Your search keyword '"34C28, 37N10"' showing total 2 results

1. Topological chaos, braiding and bifurcation of almost-cyclic sets

Author

Grover, Piyush, Ross, Shane D., Stremler, Mark A., and Kumar, Pankaj

Subjects

Nonlinear Sciences - Chaotic Dynamics, 34C28, 37N10

Abstract

In certain two-dimensional time-dependent flows, the braiding of periodic orbits provides a way to analyze chaos in the system through application of the Thurston-Nielsen classification theorem (TNCT). We expand upon earlier work that introduced the application of the TNCT to braiding of almost-cyclic sets, which are individual components of almost-invariant sets [Stremler, Ross, Grover, Kumar, Topological chaos and periodic braiding of almost-cyclic sets. Physical Review Letters 106 (2011), 114101]. In this context, almost-cyclic sets are periodic regions in the flow with high local residence time that act as stirrers or `ghost rods' around which the surrounding fluid appears to be stretched and folded. In the present work, we discuss the bifurcation of the almost-cyclic sets as a system parameter is varied, which results in a sequence of topologically distinct braids. We show that, for Stokes' flow in a lid-driven cavity, these various braids give good lower bounds on the topological entropy over the respective parameter regimes in which they exist. We make the case that a topological analysis based on spatiotemporal braiding of almost-cyclic sets can be used for analyzing chaos in fluid flows. Hence we further develop a connection between set-oriented statistical methods and topological methods, which promises to be an important analysis tool in the study of complex systems., Comment: Submitted to Chaos

Published

2012

2. Topological chaos, braiding and bifurcation of almost-cyclic sets

Author

Mark A. Stremler, Shane D. Ross, Piyush Grover, Pankaj Kumar, Biomedical Engineering and Mechanics, and Virginia Tech

Subjects

2-dimensional maps, Pure mathematics, Entropy, Complex system, FOS: Physical sciences, General Physics and Astronomy, Transport, Context (language use), Topological entropy, Invarient sets, 01 natural sciences, 34C28, 37N10, 010305 fluids & plasmas, 0103 physical sciences, Braid, Classification theorem, Fluid mechanics, Dynamical-systems, 0101 mathematics, Manifolds, Approximation, Mathematical Physics, Bifurcation, Mathematics, Sequence, Applied Mathematics, 010102 general mathematics, Statistical and Nonlinear Physics, Nonlinear Sciences - Chaotic Dynamics, Coherent structures, Flow (mathematics), Advection, Chaotic Dynamics (nlin.CD)

Abstract

In certain two-dimensional time-dependent flows, the braiding of periodic orbits provides a way to analyze chaos in the system through application of the Thurston-Nielsen classification theorem (TNCT). We expand upon earlier work that introduced the application of the TNCT to braiding of almost-cyclic sets, which are individual components of almost-invariant sets [Stremler, Ross, Grover, Kumar, Topological chaos and periodic braiding of almost-cyclic sets. Physical Review Letters 106 (2011), 114101]. In this context, almost-cyclic sets are periodic regions in the flow with high local residence time that act as stirrers or `ghost rods' around which the surrounding fluid appears to be stretched and folded. In the present work, we discuss the bifurcation of the almost-cyclic sets as a system parameter is varied, which results in a sequence of topologically distinct braids. We show that, for Stokes' flow in a lid-driven cavity, these various braids give good lower bounds on the topological entropy over the respective parameter regimes in which they exist. We make the case that a topological analysis based on spatiotemporal braiding of almost-cyclic sets can be used for analyzing chaos in fluid flows. Hence we further develop a connection between set-oriented statistical methods and topological methods, which promises to be an important analysis tool in the study of complex systems., Comment: Submitted to Chaos

Published

2012