}_i^T \cdot
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! \textbf{g}}{h_i + \lambda} \cdot \textbf{w}_i
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! \end{align*}
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! with $\lambda \neq - h_i$.
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! An interesting thing in our case is the norm of $\textbf{x}$,
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! because we want $||\textbf{x}|| = \Delta$. Due to the orthogonality of
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! the eigenvectors $\left\{\textbf{w} \right\} _{i=1}^n$ we have:
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! \begin{align*}
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! ||\textbf{x}(\lambda)||^2 = \sum_{i=1}^n \frac{(\textbf{w}_i^T \cdot
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! \textbf{g})^2}{(h_i + \lambda)^2}
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! \end{align*}
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! So the $||\textbf{x}(\lambda)||^2$ is just a function of $\lambda$.
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! And if we study the properties of this function we see that:
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! \begin{align*}
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! \lim_{\lambda\to\infty} ||\textbf{x}(\lambda)|| = 0
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! \end{align*}
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! and if $\textbf{w}_i^T \cdot \textbf{g} \neq 0$:
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! \begin{align*}
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! \lim_{\lambda\to -h_i} ||\textbf{x}(\lambda)|| = + \infty
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! \end{align*}
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! From these limits and knowing that $h_1$ is the lowest eigenvalue, we
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! can conclude that $||\textbf{x}(\lambda)||$ is a continuous and
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! strictly decreasing function on the interval $\lambda \in
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! (-h_1;\infty)$. Thus, there is one $\lambda$ in this interval which
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! gives $||\textbf{x}(\lambda)|| = \Delta$, consequently there is one
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! solution.
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! Since $\textbf{x} = - (\textbf{H} + \lambda \textbf{I})^{-1} \cdot
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! \textbf{g}$ and we want to reduce the norm of $\textbf{x}$, clearly,
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! $\lambda > 0$ ($\lambda = 0$ is the unconstraint solution). But the
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! Newton method is only defined for a positive definite hessian matrix,
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! so $(\textbf{H} + \textbf{I} \lambda)$ must be positive
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! definite. Consequently, in the case where $\textbf{H}$ is not positive
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! definite, to ensure the positive definiteness, $\lambda$ must be
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! greater than $- h_1$.
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! \begin{align*}
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! \lambda > 0 \quad \text{and} \quad \lambda \geq - h_1
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! \end{align*}
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! From that there are five cases:
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! - if $\textbf{H}$ is positive definite, $-h_1 < 0$, $\lambda \in (0,\infty)$
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! - if $\textbf{H}$ is not positive definite and $\textbf{w}_1^T \cdot
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! \textbf{g} \neq 0$, $(\textbf{H} + \textbf{I}
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! \lambda)$
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! must be positve definite, $-h_1 > 0$, $\lambda \in (-h_1, \infty)$
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! - if $\textbf{H}$ is not positive definite , $\textbf{w}_1^T \cdot
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! \textbf{g} = 0$ and $||\textbf{x}(-h_1)|| > \Delta$ by removing
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! $j=1$ in the sum, $(\textbf{H} + \textbf{I} \lambda)$ must be
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! positive definite, $-h_1 > 0$, $\lambda \in (-h_1, \infty$)
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! - if $\textbf{H}$ is not positive definite , $\textbf{w}_1^T \cdot
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! \textbf{g} = 0$ and $||\textbf{x}(-h_1)|| \leq \Delta$ by removing
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! $j=1$ in the sum, $(\textbf{H} + \textbf{I} \lambda)$ must be
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! positive definite, $-h_1 > 0$, $\lambda = -h_1$). This case is
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! similar to the case where $\textbf{H}$ and $||\textbf{x}(\lambda =
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! 0)|| \leq \Delta$
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! but we can also add to $\textbf{x}$, the first eigenvector $\textbf{W}_1$
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! time a constant to ensure the condition $||\textbf{x}(\lambda =
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! -h_1)|| = \Delta$ and escape from the saddle point
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! Thus to find the solution, we can write:
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! \begin{align*}
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! ||\textbf{x}(\lambda)|| = \Delta
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! \end{align*}
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! \begin{align*}
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! ||\textbf{x}(\lambda)|| - \Delta = 0
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! \end{align*}
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! Taking the square of this equation
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! \begin{align*}
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! (||\textbf{x}(\lambda)|| - \Delta)^2 = 0
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! \end{align*}
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! we have a function with one minimum for the optimal $\lambda$.
