Spatial Statistics IV Stat 518 Sp08. Recall Method of moments: square of all pairwise differences, smoothed over lag bins Problems: Not necessarily a.

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Presentation transcript:

Spatial Statistics IV Stat 518 Sp08

Recall Method of moments: square of all pairwise differences, smoothed over lag bins Problems: Not necessarily a valid variogram Not very robust Estimation of variograms

A robust empirical variogram estimator (Z(x)-Z(y)) 2 is chi-squared for Gaussian data Fourth root is variance stabilizing Cressie and Hawkins:

Least squares Minimize Alternatives: fourth root transformation weighting by 1/  2 generalized least squares

Maximum likelihood Z~N n ( ,  )  =  [  (s i -s j ;  )] =  V(  ) Maximize and  maximizes the profile likelihood

Parana data ml ls

A peculiar ml fit

Some more fits

All together now...

Geometric anisotropy If we have an isotropic covariance (circular isocorrelation curves). If for a linear transformation A, we have geometric anisotropy (elliptical isocorrelation curves). General nonstationary correlation structures are typically locally geometrically anisotropic.

The deformation idea In the geometric anisotropic case, write where f(x) = Ax. This suggests using a general nonlinear transformation. Usually d=2 or 3. G-plane D-space We do not want f to fold. Do a Bayesian implementation using thin plate splines

California ozone

Posterior samples