Characterisation of football trajectories for assessing flight performance

Ward, Matthew; Passmore, Martin A.; Spencer, A. J. M.; Tuplin, Simon; Harland, Andy R.

doi:10.1177/1754337118774414

Cited by 4 publications

(2 citation statements)

References 23 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It is well known that adding roughness to balls reduces their critical Reynolds number, which is why dimples and stitches help golf balls and baseballs, respectively, travel farther than if those balls were smooth. Similar results have been seen by many other researchers; see, for example, reference [9]. Note also from Figure 2 that Jabulani's drag crisis occurred at a larger Reynolds number, and hence a larger speed, than it did for Brazuca.…”

Section: Experimental Methods and Discussionsupporting

confidence: 89%

Influence of Surface Properties on Soccer Ball Trajectories

Goff

Hong

Asai

2020

The 13th Conference of the International Sports Engineering Association

View full text Add to dashboard Cite

In this paper, we summarize our recent research work on soccer balls. Employing wind tunnels and analyses of simulated trajectories, we have gained an understanding of how various surface features influence soccer ball aerodynamics. Wind tunnels provide aerodynamic coefficients for non-spinning soccer balls. The coefficients then help determine the trajectories of various simulated kicked balls. Surface features include panel texturing, seam width, and seam depth. We have determined that small changes in surface texturing can lead to hard-kicked soccer balls experiencing lateral deflections as large as 10%–20% of their horizontal ranges. We have also found that the critical Reynolds number for soccer balls is more strongly correlated with seam width than with seam depth.

show abstract

Section: Experimental Methods and Discussionsupporting

confidence: 89%

Influence of Surface Properties on Soccer Ball Trajectories

Goff

Hong

Asai

2020

The 13th Conference of the International Sports Engineering Association

View full text Add to dashboard Cite

show abstract

“…Passing is a major part of most ball related team sports such as rugby, soccer, handball or American Football. During the last forty years, researchers have tried to understand the physics of a pass with various ball shapes and under various conditions [1][2][3][4]. For most sports, the findings of the mentioned research and the given technology have led to the creation of passing or pitching machines that are used in the state of the art training of athletes (e.g., baseball and soccer).…”

Section: Introductionmentioning

confidence: 99%

Development and Verification of a Highly Accurate and Precise Passing Machine for American Football

Hollaus

Raschner

Mehrle

2020

The 13th Conference of the International Sports Engineering Association

View full text Add to dashboard Cite

Passing a ball is a central aspect in the game of American Football. However, current passing machines do not fulfill the high quality standards for adequate catch training. The goal was to realize a passing machine that could do precise and accurate passes in a fully automated way in order to create high quality automated catch training. Automation was carried out to a degree that the release angle in terms of azimuth and elevation, release velocity and the release spin of the ball could be controlled via a wireless device within a reasonable range. Additionally, a pass prediction model was developed to determine where the pass went to and which height to catch it by least squares fit of 225 sample points with a second order function (R2>0.99). Normalized precision and accuracy of the machine were verified in an experiment with precision being less than 1% and accuracy less than 3% for more than 90% of all relevant passes.

show abstract

The effect of surface geometry on the aerodynamic behaviour of a football

et al. 2023

View full text Add to dashboard Cite

Several studies have investigated the effect of surface features on the aerodynamic behaviour of a sphere or a football. Research on footballs typically compare real footballs with highly complex seam geometry and surface texture, making it difficult to identify which features influence the aerodynamic behaviour. This study commissioned many 3D printed footballs with regularly increasing seam length and surface texture to undertake a designed experiment to study these changes in a controlled fashion. Each ball was tested in a wind tunnel in non-spinning cases, or spinning about a vertical axis, at a range of speeds and key aerodynamic parameters were extracted from the data. Several methods were employed to characterise the roughness of each ball, and these roughness metrics were statistically tested for correlations with selected aerodynamic parameters. Using these relationships provides design guidance to football manufacturers to understand how modifying their surface geometry would influence the ball’s aerodynamic behaviour. In general, increasing the volume of roughness of the ball, measured as the change in volume of the ball introduced through seams or texture compared to a smooth sphere, decreased the critical Reynolds number. Balls with larger texture elements, particularly those with protrusive texture, had a much lower critical Reynolds number than other balls with the same absolute volumes of roughness. The post-critical drag coefficient did not significantly correlate with any of the roughness features of the balls. In a spinning case, the balls with high roughness generated a higher side force, this relationship plateaued at a certain level of roughness. The reverse Magnus behaviour changed significantly with the surface roughness; as the overall roughness volume of the ball increased, the Reynolds number at which the reverse Magnus changed to a conventional Magnus effect decreased. The large protrusive texture elements were effective at preventing a reverse Magnus effect from occurring at all in the tested Reynolds number range.

show abstract

Characterisation of football trajectories for assessing flight performance

Cited by 4 publications

References 23 publications

Influence of Surface Properties on Soccer Ball Trajectories

Influence of Surface Properties on Soccer Ball Trajectories

Development and Verification of a Highly Accurate and Precise Passing Machine for American Football

The effect of surface geometry on the aerodynamic behaviour of a football

Contact Info

Product

Resources

About