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Variograms/Covariances and their estimation
STAT 498B
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The exponential correlation
A commonly used correlation function is (v) = e–v/. Corresponds to a Gaussian process with continuous but not differentiable sample paths. More generally, (v) = c(v=0) + (1-c)e–v/ has a nugget c, corresponding to measurement error and spatial correlation at small distances. All isotropic correlations are a mixture of a nugget and a continuous isotropic correlation.
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The squared exponential
Using yields corresponding to an underlying Gaussian field with analytic paths. This is sometimes called the Gaussian covariance, for no really good reason. A generalization is the power(ed) exponential correlation function,
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The spherical Corresponding variogram nugget sill range
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The Matérn class where is a modified Bessel function of the third kind and order . It corresponds to a spatial field with –1 continuous derivatives =1/2 is exponential; =1 is Whittle’s spatial correlation; yields squared exponential.
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Some other covariance/variogram families
Name Covariance Variogram Wave Rational quadratic Linear None Power law
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Estimation of variograms
Recall Method of moments: square of all pairwise differences, smoothed over lag bins Problems: Not necessarily a valid variogram Not very robust
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A robust empirical variogram estimator
(Z(x)-Z(y))2 is chi-squared for Gaussian data Fourth root is variance stabilizing Cressie and Hawkins:
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Least squares Minimize Alternatives: fourth root transformation
weighting by 1/2 generalized least squares
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Maximum likelihood Z~Nn(,) = [(si-sj;)] = V() Maximize
and q maximizes the profile likelihood
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A peculiar ml fit
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Some more fits
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All together now...
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