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author | Jaron Kent-Dobias <jaron@kent-dobias.com> | 2022-01-28 12:57:40 +0100 |
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committer | Jaron Kent-Dobias <jaron@kent-dobias.com> | 2022-01-28 12:57:40 +0100 |
commit | a2cdc257777921e0af7f9984c9c91ccbdb398367 (patch) | |
tree | 92f4afeaf429baec040618e9344a6a72554fb7a3 | |
parent | 20197dc9824a736f64544911a69084d3dec0554a (diff) | |
parent | 6c9967a13e5f8d080b9b2ebcfaa61af31e12e47c (diff) | |
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Merge branch 'master' of https://git.overleaf.com/605b542c422edc5cfe6c3275
-rw-r--r-- | stokes.tex | 39 |
1 files changed, 30 insertions, 9 deletions
@@ -444,15 +444,6 @@ imaginary energy join. \section{Numerics} To confirm the presence of Stokes lines under certain processes in the $p$-spin, we studied the problem numerically. -\begin{equation} - \mathcal L(z(t), z'(t)) - = 1-\frac{\operatorname{Re}(\dot z^*_iz'_i)}{|\dot z||z'|} -\end{equation} -\begin{equation} - \mathcal C[\mathcal L]=\int dt\,\mathcal L(z(t), z'(t)) -\end{equation} -$\mathcal C$ has minimum of zero, which is reached only by functions $z(t)$ whose tangent is everywhere parallel to the direction of the dynamics. Therefore, finding functions which reach this minimum will find time-reparameterized Stokes lines. For the sake of numeric stability, we look for functions whose tangent has constant norm. - \bibliographystyle{unsrt} @@ -516,4 +507,34 @@ Putting these pieces together, we find \frac{\partial\phi}{\partial\bar z^{\bar\jmath}}\frac\partial{\partial z^i} \end{equation} +\section{Numerics} + +To study Stokes lines numerically, we approximated them by parametric curves. +If $z_0$ and $z_1$ are two stationary points of the action with +$\operatorname{Re}\mathcal S(z_0)>\operatorname{Re}\mathcal S(z_1)$, then we +take the curve +\begin{equation} + z(t) + =(1-t)z_0+tz_1+(1-t)t\sum_{i=0}^mg_it^i +\end{equation} +where the $g$s are undetermined complex vectors. These are fixed by minimizing +a cost function, which has a global minimum only for Stokes lines. Defining +\begin{equation} + \mathcal L(t) + = 1-\frac{\operatorname{Re}[\dot z^*(z(t))\cdot z'(t)]}{|\dot z(z(t))||z'(t)|} +\end{equation} +this cost is given by +\begin{equation} + \mathcal C=\int_0^1 dt\,\mathcal L(t) +\end{equation} +$\mathcal C$ has minimum of zero, which is reached only by functions $z(t)$ +whose tangent is everywhere parallel to the direction $\dot z$ of the dynamics. +Therefore, functions that minimize $\mathcal C$ are time-reparameterized Stokes +lines. + +We explicitly computed the gradient and Hessian of $\mathcal C$ with respect to +the parameter vectors $g$. Stokes lines are found or not between points by +using the Levenberg--Marquardt algorithm starting from $g^{(i)}=0$ for all $i$, +and approximating the cost integral by a finite sum. + \end{document} |