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! Since we have the formula of $||\textbf{x}(\lambda)||^2$, we solve
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! \begin{align*}
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! (||\textbf{x}(\lambda)||^2 - \Delta^2)^2 = 0
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! \end{align*}
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! But in practice, it is more effective to solve:
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! \begin{align*}
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! (\frac{1}{||\textbf{x}(\lambda)||^2} - \frac{1}{\Delta^2})^2 = 0
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! \end{align*}
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! To do that, we just use the Newton method with "trust_newton" using
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! first and second derivative of $(||\textbf{x}(\lambda)||^2 -
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! \Delta^2)^2$ with respect to $\textbf{x}$.
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! This will give the optimal $\lambda$ to compute the
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! solution $\textbf{x}$ with the formula seen previously:
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! \begin{align*}
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! \textbf{x}(\lambda) = - \sum_{i=1}^n \frac{\textbf{w}_i^T \cdot
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! \textbf{g}}{h_i + \lambda} \cdot \textbf{w}_i
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! \end{align*}
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! The solution $\textbf{x}(\lambda)$ with the optimal $\lambda$ is our
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! step to go from the (k)-th to the (k+1)-th iteration, is noted $\textbf{x}^*$.
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! Evolution of the trust region
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! We initialize the trust region at the first iteration using a radius
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! \begin{align*}
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! \Delta = ||\textbf{x}(\lambda=0)||
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! \end{align*}
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! And for the next iteration the trust region will evolves depending of
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! the agreement of the energy prediction based on the Taylor series
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! truncated at the 2nd order and the real energy. If the Taylor series
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! truncated at the 2nd order represents correctly the energy landscape
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! the trust region will be extent else it will be reduced. In order to
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! mesure this agreement we use the ratio rho cf. "rho_model" and
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! "trust_e_model". From that we use the following values:
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! - if $\rho \geq 0.75$, then $\Delta = 2 \Delta$,
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! - if $0.5 \geq \rho < 0.75$, then $\Delta = \Delta$,
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! - if $0.25 \geq \rho < 0.5$, then $\Delta = 0.5 \Delta$,
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! - if $\rho < 0.25$, then $\Delta = 0.25 \Delta$.
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! In addition, if $\rho < 0.1$ the iteration is cancelled, so it
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! restarts with a smaller trust region until the energy decreases.
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! Summary
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! To summarize, knowing the hessian (eigenvectors and eigenvalues), the
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! gradient and the radius of the trust region we can compute the norm of
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! the Newton step
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! \begin{align*}
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! ||\textbf{x}(\lambda = 0)||^2 = ||- \textbf{H}^{-1} \cdot \textbf{g}||^2 = \sum_{i=1}^n
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! \frac{(\textbf{w}_i^T \cdot \textbf{g})^2}{(h_i + \lambda)^2}, \quad h_i \neq 0
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! \end{align*}
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! - if $h_1 \geq 0$, $||\textbf{x}(\lambda = 0)|| \leq \Delta$ and
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! $\textbf{x}(\lambda=0)$ is in the trust region and it is not
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! necessary to put a constraint on $\textbf{x}$, the solution is the
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! unconstrained one, $\textbf{x}^* = \textbf{x}(\lambda = 0)$.
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! - else if $h_1 < 0$, $\textbf{w}_1^T \cdot \textbf{g} = 0$ and
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! $||\textbf{x}(\lambda = -h_1)|| \leq \Delta$ (by removing $j=1$ in
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! the sum), the solution is $\textbf{x}^* = \textbf{x}(\lambda =
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! -h_1)$, similarly to the previous case.
