Principal axes for stochastic dynamics
Abstract
We introduce a general procedure for directly ascertaining how many independent stochastic sources exist in a complex system modeled through a set of coupled Langevin equations of arbitrary dimension. The procedure is based on the computation of the eigenvalues and the corresponding eigenvectors of local diffusion matrices. We demonstrate our algorithm by applying it to two examples of systems showing Hopf-bifurcation. We argue that computing the eigenvectors associated to the eigenvalues of the diffusion matrix at local mesh points in the phase space enables one to define vector fields of stochastic eigendirections. In particular, the eigenvector associated to the lowest eigenvalue defines the path of minimum stochastic forcing in phase space, and a transform to a new coordinate system aligned with the eigenvectors can increase the predictability of the system.
Cite
@article{arxiv.1105.1700,
title = {Principal axes for stochastic dynamics},
author = {V. V. Vasconcelos and F. Raischel and M. Haase and J. Peinke and M. Wächter and P. G. Lind and D. Kleinhans},
journal= {arXiv preprint arXiv:1105.1700},
year = {2013}
}
Comments
10 pages, 7 figures