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Recurrence properties of autoregressive processes with super-heavy-tailed innovations

Published online by Cambridge University Press:  14 July 2016

Assaf Zeevi*
Affiliation:
Columbia University
Peter W. Glynn*
Affiliation:
Stanford University
*
Postal address: Graduate School of Business, Columbia University, 3022 Broadway, New York, NY 10027-6902, USA. Email address: [email protected]
∗∗ Postal address: Department of Management Science and Engineering, Stanford University, Stanford, CA 94305-4026, USA. Email address: [email protected]

Abstract

This paper studies recurrence properties of autoregressive (AR) processes with ‘super-heavy-tailed’ innovations. Specifically, we study the case where the innovations are distributed, roughly speaking, as log-Pareto random variables (i.e. the tail decay is essentially a logarithm raised to some power). We show that these processes exhibit interesting and somewhat surprising behaviour. In particular, we show that AR(1) processes, with the usual root assumption that is necessary for stability, can exhibit null-recurrent as well as transient dynamics when the innovations follow a log-Cauchy-type distribution. In this regime, the recurrence classification of the process depends, somewhat surprisingly, on the value of the constant pre-multiplier of this distribution. More generally, for log-Pareto innovations, we provide a positive-recurrence/null-recurrence/transience classification of the corresponding AR processes.

Type
Research Papers
Copyright
Copyright © Applied Probability Trust 2004 

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References

Athreya, K., and Pantula, S. (1986). Mixing properties of Harris chains and autoregressive processes. J. Appl. Prob. 23, 880892.10.2307/3214462Google Scholar
Billingsley, P. (1995). Probability and Measure, 3rd edn. John Wiley, New York.Google Scholar
Borovkov, A. A. (1998). Ergodicity and Stability of Stochastic Processes. John Wiley, Chichester.Google Scholar
Brockwell, P. J., and Davis, R. A. (1991). Time Series: Theory and Methods. Springer, New York.10.1007/978-1-4419-0320-4Google Scholar
Brockwell, P. J., Resnick, S. I., and Tweedie, R. L. (1982). Storage processes with general release rule and additive inputs. Adv. Appl. Prob. 14, 392433.10.2307/1426528Google Scholar
Diaconis, P., and Freedman, D. (1999). Iterated random functions. SIAM Rev. 41, 4576.10.1137/S0036144598338446Google Scholar
Doob, J. L. (1953). Stochastic Processes. John Wiley, New York.Google Scholar
Duflo, M. (1997). Random Iterative Models. Springer, Berlin.10.1007/978-3-662-12880-0Google Scholar
Meyn, S. P., and Tweedie, R. L. (1993). Markov Chains and Stochastic Stability. Springer, London.10.1007/978-1-4471-3267-7Google Scholar
Porat, B. (1994). Digital Processing of Random Signals. Prentice Hall, Englewood Cliffs, NJ.Google Scholar
Rai, S., Glynn, J. E., and Glynn, P. W. (2002). Recurrence classification for a family of non-linear storage models. Tech. Rep., Department of Management Science and Engineering, Stanford University. Available at http://www.stanford.edu/dept/MSandE/faculty/glynn/.Google Scholar
Vervaat, W. (1979). On a stochastic difference equation and a representation of nonnegative infinitely divisible random variables. Adv. Appl. Prob. 11, 750783.10.2307/1426858Google Scholar