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! But we can add to $\textbf{x}$, the first eigenvector $\textbf{W}_1$
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! time a constant to ensure the condition $||\textbf{x}(\lambda =
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! -h_1)|| = \Delta$ and escape from the saddle point
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! - else if $h_1 < 0$ and $\textbf{w}_1^T \cdot \textbf{g} \neq 0$ we
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! have to search $\lambda \in (-h_1, \infty)$ such as
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! $\textbf{x}(\lambda) = \Delta$ by solving with the Newton method
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! \begin{align*}
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! (||\textbf{x}(\lambda)||^2 - \Delta^2)^2 = 0
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! \end{align*}
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! or
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! \begin{align*}
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! (\frac{1}{||\textbf{x}(\lambda)||^2} - \frac{1}{\Delta^2})^2 = 0
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! \end{align*}
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! which is numerically more stable. And finally compute
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! \begin{align*}
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! \textbf{x}^* = \textbf{x}(\lambda) = - \sum_{i=1}^n \frac{\textbf{w}_i^T \cdot
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! \textbf{g}}{h_i + \lambda} \cdot \textbf{w}_i
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! \end{align*}
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! - else if $h_1 \geq 0$ and $||\textbf{x}(\lambda = 0)|| > \Delta$ we
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! do exactly the same thing that the previous case but we search
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! $\lambda \in (0, \infty)$
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! - else if $h_1 < 0$ and $\textbf{w}_1^T \cdot \textbf{g} = 0$ and
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! $||\textbf{x}(\lambda = -h_1)|| > \Delta$ (by removing $j=1$ in the
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! sum), again we do exactly the same thing that the previous case
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! searching $\lambda \in (-h_1, \infty)$.
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! For the cases where $\textbf{w}_1^T \cdot \textbf{g} = 0$ it is not
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! necessary in fact to remove the $j = 1$ in the sum since the term
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! where $h_i - \lambda < 10^{-6}$ are not computed.
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! After that, we take this vector $\textbf{x}^*$, called "x", and we do
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! the transformation to an antisymmetric matrix $\textbf{X}$, called
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! m_x. This matrix $\textbf{X}$ will be used to compute a rotation
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! matrix $\textbf{R}= \exp(\textbf{X})$ in "rotation_matrix".
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! NB:
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! An improvement can be done using a elleptical trust region.
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! Code
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! Provided:
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! | mo_num | integer | number of MOs |
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! Cf. qp_edit in orbital optimization section, for some constants/thresholds
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! Input:
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! | m | integer | number of MOs |
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! | n | integer | m*(m-1)/2 |
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! | n2 | integer | m*(m-1)/2 or 1 if the hessian is diagonal |
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! | H(n,n2) | double precision | hessian |
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! | v_grad(n) | double precision | gradient |
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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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! | rho | double precision | agreement between the model and the reality, |
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! | | | represents the quality of the energy prediction |
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! | nb_iter | integer | number of iteration |
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! Input/Ouput:
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! | delta | double precision | radius of the trust region |
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! Output:
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! | x(n) | double precision | vector containing the step |
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! Internal:
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! | accu | double precision | temporary variable to compute the step |
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! | lambda | double precision | lagrange multiplier |
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! | trust_radius2 | double precision | square of the radius of the trust region |
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! | norm2_x | double precision | norm^2 of the vector x |
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! | norm2_g | double precision | norm^2 of the vector containing the gradient |
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! | tmp_wtg(n) | double precision | tmp_wtg(i) = w_i^T . g |
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! | i, j, k | integer | indexes |
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! Function:
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! | dnrm2 | double precision | Blas function computing the norm |
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! | f_norm_trust_region_omp | double precision | compute the value of norm(x(lambda)^2) |
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subroutine trust_region_step(n,n2,nb_iter,v_grad,rho,e_val,w,x,delta)
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include 'pi.h'
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!BEGIN_DOC
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! Compuet the step 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,n2
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double precision, intent(in) :: v_grad(n), rho
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integer, intent(inout) :: nb_iter
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double precision, intent(in) :: e_val(n), w(n,n2)
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! inout
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double precision, intent(inout) :: delta
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! out
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double precision, intent(out) :: x(n)
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! Internal
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double precision :: accu, lambda, trust_radius2
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double precision :: norm2_x, norm2_g
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double precision, allocatable :: tmp_wtg(:)
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integer :: i,j,k
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double precision :: t1,t2,t3
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integer :: n_neg_eval
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! Functions
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double precision :: ddot, dnrm2
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double precision :: f_norm_trust_region_omp
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print*,''
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print*,'=================='
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print*,'---Trust_region---'
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print*,'=================='
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call wall_time(t1)
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! Allocation
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allocate(tmp_wtg(n))
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! Initialization and norm
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! The norm of the step size will be useful for the trust region
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! algorithm. We start from a first guess and the radius of the trust
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! region will evolve during the optimization.
