Copyright @ 2009 International Statistical Institute / Bernoulli Society for Mathematical Statistics and Probability.Let {(Yi,Xi), i ∈ ZN} be a stationary real-valued (d + 1)-dimensional spatial processes. Denote by x  →
qp(x), p ∈ (0, 1), x ∈ Rd , the spatial quantile regression function of order p, characterized by P{Yi ≤
qp(x)|Xi = x} = p. Assume that the process has been observed over an N-dimensional rectangular domain
of the form In := {i = (i1, . . . , iN) ∈ ZN|1 ≤ ik
≤ nk, k = 1, . . . , N}, with n = (n1, . . . , nN) ∈ ZN. We
propose a local linear estimator of qp. That estimator extends to random fields with unspecified and possibly
highly complex spatial dependence structure, the quantile regression methods considered in the context of
independent samples or time series. Under mild regularity assumptions, we obtain a Bahadur representation
for the estimators of qp and its first-order derivatives, from which we establish consistency and asymptotic
normality. The spatial process is assumed to satisfy general mixing conditions, generalizing classical time
series mixing concepts. The size of the rectangular domain In is allowed to tend to infinity at different
rates depending on the direction in ZN (non-isotropic asymptotics). The method provides muchAustralian Research Counci

Hallin, M

Lu, Z

Yu, K

Bernoulli

English

Let {(Yi,Xi), i ∈ ZN} be a stationary real-valued (d+1)-dimensional spatial processes. Denote by x 7 → qp(x), p ∈ (0, 1), x ∈ Rd, the spatial quantile regres-sion function of order p, characterized by P{Yi ≤ qp(x)|Xi = x}  = p. Assume that the process has been observed over an N-dimensional rectangular domain of the form In: = {i = (i1,..., iN)  ∈ ZN |1 ≤ ik ≤ nk, k = 1,..., N}, with n = (n1,..., nN)  ∈ ZN. We propose a local linear estimator of qp extending to random fields with unspecified and possibly highly complex spatial dependence structure the quantile regression methods considered in the context of indepen-dent samples or time series. Under mild regularity assumptions, we obtain a Bahadur representation for the estimators of qp and its first order derivatives, from which we establish consistency and asymptotic normality. The spatial process is assumed to satisfy general mixing conditions, generalizing classical time-series mixing concepts. The size of the rectangular domain In is allowed to tend to infinity at different rates depending on the direction in ZN (non-isotropic asymptotics). The method provides much richer information than the mean regression approach considered in most spatial modelling techniques

Marc Hallin

Zudi Lu

Keming Yu

CiteSeerX

Local linear spatial quantile regression

Brunel University Research Archive

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Let {(Yi,Xi), i ∈ ZN} be a stationary real-valued (d + 1)-dimensional spatial processes. Denote by x → qp(x), p ∈ (0,1), x ∈ Rd, the spatial quantile regression function of order p, characterized by P{Yi ≤ qp(x)|Xi = x}  = p. Assume that the process has been observed over an N-dimensional rectangular domain of the form In: = {i = (i1,..., iN)  ∈ ZN |1 ≤ ik ≤ nk, k = 1,...,N}, with n = (n1,..., nN)  ∈ ZN. We propose a local linear estimator of qp. That estimator extends to random fields with unspecified and possibly highly complex spatial dependence structure, the quantile regression methods considered in the context of independent samples or time series. Under mild regularity assumptions, we obtain a Bahadur representation for the estimators of qp and its first-order derivatives, from which we establish consistency and asymptotic normality. The spatial process is assumed to satisfy general mixing conditions, generalizing classical time series mixing concepts. The size of the rectangular domain In is allowed to tend to infinity at different rates depending on the direction in ZN (non-isotropic asymptotics). The method provides much richer information than the mean regression approach considered in most spatial modelling techniques

Hallin, Marc

Yu, Keming

Lu, Zudi

DI-fusion

Crossref

Let {(Y i, X i), i ∈ ℤ n} be a stationary real-valued (d + 1)-dimensional spatial processes. Denote by x → qp(x). P ∈ (0,1), x ∈ ℝ d, the spatial quantile regression function of order p, characterized by P{Y i[≤ qp(x)|X i=x} = p. Assume that the process has been observed over an N-dimensional rectangular domain of the form I n : = {i = (i 1...,i N) ∈ ℤ N|1 ≤ k ≤n k, k= l,...,N}, with n = (n 1.....n N) ∈ℤ N. We propose a local linear estimator of q p. That estimator extends to random fields with unspecified and possibly highly complex spatial dependence structure, the quantile regression methods considered in the context of independent samples or time series. Under mild regularity assumptions, we obtain a Bahadur representation for the estimators of q p and its first-order derivatives, from which we establish consistency and asymptotic normality. The spatial process is assumed to satisfy general mixing conditions, generalizing classical time series mixing concepts. The size of the rectangular domain I n is allowed to tend to infinity at different rates depending on the direction in ℤ N (non-isotropic asymptotics). The method provides much richer information than the mean regression approach considered in most spatial modelling techniques. © 2009 ISI/BS.Marc Hallin, Zudi Lu, and Keming Yuhttp://projecteuclid.org/euclid.bj/125146327

Hallin, M.

Lu, Z.

Yu, K.

Adelaide Research &amp; Scholarship

Southampton (e-Prints Soton)

http://www.e-publications.org/ims/submission/index.php/BEJ/user/submissionFile/1558?confirm=95cdbe05

Local linear spatial quantile regression

Abstract

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DI-fusion

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Southampton (e-Prints Soton)

Local linear spatial quantile regression

Abstract

Similar works

Full text

Available Versions

CiteSeerX

Brunel University Research Archive

CiteSeerX

DI-fusion

Crossref

Adelaide Research &amp; Scholarship

Southampton (e-Prints Soton)

Adelaide Research & Scholarship