Supervised Multiscale Dimension Reduction for Spatial Interaction Networks
This work addresses the need for interpretable dimension reduction in spatial interaction networks, which is incremental as it builds on existing methods with a new prior and application focus.
The authors tackled the problem of reducing dimensionality in spatial interaction network data by introducing spinlets, an empirical Bayes method that constructs a partitioning tree and refines predictors based on response relevance, resulting in compact vectorial representations and interpretable visualizations for applications like soccer analytics.
We introduce a multiscale supervised dimension reduction method for SPatial Interaction Network (SPIN) data, which consist of a collection of spatially coordinated interactions. This type of predictor arises when the sampling unit of data is composed of a collection of primitive variables, each of them being essentially unique, so that it becomes necessary to group the variables in order to simplify the representation and enhance interpretability. In this paper, we introduce an empirical Bayes approach called spinlets, which first constructs a partitioning tree to guide the reduction over multiple spatial granularities, and then refines the representation of predictors according to the relevance to the response. We consider an inverse Poisson regression model and propose a new multiscale generalized double Pareto prior, which is induced via a tree-structured parameter expansion scheme. Our approach is motivated by an application in soccer analytics, in which we obtain compact vectorial representations and readily interpretable visualizations of the complex network objects, supervised by the response of interest.