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! avoid_saddle is actually a test to avoid saddle points
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! Initialization of the Lagrange multiplier
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lambda = 0d0
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! List of w^T.g, to avoid the recomputation
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tmp_wtg = 0d0
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if (n == n2) then
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do j = 1, n
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do i = 1, n
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tmp_wtg(j) = tmp_wtg(j) + w(i,j) * v_grad(i)
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enddo
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enddo
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else
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! For the diagonal case
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do j = 1, n
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k = int(w(j,1)+1d-15)
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tmp_wtg(j) = v_grad(k)
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enddo
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endif
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! Replacement of the small tmp_wtg corresponding to a negative eigenvalue
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! in the case of avoid_saddle
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if (avoid_saddle .and. e_val(1) < - thresh_eig) then
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i = 2
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! Number of negative eigenvalues
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do while (e_val(i) < - thresh_eig)
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if (tmp_wtg(i) < thresh_wtg2) then
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if (version_avoid_saddle == 1) then
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tmp_wtg(i) = 1d0
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elseif (version_avoid_saddle == 2) then
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tmp_wtg(i) = DABS(e_val(i))
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elseif (version_avoid_saddle == 3) then
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tmp_wtg(i) = dsqrt(DABS(e_val(i)))
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else
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tmp_wtg(i) = thresh_wtg2
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endif
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endif
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i = i + 1
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enddo
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! For the fist one it's a little bit different
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if (tmp_wtg(1) < thresh_wtg2) then
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tmp_wtg(1) = 0d0
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endif
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endif
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! Norm^2 of x, ||x||^2
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norm2_x = f_norm_trust_region_omp(n,e_val,tmp_wtg,0d0)
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! We just use this norm for the nb_iter = 0 in order to initialize the trust radius delta
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! We don't care about the sign of the eigenvalue we just want the size of the step in a normal Newton-Raphson algorithm
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! Anyway if the step is too big it will be reduced
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!print*,'||x||^2 :', norm2_x
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! Norm^2 of the gradient, ||v_grad||^2
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norm2_g = (dnrm2(n,v_grad,1))**2
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!print*,'||grad||^2 :', norm2_g
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! Trust radius initialization
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! At the first iteration (nb_iter = 0) we initialize the trust region
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! with the norm of the step generate by the Newton's method ($\textbf{x}_1 =
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! (\textbf{H}_0)^{-1} \cdot \textbf{g}_0$,
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! we compute this norm using f_norm_trust_region_omp as explain just
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! below)
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! trust radius
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if (nb_iter == 0) then
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trust_radius2 = norm2_x
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! To avoid infinite loop of cancellation of this first step
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! without changing delta
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nb_iter = 1
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! Compute delta, delta = sqrt(trust_radius)
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delta = dsqrt(trust_radius2)
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endif
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! Modification of the trust radius
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! In function of rho (which represents the agreement between the model
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! and the reality, cf. rho_model) the trust region evolves. We update
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! delta (the radius of the trust region).
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! To avoid too big trust region we put a maximum size.
