Finding Chaos in Noisy Systems

In the past twenty years there has been much interest in the physical and biological sciences in nonlinear dynamical systems that appear to have random, unpredictable behavior. One important parameter of a dynamic system is the dominant Lyapunov exponent (LE). When the behavior of the system is comp...

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Bibliographic Details
Main Authors: Douglas Nychka, Slephen Ellner, Daniel McCaffrey, A. R. Gallant
Other Authors: The Pennsylvania State University CiteSeerX Archives
Format: Text
Language:English
Published: 1991
Subjects:
Lyapunov Exponent
Nonparametric Regression
Thin Plate Splines
Cross-validation
Neural Networks
Dynamical Systems
Marten Fur Returns
Hudson
Hudson Bay
Online Access:http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.154.4019
http://www.stat.ncsu.edu/library/mimeo.archive/ISMS_1991_1996.pdf
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Summary:In the past twenty years there has been much interest in the physical and biological sciences in nonlinear dynamical systems that appear to have random, unpredictable behavior. One important parameter of a dynamic system is the dominant Lyapunov exponent (LE). When the behavior of the system is compared for two similar initial conditions, this exponent is related to the rate at which the subsequent trajectories diverge. A bounded system with a positive LE is one operational definition of chaotic behavior. Most methods for determining the LE have assumed thousands of observations generated from carefully controlled physical experiments. Less attention has been given to estimating the LE for biological and economic systems that are subjected to random perturbations and observed over a limited amount of time. Using nonparametric regression techniques (Neural Networks and Thin Plate Splines) it is possible to consistently estimate the LE. The properties of these methods have been studied using simulated data and are applied to a biological time series: marten fur returns for the Hudson Bay Company (1820-1900). Based on a nonparametric analysis there is little evidence for lowdimensional chaos in these data. Although these methods appear to work well for systems perturbed by small amounts of noise, finding chaos in a system with a significant stochastic component may be difficult.

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