Exploring and modelling team performances of the Kaggle European Soccer database

Akl

et al. 2020

Sensors

Predicting the results of soccer competitions and the contributions of match attributes, in particular, has gained popularity in recent years. Big data processing obtained from different sensors, cameras and analysis systems needs modern tools that can provide a deep understanding of the relationship between this huge amount of data produced by sensors and cameras, both linear and non-linear data. Using data mining tools does not appear sufficient to provide a deep understanding of the relationship between the match attributes and results and how to predict or optimize the results based upon performance variables. This study aimed to suggest a different approach to predict wins, losses and attributes’ sensitivities which enables the prediction of match results based on the most sensitive attributes that affect it as a second step. A radial basis function neural network model has successfully weighted the effectiveness of all match attributes and classified the team results into the target groups as a win or loss. The neural network model’s output demonstrated a correct percentage of win and loss of 83.3% and 72.7% respectively, with a low Root Mean Square training error of 2.9% and testing error of 0.37%. Out of 75 match attributes, 19 were identified as powerful predictors of success. The most powerful respectively were: the Total Team Medium Pass Attempted (MBA) 100%; the Distance Covered Team Average in zone 3 (15–20 km/h; Zone3_TA) 99%; the Team Average ball delivery into the attacking third of the field (TA_DAT) 80.9%; the Total Team Covered Distance without Ball Possession (Not in_Poss_TT) 76.8%; and the Average Distance Covered by Team (Game TA) 75.1%. Therefore, the novel radial based function neural network model can be employed by sports scientists to adapt training, tactics and opposition analysis to improve performance.

Section: Introductionmentioning

confidence: 99%

Predicting Wins, Losses and Attributes’ Sensitivities in the Soccer World Cup 2018 Using Neural Network Analysis

Akl

et al. 2020

Sensors

“…The inclusion of diverse indicators, extracted from structured and unstructured data at a more or less granular level, allows for fine‐tuned hypothesis formulation and testing (Carpita, Ciavolino, & Pasca, 2019; Landers et al, 2016). Recent work has shown, for example, that studies that include a wider variety of behavioural indicators can more accurately and comprehensively predict personality traits than those with less varied data (Azucar, Marengo, & Settanni, 2018).…”

Section: Approaching a Modern Understanding Of Personality Datamentioning

confidence: 99%

“…Many symptoms of depression and other psychopathologies are already observable on social media using current methods (Birnbaum, Ernala, Rizvi, De Choudhury, & Kane, 2017; Guntuku, Yaden, Kern, Ungar, & Eichstaedt, 2017; Hassanpour, Tomita, DeLise, Crosier, & Marsch, 2019; Reece & Danforth, 2017; Stanton et al, 2017; Thorstad & Wolff, 2019); it would be a grave mistake to ignore the reduction in human suffering that could be afforded by faster and more accurate diagnosis and treatment. But a utilitarian framework such as this may be insufficient, not just because the distribution of winners and losers is dramatically uneven, but also because it conflicts with a Kantian view in which one does not use others as means to an end (Celie & Paris, 2019; Tunick, 2014). Privacy is fraught, for secrecy can destroy as well as elevate human dignity (Martin, 2019).…”

Section: The Personality Panoramamentioning

confidence: 99%

The Personality Panorama: Conceptualizing Personality through Big Behavioural Data

2020

Self Cite

Personality psychology has long been grounded in data typologies, particularly in the delineation of behavioural, life outcome, informant‐report, and self‐report sources of data from one another. Such data typologies are becoming obsolete in the face of new methods, technologies, and data philosophies. In this article, we discuss personality psychology's historical thinking about data, modern data theory's place in personality psychology, and several qualities of big data that urge a rethinking of personality itself. We call for a move away from self‐report questionnaires and a reprioritization of the study of behaviour within personality science. With big data and behavioural assessment, we have the potential to witness the confluence of situated, seamlessly interacting psychological processes, forming an inclusive, dynamic, multiangle view of personality. However, big behavioural data come hand in hand with important ethical considerations, and our emerging ability to create a ‘personality panopticon’ requires careful and thoughtful navigation. For our research to improve and thrive in partnership with new technologies, we must not only wield our new tools thoughtfully, but humanely. Through discourse and collaboration with other disciplines and the general public, we can foster mutual growth and ensure that humanity's burgeoning technological capabilities serve, rather than control, the public interest. © 2020 European Association of Personality Psychology

“…Furthermore, Ievoli et al (2021) used network indicators to model the probability of winning the game for a team. From a slightly different perspective, Carpita et al (2019) included the a priori evaluation of players' abilities (involving passing skills) in predicting the win, without using passing network information.…”

Section: Introductionmentioning

confidence: 99%

The role of passing network indicators in modeling football outcomes: an application using Bayesian hierarchical models

2021

Passes are undoubtedly the more frequent events in football and other team sports. Passing networks and their structural features can be useful to evaluate the style of play in terms of passing behavior, analyzing and quantifying interactions among players. The present paper aims to show how information retrieved from passing networks can have a relevant impact on predicting the match outcome. In particular, we focus on modeling both the scored goals by two competing teams and the goal difference between them. With this purpose, we fit these outcomes using Bayesian hierarchical models, including both in-match and network-based covariates to cover many aspects of the offensive actions on the pitch. Furthermore, we review and compare different approaches to include covariates in modeling football outcomes. The presented methodology is applied to a real dataset containing information on 125 matches of the 2016–2017 UEFA Champions League, involving 32 among the best European teams. From our results, shots on target, corners, and such passing network indicators are the main determinants of the considered football outcomes.