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! Modification of the trust radius in function of rho
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if (rho >= 0.75d0) then
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delta = 2d0 * delta
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elseif (rho >= 0.5d0) then
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delta = delta
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elseif (rho >= 0.25d0) then
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delta = 0.5d0 * delta
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else
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delta = 0.25d0 * delta
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endif
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! Maximum size of the trust region
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!if (delta > 0.5d0 * n * pi) then
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! delta = 0.5d0 * n * pi
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! print*,'Delta > delta_max, delta = 0.5d0 * n * pi'
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!endif
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if (delta > 1d10) then
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delta = 1d10
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endif
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!print*, 'Delta :', delta
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! Calculation of the optimal lambda
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! We search the solution of $(||x||^2 - \Delta^2)^2 = 0$
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! - If $||\textbf{x}|| > \Delta$ or $h_1 < 0$ we have to add a constant
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! $\lambda > 0 \quad \text{and} \quad \lambda > -h_1$
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! - If $||\textbf{x}|| \leq \Delta$ and $h_1 \geq 0$ the solution is the
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! unconstrained one, $\lambda = 0$
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! You will find more details at the beginning
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! By giving delta, we search (||x||^2 - delta^2)^2 = 0
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! and not (||x||^2 - delta)^2 = 0
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! Research of lambda to solve ||x(lambda)|| = Delta
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! Display
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!print*, 'e_val(1) = ', e_val(1)
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!print*, 'w_1^T.g =', tmp_wtg(1)
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! H positive definite
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if (e_val(1) > - thresh_eig) then
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norm2_x = f_norm_trust_region_omp(n,e_val,tmp_wtg,0d0)
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!print*, '||x(0)||=', dsqrt(norm2_x)
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!print*, 'Delta=', delta
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! H positive definite, ||x(lambda = 0)|| <= Delta
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if (dsqrt(norm2_x) <= delta) then
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!print*, 'H positive definite, ||x(lambda = 0)|| <= Delta'
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!print*, 'lambda = 0, no lambda optimization'
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lambda = 0d0
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! H positive definite, ||x(lambda = 0)|| > Delta
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else
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! Constraint solution
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!print*, 'H positive definite, ||x(lambda = 0)|| > Delta'
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!print*,'Computation of the optimal lambda...'
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call trust_region_optimal_lambda(n,e_val,tmp_wtg,delta,lambda)
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endif
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! H indefinite
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else
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if (DABS(tmp_wtg(1)) < thresh_wtg) then
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norm2_x = f_norm_trust_region_omp(n,e_val,tmp_wtg, - e_val(1))
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!print*, 'w_1^T.g <', thresh_wtg,', ||x(lambda = -e_val(1))|| =', dsqrt(norm2_x)
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endif
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! H indefinite, w_1^T.g = 0, ||x(lambda = -e_val(1))|| <= Delta
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if (dsqrt(norm2_x) <= delta .and. DABS(tmp_wtg(1)) < thresh_wtg) then
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! Add e_val(1) in order to have (H - e_val(1) I) positive definite
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!print*, 'H indefinite, w_1^T.g = 0, ||x(lambda = -e_val(1))|| <= Delta'
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!print*, 'lambda = -e_val(1), no lambda optimization'
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lambda = - e_val(1)
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! H indefinite, w_1^T.g = 0, ||x(lambda = -e_val(1))|| > Delta
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! and
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! H indefinite, w_1^T.g =/= 0
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else
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! Constraint solution/ add lambda
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!if (DABS(tmp_wtg(1)) < thresh_wtg) then
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! print*, 'H indefinite, w_1^T.g = 0, ||x(lambda = -e_val(1))|| > Delta'
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!else
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! print*, 'H indefinite, w_1^T.g =/= 0'
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!endif
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!print*, 'Computation of the optimal lambda...'
