The penalty shot in soccer is one of the most exciting one-on-one contests in sport, where a single kick of the ball can decide major tournaments and multimillion-dollar prizes. Successful shooters must use power and accuracy to kick the ball beyond the goalkeeper’s reach and into the goal; conversely, goalkeepers must predict the shooter’s intent and move accurately to intercept the ball. Each player’s performance is constrained by biomechanical trade-offs, and success relies on selecting the best strategy to overcome these constraints in myriad situations. Thus, the soccer penalty provides an ideal study system to investigate how the strategies of two competing agents interact to determine success or failure.
The aim of this thesis was to quantify the trade-offs faced by shooters and goalkeepers during a soccer penalty, determine the strategies used to overcome them, and show how these strategies interact to affect the outcome. From these outcomes, I developed an optimality model that predicts the likelihood of success for different shooting strategies, accounting for the biomechanical trade-offs that constrain each player. The model can match individual shooters against individual goalkeepers to identify the shooting strategy with the best chance of success.
In Chapter 2, I quantified the trade-off between speed and accuracy when kicking a ball. As expected, shooting precision decreased as shot speed increased. I also found that the likely dispersion of shots around a target was dependent on target height, kick technique, and player left- or right-footedness. Aiming at a target off the ground decreased precision compared with a target on the ground, and kicks made with the side of the foot were more accurate, while those made with the top of the foot generated greater speeds. Right-footed players tended to miss above the target and to the right, or below the target and to the left, with the opposite true for left-footed players.
In Chapter 3, I identified a previously unknown trade-off between shot speed and unpredictability. Unpredictability is advantageous for a penalty-kicker because it makes the ball more difficult for the goalkeeper to defend. I found that goalkeepers were better able to predict the direction of fast side-foot shots compared with slow- or medium-paced side-foot shots. Furthermore, the direction of shots became easier to predict as the shooter’s kicking action neared contact with the ball. During a penalty, goalkeepers generally start to move toward a side of the goal before the kicker contacts the ball—thus, moving earlier gives them more time to move to reach and intercept a shot, while moving later increases the likelihood that they move in the correct direction. Ultimately, the likelihood that a goalkeeper moved in the correction direction was determined by an interaction between when they began to move and the speed and technique used to kick the ball.
A penalty shooter selects where to aim and how fast to kick the ball, and a goalkeeper decides when to initiate movement relative to the shooter’s kicking action. Yet each player can be deceptive, giving the impression of kicking or moving to one side of the goal while doing the opposite. In Chapter 4, I quantified the strategies used by both players, and identified elements of these strategies that interact to affect the outcome of penalty shots. I found that shooters usually aimed toward the lower extremities of the goal, kicking at sub-maximal speeds with a side-foot technique (mean = 23.5 ms⁻¹, SD = 1.9 ms⁻¹, min = 16 ms⁻¹, max = 30 ms⁻¹)—suggesting that shooters prioritise accuracy over speed. Though shooters occasionally tried to be deceptive, goalkeepers were not susceptible to this strategy. Goalkeepers tended to move to either side of the goal, on average, 0.19 s (SD = 0.15 s) before the shooter kicked the ball, though certain individuals moved consistently earlier or later. Faster penalty shots elicited earlier movement in goalkeepers, and were harder to save, even when they were within reach. In contrast with shooters, goalkeepers rarely used a deceptive strategy.
In Chapter 5, I constructed a model based on trade-offs for shooters and goalkeepers that could be used to predict the likelihood of success for any shooter strategy. I parameterised the model with results from Chapters 2-4, and found that in general, faster shots aimed closer to the ground give the best chance of scoring. Importantly, the model can be used to compete individual shooters and goalkeepers to identify the best shooting strategy for that specific matchup. Therefore, a shooter matched against a goalkeeper who tends to move early should shoot toward the centre of the goal; if matched against a goalkeeper who tends to move late, shooting toward the extremities of the goal is the best strategy, with the optimal target location in the horizontal dimension dependent on shot speed and kick technique.
Taken together, the results of this thesis indicate the outcome of a penalty shot in soccer is determined by a complex interaction between the shooter and goalkeeper strategies. For a shooter, whatever strategy they choose is subject to the inherent error involved when kicking a ball. However, with knowledge of the goalkeeper’s behaviour, they can select a strategy that directs the shot to regions of the goal unlikely to be defended.