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WEIGHTED LEAST ABSOLUTE DEVIATIONS ESTIMATION FOR ARMA MODELS WITH INFINITE VARIANCE

Published online by Cambridge University Press:  14 May 2007

Jiazhu Pan ,
Hui Wang  and
Qiwei Yao
Jiazhu Pan
Affiliation:
Peking University London School of Economics
Hui Wang
Affiliation:
Peking University
Qiwei Yao
Affiliation:
Peking University London School of Economics
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Abstract

For autoregressive moving average (ARMA) models with infinite variance innovations, quasi-likelihood-based estimators (such as Whittle estimators) suffer from complex asymptotic distributions depending on unknown tail indices. This makes statistical inference for such models difficult. In contrast, the least absolute deviations estimators (LADE) are more appealing in dealing with heavy tailed processes. In this paper, we propose a weighted least absolute deviations estimator (WLADE) for ARMA models. We show that the proposed WLADE is asymptotically normal, is unbiased, and has the standard root-n convergence rate even when the variance of innovations is infinity. This paves the way for statistical inference based on asymptotic normality for heavy-tailed ARMA processes. For relatively small samples numerical results illustrate that the WLADE with appropriate weight is more accurate than the Whittle estimator, the quasi-maximum-likelihood estimator (QMLE), and the Gauss–Newton estimator when the innovation variance is infinite and that the efficiency loss due to the use of weights in estimation is not substantial.The authors thank the two referees for their valuable suggestions. The work was partially supported by an EPSRC research grant (UK) and the Natural Science Foundation of China (grant 10471005).

Type
Research Article
Information
Econometric Theory , Volume 23 , Issue 5 , October 2007 , pp. 852 - 879
Copyright
© 2007 Cambridge University Press

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References

REFERENCES

Adler, R.J., R. Feldaman, & M. Taqqu (1997) A User's Guide to Heavy Tails: Statistical Techniques for Analyzing Heavy Tailed Distribution and Processes. Birkhauser.
An, H.Z. & Z.G. Chen (1982) On convergence of LAD estimates in autoregression with infinite variance. Journal of Multivariate Analysis 12, 335345.Google Scholar
Billingsley, P. (1999) Convergence of Probability Measures. Wiley.
Brockwell, P.J. & R.A. Davis (1991) Time Series: Theory and Methods. Springer-Verlag.
Calder, M. & R.A. Davis (1998) Inference for linear processes with stable noise. In R.J. Adler, R. Feldaman, & M. Taqqu (eds.), A Practical Guide to Heavy Tails, pp. 159176. Birkhauser.
Davis, R.A. (1996) Gauss-Newton and M–estimation for ARMA processes with infinite variance. Stochastic Processes and Their Applications 63, 7595.Google Scholar
Davis, R.A. & W.T.M. Dunsmuir (1997) Least absolute deviation estimation for regression with ARMA errors. Journal of Theoretical Probability 10, 481497.Google Scholar
Davis, R.A., K. Knight, & J. Liu (1992) M–estimation for autoregressions with infinite variance. Stochastic Processes and Their Applications 40, 145180.Google Scholar
Davis, R.A. & S.I. Resnick (1985) Limit theory for moving averages of random variables with regularly varying tail probabilities. Annals of Probability 13, 179195.Google Scholar
Davis, R.A. & S.I. Resnick (1986) Limit theory for the sample covariance and correlation functions of moving averages. Annals of Statistics 14, 533558.Google Scholar
Dunsmuir, W.T.M. & N.M. Spencer (1991) Strong consistency and asymptotic normality of L1 estimates of the autoregressive moving-average model. Journal of Time Series Analysis 12, 95104.Google Scholar
Gross, S. & W.L. Steiger (1979) Least absolute deviation estimates in autoregressions with infinite variance. Journal of Applied Probability 16, 104116.Google Scholar
Hall, P.C. & C.C. Heyde (1980) Martingale Limit Theory and Its Applications. Academic Press.
Hjort, N.L. & D. Pollard (1993) Asymptotics for Minimisers of Convex Processes. Yale University. Available at http://www.stat.yale.edu/∼pollard/Papers/convex.pdf.
Horvath, L. & F. Liese (2004) Lp-estimators in ARCH models. Journal of Statistical Planning and Inference 119, 277309.Google Scholar
Jansen, D. & C. de Vries (1991) On the frequency of large stock returns: Putting booms and busts into perspective. Review of Economics and Statistics 73, 1828.Google Scholar
Koedijk, K.G., M.M.A. Schafgans, & C.G. De Vries (1990) The tail index of exchange rate returns. Journal of International Economics 29, 93108.Google Scholar
Kokoszka, P.S. & M.S. Taqqu (1996) Parameter estimation for infinite variance fractional ARIMA. Annals of Statistics 24, 18801913.Google Scholar
Ling, S. (2005) Self-weighted LAD estimation for infinite variance autoregressive models. Journal of the Royal Statistical Society, Series B 67, 381393.Google Scholar
Mikosch, T., T. Gadrich, & R.J. Adler (1995) Parameter estimation for ARMA models with infinite variance innovations. Annals of Statistics 23, 305326.Google Scholar
Pollard, D. (1984) Convergence of Stochastic Processes. Springer-Verlag.
Resnick, S.I. (1997) Heavy tail modeling and teletraffic data (with discussions). Annals of Statistics 25, 18051869.Google Scholar
Rudin, W. (1991) Functional Analysis. McGraw-Hill.
Silverman, B.W. (1986) Density Estimation for Statistics and Data Analysis. Chapman and Hall.