Most statistical methods within the field of spatial statistics developed independently and grew out of different areas of application, including mining engineering, agriculture and forestry (see Gelfand at al. 2010). As a consequence of its scattered history the field of spatial statistics is generally viewed as being comprised of three major branches (Cressie 1993):
In this section we focus on the branch of spatial point patterns.
The other branches of spatial statistics, continuous spatial variation and discrete spatial variation, are discussed elsewhere. Though these two branches can be roughly described as following:
Continuous spatial variation: In this field, often denoted as geostatistics, the spatial locations are treated as explanatory variables and the values attached to them as response variables. Many geostatistical methods were developed to predict values over a spatial region from observations at a finite set of locations. An example application is the computation of spatially continuous weather maps from spatially discrete observations on the ground.
Discrete spatial variation: In this branch of spatial statistics the observed entities form a tessellation of the study area, sometimes referred to as tiles, with no overlaps and no gaps. Examples include lattice data, pixel data, and areal unit data (including irregular areal units both in size and shape). The goals of inference for discrete spatial variation are explanation, smoothing and prediction rather than interpolation (Gelfand at al. 2010).
Citation
The E-Learning project SOGA-Py was developed at the Department of Earth Sciences by Annette Rudolph, Joachim Krois and Kai Hartmann. You can reach us via mail by soga[at]zedat.fu-berlin.de.
Please cite as follow: Rudolph, A., Krois, J., Hartmann, K. (2023): Statistics and Geodata Analysis using Python (SOGA-Py). Department of Earth Sciences, Freie Universitaet Berlin.