Abstract
The danger of confusing long-range dependence with non-stationarity has been pointed out by many authors. Finding an answer to this difficult question is of importance to model time-series showing trend-like behavior, such as river runoff in hydrology, historical temperatures in the study of climates changes, or packet counts in network traffic engineering.
The main goal of this paper is to develop a test procedure to detect the presence of non-stationarity for a class of processes whose K-th order difference is stationary. Contrary to most of the proposed methods, the test procedure has the same distribution for short-range and long-range dependence covariance stationary processes, which means that this test is able to detect the presence of non-stationarity for processes showing long-range dependence or which are unit root.
The proposed test is formulated in the wavelet domain, where a change in the generalized spectral density results in a change in the variance of wavelet coefficients at one or several scales. Such tests have been already proposed in [26], but these authors do not have taken into account the dependence of the wavelet coefficients within scales and between scales. Therefore, the asymptotic distribution of the test they have proposed was erroneous; as a consequence, the level of the test under the null hypothesis of stationarity was wrong.
In this contribution, we introduce two test procedures, both using an estimator of the variance of the scalogram at one or several scales. The asymptotic distribution of the test under the null is rigorously justified. The pointwise consistency of the test in the presence of a single jump in the general spectral density is also be presented. A limited Monte-Carlo experiment is performed to illustrate our findings.
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References
Andrews., D. W. K. (1991) Heteroskedasticity and autocorrelation consistent covariance matrix estimation. Econometrica, 59, 817–858.
Berkes, I, Horvátz, L, Kokoszka P. and Shao, Q-M. (2006) On discriminating between long-range dependence and change in mean,. The annals of statistics, 34, 1140–1165.
Bhattacharya, R.N. Gupta, V.K. and Waymire, E. (1983) The Hurst effect under trends. Journal of Applied Probability, 20, 649–662.
Billingsley, P. (1999) Convergence of probability measures. Wiley Series in Probability and Statistics: Probability and Statistics. John Wiley & Sons Inc., New York, second edition.
Boes, D.C. and Salas. J. D. (1978) Nonstationarity of the Mean and the Hurst Phenomenon. Water Resources Research, 14, 135–143.
Brodsky, B. E. and Darkhovsky, B. S. (2000) Non-parametric statistical diagnosis, volume 509 of Mathematics and its Applications. Kluwer Academic Publishers, Dordrecht, 2000.
Carmona, P. Petit, F., Pitman, J. and Yor. M. (1999) On the laws of homogeneous functionals of the Brownian bridge. Studia Sci. Math. Hungar., 35, 445–455.
Cohen, A. (2003) Numerical analysis of wavelet methods, volume 32 of Studies in Mathematics and its Applications. North-Holland Publishing Co., Amsterdam.
Diebold, F.X. and Inoue, A. (2001) Long memory and regime switching. J. Econometrics, 105, 131–159.
Giraitis, L., Kokoszka, P., Leipus, R. and Teyssière, G. (2003) Rescaled variance and related tests for long memory in volatility and levels. Journal of econometrics, 112, 265–294.
Granger, C.W.J. and Hyung, N. (2004) Occasional structural breaks and long memory with an application to the S& P 500 absolute stock returns. Journal of Empirical Finance, 11, 399–421.
Hidalgo, J. and Robinson, P. M. (1996) Testing for structural change in a longmemory environment. J. Econometrics, 70, 159–174.
Hurvich, C.M., Lang, G. and Soulier, P. (2005) Estimation of long memory in the presence of a smooth nonparametric trend. J. Amer. Statist. Assoc., 100, 853–871.
Inclan, C. and Tiao, G. C. (1994) Use of cumulative sums of squares for retrospective detection of changes of variance. American Statistics, 89, 913–923.
Kiefer, J. (1959) K-sample analogues of the Kolmogorov-Smirnov and Cramér-V. Mises tests. Ann. Math. Statist., 30, 420–447.
Klemes, V. (1974) The Hurst Phenomenon: A Puzzle? Water Resources Research, 10 675–688.
Mallat, S. (1998) A wavelet tour of signal processing. Academic Press Inc., San Diego, CA.
Mikosch, T. and St˘ric˘, C. (2004) Changes of structure in financial time series and the Garch model. REVSTAT, 2, 41–73.
Moulines, E., Roueff, F. and Taqqu, M. S. (2007) On the spectral density of the wavelet coefficients of long memory time series with application to the log-regression estimation of the memory parameter. J. Time Ser. Anal., 28, 155–187.
Moulines, E., Roueff, F. and Taqqu M.S. (2008) A wavelet Whittle estimator of the memory parameter of a non-stationary Gaussian time series. Ann. Statist., 36, 1925–1956.
Newey, W. K. and West K. D. (1987) A simple, positive semidefinite, heteroskedasticity and autocorrelation consistent covariance matrix. Econometrica, 55, 703–708.
Newey, W. K. and West K. D. (1994) Automatic lag selection in covariance matrix estimation. Rev. Econom. Stud., 61, 631–653.
Pitman, J. and Yor, M. (1999). The law of the maximum of a Bessel bridge. Electron. J. Probab., 4, no. 15, 35 pp.
Potter., K.W (1976) Evidence of nonstationarity as a physical explanation of the Hurst phenomenon. Water Resources Research, 12, 1047–1052.
Ramachandra Rao, A. and Yu., G.H. (1986) Detection of nonstationarity in hydrologic time series. Management Science, 32, 1206–1217.
Whitcher, B., Byers, S.D., Guttorp, P. and Percival, D. (2002) Testing for homogeneity of variance in time series: Long memory, wavelets and the nile river. Water Resour. Res, 38 (5), 1054, doi:10.1029/2001WR000509.
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Kouamo, O., Moulines, E., Roueff, F. (2010). Testing for homogeneity of variance in the wavelet domain.. In: Doukhan, P., Lang, G., Surgailis, D., Teyssière, G. (eds) Dependence in Probability and Statistics. Lecture Notes in Statistics(), vol 200. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-14104-1_10
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