The bifurcation structure within robust chaos for two-dimensional piecewise-linear maps
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Date
2024-07
Open Access Location
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Publisher
Elsevier Ltd
Rights
(c) 2024 The Author/s
CC BY 4.0
CC BY 4.0
Abstract
We study two-dimensional, two-piece, piecewise-linear maps having two saddle fixed points. Such maps reduce to a four-parameter family and are well known to have a chaotic attractor throughout open regions of parameter space. The purpose of this paper is to determine where and how this attractor undergoes bifurcations. We explore the bifurcation structure numerically by using Eckstein's greatest common divisor algorithm to estimate from sample orbits the number of connected components in the attractor. Where the map is orientation-preserving the numerical results agree with formal results obtained previously through renormalisation. Where the map is orientation-reversing or non-invertible the same renormalisation scheme appears to generate the bifurcation boundaries, but here we need to account for the possibility of some stable low-period solutions. Also the attractor can be destroyed in novel heteroclinic bifurcations (boundary crises) that do not correspond to simple algebraic constraints on the parameters. Overall the results reveal a broadly similar component-doubling bifurcation structure in the orientation-reversing and non-invertible settings, but with some additional complexities.
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Keywords
Piecewise-linear maps, Difference equations, Border-collision normal form, Robust chaos, Renormalisation
Citation
Ghosh I, McLachlan RI, Simpson DJW. (2024). The bifurcation structure within robust chaos for two-dimensional piecewise-linear maps. Communications in Nonlinear Science and Numerical Simulation. 134.