Algorithmically deconstructing shot locations as a method for shot quality in hockey

IF 1.1 Q3 SOCIAL SCIENCES, MATHEMATICAL METHODS

Journal of Quantitative Analysis in Sports Pub Date : 2020-10-10 DOI:10.1515/jqas-2020-0012

Devan G. Becker, D. Woolford, C. Dean

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引用次数: 2

Abstract

Abstract Spatial point processes have been successfully used to model the relative efficiency of shot locations for each player in professional basketball games. Those analyses were possible because each player makes enough baskets to reliably fit a point process model. Goals in hockey are rare enough that a point process cannot be fit to each player’s goal locations, so novel techniques are needed to obtain measures of shot efficiency for each player. A Log-Gaussian Cox Process (LGCP) is used to model all shot locations, including goals, of each NHL player who took at least 500 shots during the 2011–2018 seasons. Each player’s LGCP surface is treated as an image and these images are then used in an unsupervised statistical learning algorithm that decomposes the pictures into a linear combination of spatial basis functions. The coefficients of these basis functions are shown to be a very useful tool to compare players. To incorporate goals, the locations of all shots that resulted in a goal are treated as a “perfect player” and used in the same algorithm (goals are further split into perfect forwards, perfect centres and perfect defence). These perfect players are compared to other players as a measure of shot efficiency. This analysis provides a map of common shooting locations, identifies regions with the most goals relative to the number of shots and demonstrates how each player’s shot location differs from scoring locations.

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基于算法解构的冰球击球位置分析方法

摘要利用空间点过程成功地模拟了职业篮球比赛中每个球员投篮位置的相对效率。这些分析之所以成为可能，是因为每个球员都能投进足够多的球，从而可靠地符合得分过程模型。在曲棍球比赛中，进球是非常罕见的，以至于得分过程不能适合每个球员的进球位置，因此需要新的技术来获得每个球员的射门效率。使用log -高斯考克斯过程(LGCP)对2011-2018赛季每位至少投篮500次的NHL球员的所有投篮位置(包括进球)进行建模。每个玩家的LGCP表面都被视为图像，然后这些图像被用于无监督统计学习算法，该算法将图像分解为空间基函数的线性组合。这些基本函数的系数是比较玩家的一个非常有用的工具。为了整合进球，所有射门得分的位置都被视为“完美球员”，并使用相同的算法(进球进一步分为完美前锋、完美中锋和完美防守)。将这些完美球员与其他球员进行比较，作为射门效率的衡量标准。该分析提供了一个常见射门位置的地图，确定了相对于射门次数而言进球最多的区域，并展示了每个球员的射门位置与得分位置的不同之处。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Quantitative Analysis in Sports SOCIAL SCIENCES, MATHEMATICAL METHODS-

CiteScore

2.00

自引率

12.50%

发文量

期刊介绍： The Journal of Quantitative Analysis in Sports (JQAS), an official journal of the American Statistical Association, publishes timely, high-quality peer-reviewed research on the quantitative aspects of professional and amateur sports, including collegiate and Olympic competition. The scope of application reflects the increasing demand for novel methods to analyze and understand data in the growing field of sports analytics. Articles come from a wide variety of sports and diverse perspectives, and address topics such as game outcome models, measurement and evaluation of player performance, tournament structure, analysis of rules and adjudication, within-game strategy, analysis of sporting technologies, and player and team ranking methods. JQAS seeks to publish manuscripts that demonstrate original ways of approaching problems, develop cutting edge methods, and apply innovative thinking to solve difficult challenges in sports contexts. JQAS brings together researchers from various disciplines, including statistics, operations research, machine learning, scientific computing, econometrics, and sports management.