Abstract
ABSTRACTBasketball games evolve continuously in space and time as players constantly interact with their teammates, the opposing team, and the ball. However, current analyses of basketball outcomes rely on discretized summaries of the game that reduce such interactions to tallies of points, assists, and similar events. In this article, we propose a framework for using optical player tracking data to estimate, in real time, the expected number of points obtained by the end of a possession. This quantity, called expected possession value (EPV), derives from a stochastic process model for the evolution of a basketball possession. We model this process at multiple levels of resolution, differentiating between continuous, infinitesimal movements of players, and discrete events such as shot attempts and turnovers. Transition kernels are estimated using hierarchical spatiotemporal models that share information across players while remaining computationally tractable on very large data sets. In addition to estimating EPV, these models reveal novel insights on players’ decision-making tendencies as a function of their spatial strategy. In the supplementary material, we provide a data sample and R code for further exploration of our model and its results.
Highlights
Basketball is a fast-paced sport, free-flowing in both space and time, in which players’ actions and decisions continuously impact their teams’ prospective game outcomes
There are several types of fouls and game situations for which fouls lead to free throws—for instance, shooting fouls, technical/flagrant fouls, clear path fouls, and fouls during the fouling team’s “bonus” period; modeling fouls presents additional complications relative to the other events we model in our expected possession value (EPV) model
Before analyzing EPV estimates, it is essential to check that such estimates are properly calibrated (Gneiting, Balabdaoui & Raftery 2007) and accurate enough to be useful to basketball analysts
Summary
Award W911NF-15-1-0172, an Amazon AWS Research Grant, and the Natural Sciences and Engineering Research Council of Canada. The authors would like to thank Alex Franks, Andrew Miller, Carl Morris, Natesh Pillai, and Edoardo Airoldi for helpful comments, as well as STATS LLC in partnership with the NBA for providing the optical tracking data. The computations in this paper were run on the Odyssey cluster supported by the FAS Division of Science, Research Computing Group at Harvard University
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