English

Regression and Classification by Zonal Kriging

Machine Learning 2018-12-12 v2 Machine Learning

Abstract

Consider a family Z={xi,yiZ=\{\boldsymbol{x_{i}},y_{i},1iN}1\leq i\leq N\} of NN pairs of vectors xiRd\boldsymbol{x_{i}} \in \mathbb{R}^d and scalars yiy_{i} that we aim to predict for a new sample vector x0\mathbf{x}_0. Kriging models yy as a sum of a deterministic function mm, a drift which depends on the point x\boldsymbol{x}, and a random function zz with zero mean. The zonality hypothesis interprets yy as a weighted sum of dd random functions of a single independent variables, each of which is a kriging, with a quadratic form for the variograms drift. We can therefore construct an unbiased estimator y(x0)=iλiz(xi)y^{*}(\boldsymbol{x_{0}})=\sum_{i}\lambda^{i}z(\boldsymbol{x_{i}}) de y(x0)y(\boldsymbol{x_{0}}) with minimal variance E[y(x0)y(x0)]2E[y^{*}(\boldsymbol{x_{0}})-y(\boldsymbol{x_{0}})]^{2}, with the help of the known training set points. We give the explicitly closed form for λi\lambda^{i} without having calculated the inverse of the matrices.

Cite

@article{arxiv.1811.12507,
  title  = {Regression and Classification by Zonal Kriging},
  author = {Jean Serra and Jesus Angulo and B Ravi Kiran},
  journal= {arXiv preprint arXiv:1811.12507},
  year   = {2018}
}

Comments

Technical Report

R2 v1 2026-06-23T06:26:12.082Z