The VARIOGRAM Procedure

Nested Models

When you try to represent an empirical semivariogram by fitting a theoretical model, you might find that using a combination of theoretical models results in a more accurate fit onto the empirical semivariance than using a single model. This is known as model nesting. The semivariance models that result as the sum of two or more semivariance structures are called nested models.

In general, a linear combination of permissible semivariance models produces a new permissible semivariance model. Nested models are based on this premise. You can include in a sum any combination of the models presented in Table 4. For example, a nested semivariance gamma Subscript z Baseline left-parenthesis bold-italic h right-parenthesis that contains two structures, one exponential gamma Subscript z comma normal upper E normal upper X normal upper P Baseline left-parenthesis bold-italic h right-parenthesis and one spherical gamma Subscript z comma normal upper S normal upper P normal upper H Baseline left-parenthesis bold-italic h right-parenthesis, can be expressed as

gamma Subscript z Baseline left-parenthesis bold-italic h right-parenthesis equals gamma Subscript z comma normal upper E normal upper X normal upper P Baseline left-parenthesis bold-italic h right-parenthesis plus gamma Subscript z comma normal upper S normal upper P normal upper H Baseline left-parenthesis bold-italic h right-parenthesis

If you have a nested model and a nugget effect, then the nugget effect c Subscript n is a single parameter that is considered jointly for all the nested structures.

Nested models, anisotropic models, and the nugget effect increase the scope of theoretical models available. You can find additional discussion about these concepts in the section Theoretical Semivariogram Models in ChapterĀ 74, The KRIGE2D Procedure.

Last updated: December 09, 2022