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Time-Series Analysis

Time-Series Analysis. J. C. (Clint) Sprott Department of Physics University of Wisconsin - Madison Workshop presented at the 2004 SCTPLS Annual Conference at Marquette University on July 15, 2004. Agenda. Introductory lecture Hands-on tutorial Strange attractors – Break –

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Time-Series Analysis

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  1. Time-Series Analysis J. C. (Clint) Sprott Department of Physics University of Wisconsin - Madison Workshop presented at the 2004 SCTPLS Annual Conference at Marquette University on July 15, 2004

  2. Agenda • Introductory lecture • Hands-on tutorial • Strange attractors • – Break – • Individual exploration • Closing comments

  3. Motivation Many quantities in nature fluctuate in time. Examples are the stock market, the weather, seismic waves, sunspots, heartbeats, and plant and animal populations. Until recently it was assumed that such fluctuations are a consequence of random and unpredictable events. With the discovery of chaos, it has come to be understood that some of these cases may be a result of deterministic chaos and hence predictable in the short term and amenable to simple modeling. Many tests have been developed to determine whether a time series is random or chaotic, and if the latter, to quantify the chaos. If chaos is found, it may be possible to improve the short-term predictability and enhance understanding of the governing process.

  4. Goals This workshop will provide examples of time-series data from real systems as well as from simple chaotic models. A variety of tests will be described including linear methods such as Fourier analysis and autoregression, and nonlinear methods using state-space reconstruction. The primary methods for nonlinear analysis include calculation of the correlation dimension and largest Lyapunov exponent, as well as principal component analysis and various nonlinear predictors. Methods for detrending, noise reduction, false nearest neighbors, and surrogate data tests will be explained. Participants will use the "Chaos Data Analyzer" program to analyze a variety of typical time-series records and will learn to distinguish chaos from colored noise and to avoid the many common pitfalls that can lead to false conclusions. No previous knowledge or experience is assumed.

  5. Precautions • More art than science • No sure-fire methods • Easy to fool yourself • Many published false claims • Must use multiple tests • Conclusions seldom definitive • Compare with surrogate data • Must ask the right questions • “Is it chaos?” too simplistic

  6. Applications • Prediction • Noise reduction • Scientific insight • Control

  7. Examples • Weather data • Climate data • Tide levels • Seismic waves • Cepheid variable stars • Sunspots • Financial markets • Ecological fluctuations • EKG and EEG data • …

  8. (Non-)Time Series • Core samples • Terrain features • Sequence of letters in written text • Notes in a musical composition • Bases in a DNA molecule • Heartbeat intervals • Dripping faucet • Necker cube flips • Eye fixations during a visual task • ...

  9. Methods • Linear (traditional) • Fourier Analysis • Autocorrelation • ARMA • LPC … • Nonlinear (chaotic) • State space reconstruction • Correlation dimension • Lyapunov exponent • Principle component analysis • Surrogate data …

  10. Resources

  11. Hierarchy of Dynamical Behaviors

  12. Typical Experimental Data 5 x -5 500 0 Time

  13. Stationarity

  14. Detrending

  15. Detrended

  16. Case Study

  17. First Return Map

  18. Time-Delayed Embedding Space • Plot x(t) vs. x(t-), x(t-2), x(t-3), … • Embedding dimension is # of delays • Must choose  and dim carefully • Orbit does not fill the space • Diffiomorphic to actual orbit • Dim of orbit = min # of variables • x(t) can be any measurement fcn

  19. Measurement Functions Xn+1 = 1 – 1.4X2 + 0.3Yn Yn+1 = Xn Hénon map:

  20. Correlation Dimension N(r)  rD2 D2 = dlogN(r)/dlogr

  21. Inevitable Ambiguity

  22. Lyapunov Exponent Rn = R0en  = <ln|Rn/R0|>

  23. Principal Component Analysis x(t)

  24. State-space Prediction

  25. Surrogate Data Original time series Shuffled surrogate Phase randomized

  26. General Strategy • Verify integrity of the data • Test for stationarity • Look at return maps, etc. • Look at autocorrelation function • Look at power spectrum • Calculate correlation dimension • Calculate Lyapunov exponent • Compare with surrogate data sets • Construct models • Make predictions from models

  27. Tutorial using CDA

  28. Types of Attractors Limit Cycle Fixed Point Focus Node Torus Strange Attractor

  29. Strange Attractors • Limit set as t  • Set of measure zero • Basin of attraction • Fractal structure • non-integer dimension • self-similarity • infinite detail • Chaotic dynamics • sensitivity to initial conditions • topological transitivity • dense periodic orbits • Aesthetic appeal

  30. Individual Exploration using CDA

  31. Practical Considerations • Calculation speed • Required number of data points • Required precision of the data • Noisy data • Multivariate data • Filtered data • Missing data • Nonuniformly sampled data • Nonstationary data

  32. Some General High-Dimensional Models Fourier Series: Linear Autoregression: (ARMA, LPC, MEM…) Nonlinear Autogression: (Polynomial Map) Neural Network:

  33. Artificial Neural Network

  34. Summary • Nature is complex • Simple models may suffice but

  35. http://sprott.physics.wisc.edu/lectures/tsa.ppt (this presentation) http://sprott.physics.wisc.edu/cda.htm (Chaos Data Analyzer) sprott@physics.wisc.edu (my email) References

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