Your search keyword '"Gear, C. William"' showing total 3 results

1. Data-Driven Reduction for Multiscale Stochastic Dynamical Systems

Author

Dsilva, Carmeline J., Talmon, Ronen, Gear, C. William, Coifman, Ronald R., and Kevrekidis, Ioannis G.

Subjects

FOS: Mathematics, Dynamical Systems (math.DS), Mathematics - Dynamical Systems

Abstract

Multiple time scale stochastic dynamical systems are ubiquitous in science and engineering, and the reduction of such systems and their models to only their slow components is often essential for scientific computation and further analysis. Rather than being available in the form of an explicit analytical model, often such systems can only be observed as a data set which exhibits dynamics on several time scales. We will focus on applying and adapting data mining and manifold learning techniques to detect the slow components in such multiscale data. Traditional data mining methods are based on metrics (and thus, geometries) which are not informed of the multiscale nature of the underlying system dynamics; such methods cannot successfully recover the slow variables. Here, we present an approach which utilizes both the local geometry and the local dynamics within the data set through a metric which is both insensitive to the fast variables and more general than simple statistical averaging. Our analysis of the approach provides conditions for successfully recovering the underlying slow variables, as well as an empirical protocol guiding the selection of the method parameters.

Published

2015

2. Manifold learning techniques and model reduction applied to dissipative PDEs

Author

Sonday, Benjamin E., Singer, Amit, Gear, C. William, and Kevrekidis, Ioannis G.

Subjects

FOS: Mathematics, FOS: Physical sciences, Dynamical Systems (math.DS), Mathematics - Dynamical Systems, Computational Physics (physics.comp-ph), Physics - Computational Physics, Mathematics::Numerical Analysis

Abstract

We link nonlinear manifold learning techniques for data analysis/compression with model reduction techniques for evolution equations with time scale separation. In particular, we demonstrate a `"nonlinear extension" of the POD-Galerkin approach to obtaining reduced dynamic models of dissipative evolution equations. The approach is illustrated through a reaction-diffusion PDE, and the performance of different simulators on the full and the reduced models is compared. We also discuss the relation of this nonlinear extension with the so-called "nonlinear Galerkin" methods developed in the context of Approximate Inertial Manifolds., Comment: 20 pages, 8 figures

Published

2010

3. Equation-Free Multiscale Computation: enabling microscopic simulators to perform system-level tasks

Author

Kevrekidis, Ioannis G., Gear, C. William, Hyman, James M., Kevrekidis, Panagiotis G., Runborg, Olof, and Theodoropoulos, Constantinos

Subjects

FOS: Physical sciences, Computational Physics (physics.comp-ph), Physics - Computational Physics

Abstract

We present and discuss a framework for computer-aided multiscale analysis, which enables models at a "fine" (microscopic/stochastic) level of description to perform modeling tasks at a "coarse" (macroscopic, systems) level. These macroscopic modeling tasks, yielding information over long time and large space scales, are accomplished through appropriately initialized calls to the microscopic simulator for only short times and small spatial domains. Our equation-free (EF) approach, when successful, can bypass the derivation of the macroscopic evolution equations when these equations conceptually exist but are not available in closed form. We discuss how the mathematics-assisted development of a computational superstructure may enable alternative descriptions of the problem physics (e.g. Lattice Boltzmann (LB), kinetic Monte Carlo (KMC) or Molecular Dynamics (MD) microscopic simulators, executed over relatively short time and space scales) to perform systems level tasks (integration over relatively large time and space scales,"coarse" bifurcation analysis, optimization, and control) directly. In effect, the procedure constitutes a systems identification based, "closure on demand" computational toolkit, bridging microscopic/stochastic simulation with traditional continuum scientific computation and numerical analysis. We illustrate these ideas through examples from chemical kinetics (LB, KMC), rheology (Brownian Dynamics), homogenization and the computation of "coarsely self-similar" solutions, and discuss various features, limitations and potential extensions of the approach.

Published

2002