Abstract
For a general class of stationary random fields we study asymptotic properties of the discrete Fourier transform (DFT), periodogram, parametric and nonparametric spectral density estimators under an easily verifiable short-range dependence condition expressed in terms of functional dependence measures. We allow irregularly spaced data which is indexed by a subset $\Gamma $ of $\mathbb{Z}^{d}$. Our asymptotic theory requires minimal restriction on the index set $\Gamma $. Asymptotic normality is derived for kernel spectral density estimators and the Whittle estimator of a parameterized spectral density function. We also develop asymptotic results for a covariance matrix estimate.
Highlights
Analysis of irregularly spaced data has been attracting considerable attention from researchers in various fields, ranging from environmental science to economics
The origin of irregular data is the limit theorem for random fields with continuous parameter where the sets of integration in the limit theorems approach to infinity in Van Hove sense, see for example, Ivanov and Leonenko (2012)
A nonparametric or a frequency domain approach was considered by Fuentes (2007) which revolves around the assumption that the sampled locations are fixed and not random
Summary
Analysis of irregularly spaced data has been attracting considerable attention from researchers in various fields, ranging from environmental science to economics. Spectral domain methods to approximate the Gaussian likelihood for irregularly spaced datasets were proposed by Matsuda and Yajima (2009) where the sampled locations are assumed random with a particular distribution having a continuous density function. Their non-parametric and parametric estimators of the spectral density function of the underlying random fields are similar to those in classical time series analysis. We begin by finding asymptotic results for the discrete Fourier transform (DFT) for irregularly spaced random fields, and study the asymptotic properties of the spectral density estimates.
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