Characteristic function-based tests for spatial randomness

We introduce a new type of test for complete spatial randomness that applies to mapped point patterns in a rectangle or a cube of any dimension. This is the first test of its kind to be based on characteristic functions and utilizes a weighted L2-distance between the empirical and uniform characteristic functions. It is simple to calculate and does not require adjusting for edge effects. An efficient algorithm is developed to find the asymptotic null distribution of the test statistic under the Cauchy weight function. In a simulation, our test shows varying sensitivity to different levels of spatial interaction depending on the scale parameter of the Cauchy weight function. Tests with different parameter values can be combined to create a Bonferroni-corrected omnibus test, which is almost always more powerful than the popular L-test and the Clark-Evans test for detecting heterogeneous and aggregated alternatives, although less powerful than the L-test for detecting regular alternatives. The simplicity of empirical characteristic function makes it straightforward to extend our test to non-rectangular or sparsely sampled point patterns.