Large scale reduction principle and application to hypothesis testing

Marianne Clausel; François Roueff; Murad S. Taqqu

doi:10.1214/15-EJS987

Large scale reduction principle and application to hypothesis testing

Marianne Clausel, François Roueff, Murad S. Taqqu

Research output: Contribution to journal › Article › peer-review

Abstract

Consider a non–linear function G(X_t) where X_t is a stationary Gaussian sequence with long–range dependence. The usual reduction principle states that the partial sums of G(X_t) behave asymptotically like the partial sums of the first term in the expansion of G in Hermite polynomials. In the context of the wavelet estimation of the long–range dependence parameter, one replaces the partial sums of G(X_t) by the wavelet scalogram, namely the partial sum of squares of the wavelet coefficients. Is there a reduction principle in the wavelet setting, namely is the asymptotic behavior of the scalogram for G(X_t) the same as that for the first term in the expansion of G in Hermite polynomial? The answer is negative in general. This paper provides a minimal growth condition on the scales of the wavelet coefficients which ensures that the reduction principle also holds for the scalogram. The results are applied to testing the hypothesis that the long-range dependence parameter takes a specific value.

Original language	English
Pages (from-to)	153-203
Number of pages	51
Journal	Electronic Journal of Statistics
Volume	9
DOIs	https://doi.org/10.1214/15-EJS987
Publication status	Published - 1 Jan 2015
Externally published	Yes

Keywords

Estimation
Hypothesis testing
Long memory
Long-range dependence
Self-simi-larity
Wavelet transform

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10.1214/15-EJS987

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title = "Large scale reduction principle and application to hypothesis testing",

abstract = "Consider a non–linear function G(Xt) where Xt is a stationary Gaussian sequence with long–range dependence. The usual reduction principle states that the partial sums of G(Xt) behave asymptotically like the partial sums of the first term in the expansion of G in Hermite polynomials. In the context of the wavelet estimation of the long–range dependence parameter, one replaces the partial sums of G(Xt) by the wavelet scalogram, namely the partial sum of squares of the wavelet coefficients. Is there a reduction principle in the wavelet setting, namely is the asymptotic behavior of the scalogram for G(Xt) the same as that for the first term in the expansion of G in Hermite polynomial? The answer is negative in general. This paper provides a minimal growth condition on the scales of the wavelet coefficients which ensures that the reduction principle also holds for the scalogram. The results are applied to testing the hypothesis that the long-range dependence parameter takes a specific value.",

keywords = "Estimation, Hypothesis testing, Long memory, Long-range dependence, Self-simi-larity, Wavelet transform",

author = "Marianne Clausel and Fran{\c c}ois Roueff and Taqqu, \{Murad S.\}",

note = "Publisher Copyright: {\textcopyright} 2015, Institute of Mathematical Statistics. All right received.",

year = "2015",

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doi = "10.1214/15-EJS987",

language = "English",

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TY - JOUR

T1 - Large scale reduction principle and application to hypothesis testing

AU - Clausel, Marianne

AU - Roueff, François

AU - Taqqu, Murad S.

PY - 2015/1/1

Y1 - 2015/1/1

N2 - Consider a non–linear function G(Xt) where Xt is a stationary Gaussian sequence with long–range dependence. The usual reduction principle states that the partial sums of G(Xt) behave asymptotically like the partial sums of the first term in the expansion of G in Hermite polynomials. In the context of the wavelet estimation of the long–range dependence parameter, one replaces the partial sums of G(Xt) by the wavelet scalogram, namely the partial sum of squares of the wavelet coefficients. Is there a reduction principle in the wavelet setting, namely is the asymptotic behavior of the scalogram for G(Xt) the same as that for the first term in the expansion of G in Hermite polynomial? The answer is negative in general. This paper provides a minimal growth condition on the scales of the wavelet coefficients which ensures that the reduction principle also holds for the scalogram. The results are applied to testing the hypothesis that the long-range dependence parameter takes a specific value.

AB - Consider a non–linear function G(Xt) where Xt is a stationary Gaussian sequence with long–range dependence. The usual reduction principle states that the partial sums of G(Xt) behave asymptotically like the partial sums of the first term in the expansion of G in Hermite polynomials. In the context of the wavelet estimation of the long–range dependence parameter, one replaces the partial sums of G(Xt) by the wavelet scalogram, namely the partial sum of squares of the wavelet coefficients. Is there a reduction principle in the wavelet setting, namely is the asymptotic behavior of the scalogram for G(Xt) the same as that for the first term in the expansion of G in Hermite polynomial? The answer is negative in general. This paper provides a minimal growth condition on the scales of the wavelet coefficients which ensures that the reduction principle also holds for the scalogram. The results are applied to testing the hypothesis that the long-range dependence parameter takes a specific value.

KW - Estimation

KW - Hypothesis testing

KW - Long memory

KW - Long-range dependence

KW - Self-simi-larity

KW - Wavelet transform

U2 - 10.1214/15-EJS987

DO - 10.1214/15-EJS987

M3 - Article

AN - SCOPUS:84922908151

SN - 1935-7524

VL - 9

SP - 153

EP - 203

JO - Electronic Journal of Statistics

JF - Electronic Journal of Statistics

ER -

Large scale reduction principle and application to hypothesis testing

Abstract

Keywords

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