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call trust_region_optimal_lambda(n,e_val,tmp_wtg,delta,lambda)
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endif
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endif
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! Recomputation of the norm^2 of the step x
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norm2_x = f_norm_trust_region_omp(n,e_val,tmp_wtg,lambda)
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print*,''
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print*,'Summary after the trust region:'
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print*,'lambda:', lambda
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print*,'||x||:', dsqrt(norm2_x)
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print*,'delta:', delta
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! Calculation of the step x
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! x refers to $\textbf{x}^*$
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! We compute x in function of lambda using its formula :
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! \begin{align*}
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! \textbf{x}^* = \textbf{x}(\lambda) = - \sum_{i=1}^n \frac{\textbf{w}_i^T \cdot \textbf{g}}{h_i
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! + \lambda} \cdot \textbf{w}_i
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! \end{align*}
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! Initialisation
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x = 0d0
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! Calculation of the step x
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if (n == n2) then
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! Normal version
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if (.not. absolute_eig) then
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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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do j = 1, n
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x(j) = x(j) - tmp_wtg(i) * W(j,i) / (e_val(i) + lambda)
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enddo
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endif
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enddo
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! Version to use the absolute value of the eigenvalues
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else
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do i = 1, n
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if (DABS(e_val(i)) > thresh_eig) then
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do j = 1, n
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x(j) = x(j) - tmp_wtg(i) * W(j,i) / (DABS(e_val(i)) + lambda)
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enddo
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endif
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enddo
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endif
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else
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! If the hessian is diagonal
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! Normal version
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if (.not. absolute_eig) then
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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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j = int(w(i,1) + 1d-15)
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x(j) = - tmp_wtg(i) * 1d0 / (e_val(i) + lambda)
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endif
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enddo
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! Version to use the absolute value of the eigenvalues
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else
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do i = 1, n
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if (DABS(e_val(i)) > thresh_eig) then
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j = int(w(i,1) + 1d-15)
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x(j) = - tmp_wtg(i) * 1d0 / (DABS(e_val(i)) + lambda)
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endif
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enddo
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endif
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endif
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double precision :: beta, norm_x
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! Test
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! If w_1^T.g = 0, the lim of ||x(lambda)|| when lambda tend to -e_val(1)
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! is not + infinity. So ||x(lambda=-e_val(1))|| < delta, we add the first
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! eigenvectors multiply by a constant to ensure the condition
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! ||x(lambda=-e_val(1))|| = delta and escape the saddle point
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if (avoid_saddle .and. e_val(1) < - thresh_eig) then
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if (tmp_wtg(1) < 1d-15 .and. (1d0 - dsqrt(norm2_x)/delta) > 1d-3 ) then
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! norm of x
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norm_x = dnrm2(n,x,1)
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! Computes the coefficient for the w_1
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beta = delta**2 - norm_x**2
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! Updates the step x
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x = x + W(:,1) * dsqrt(beta)
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! Recomputes the norm to check
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norm_x = dnrm2(n,x,1)
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print*, 'Add w_1 * dsqrt(delta^2 - ||x||^2):'
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print*, '||x||', norm_x
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endif
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endif
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! Transformation of x
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! x is a vector of size n, so it can be write as a m by m
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! antisymmetric matrix m_x cf. "mat_to_vec_index" and "vec_to_mat_index".
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! ! Step transformation vector -> matrix
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! ! Vector with n element -> mo_num by mo_num matrix
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! do j = 1, m
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! do i = 1, m
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! if (i>j) then
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! call mat_to_vec_index(i,j,k)
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! m_x(i,j) = x(k)
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! else
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! m_x(i,j) = 0d0
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! endif
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! enddo
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! enddo
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!
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! ! Antisymmetrization of the previous matrix
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! do j = 1, m
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! do i = 1, m
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! if (i<j) then
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! m_x(i,j) = - m_x(j,i)
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! endif
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! enddo
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! enddo
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! Deallocation, end
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deallocate(tmp_wtg)
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call wall_time(t2)
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t3 = t2 - t1
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print*,'Time in trust_region:', t3
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print*,'======================'
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print*,'---End trust_region---'
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print*,'======================'
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end
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