Predicting Wide Receiver Trajectories in American Football

Abstract

Predicting the trajectory of a wide receiver in the game of American football requires prior knowledge about the game (e.g., route trees, defensive formations) and an accurate model of how the environment will change over time (e.g., opponent reaction strategies, motion attributes of players). Our aim is to build a computational model of the wide receiver, which takes into account prior knowledge about the game and short-term predictive models of how the environment will change over time. While prior knowledge of the game is readily accessible, it is quite challenging to build predictive models of how the environment will change over time. We propose several models for predicting short-term motions of opponent players to generate dynamic input features for our wide receiver forecasting model. In particular, we model the wide receiver with a Markov Decision Process (MDP), where the reward function is a linear combination of static features (prior knowledge about the game) and dynamic features (short-term prediction of opponent players). Since the dynamic features change over time, we make recursive calls to an inference procedure over the MDP while updating the dynamic features. We validate our technique on a video dataset of American football plays. Our results show that more informed models that accurately predict the motions of the defensive players are better at forecasting wide receiver plays.