Exploring the impact of bowling ball properties and performance through the use of technology: An analysis of bowling ball motion

Abstract

Bowling balls are traditionally drilled with three holes to enhance the grip of the bowler and roll it down the lane. The path of the ball may be either straight or curved, with the intention of knocking over the pins situated at the edge of the lane. Alterations in the trajectory of the ball lead to irregular pinfalls, ultimately affecting the player’s score. This research was initiated to investigate the characteristics of bowling balls (weights), with a focus on examining the motion of bowling balls in relation to various factors such as pocket entry angle, speed, and position on the boards, as well as the impact of different types of drilling on bowling-ball kinematics. The Powerhouse Blueprint software was utilized to simulate thirty-two (32) distinct types of drilling on four separate bowling balls. The arrangement of the drilling proved to have a substantial impact on the kinematic entry factors, as evidenced by the statistically significant result of p < 0.01. It is essential from a practical standpoint to comprehend the characteristics and movement of bowling balls to enhance performance and improve outcomes during tenpin bowling competitions.

Keywords

Recreational pinfalls strike trajectory entry angle tenpin bowling simulation symmetrical cores asymmetrical cores properties

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References

Cint. Malaysia: what sports do you regularly participate in? (Statista Research Department, Issue. S. R. Department, https://www.statista.com/statistics/562710/malaysia-kinds-of-sports-regularly-participated-in/(2018, accessed 15 April 2022)

Seiferheld

Frost

Østergaard

, et al. Full-body kinematics and vertical ground reaction forces in elite ten-pin bowling: a field study. Sensors 2023; 23: 8284.

Banerjee

McPhee

. A volumetric contact model to study the effect of lane friction and the radii of gyration on the “hook shot” in indoor bowling. Procedia Eng 2014; 72: 429–434.

Yang

Dominguez

, et al. Using physics simulations to find targeting strategies in competitive bowling. Epub ahead of print October 14, 2022. DOI: 10.48550/arXiv.2210.06753.

Hooper

. Mathematical modelling of the application of lane conditioner to a Tenpin bowling lane. Proc IMechE, Part P: J Sports Engineering and Technology. Epub ahead of print 30 December 2023. DOI: 10.1177/17543371231217021.

USBC. House ball or your own ball: what’s the difference?https://bowl.com/welcome/house-ball-or-your-own-ball-what-s-the-difference (2015, accessed 5 June 2022).

Carruba

. How to layout a bowling ball: dual angle layout technique, https://www.bowlingball.com/BowlVersity/how-to-layout-a-bowling-ball-dual-angle-layout-technique (2009, accessed 31 January 2023).

Stremmel

Ridenour

Sterbenz

. Identifying the critical factors that contribute to bowling ball motion on a bowling lane. Report, USA, 2008.

Inaba

Hakamada

Murata

. Influence of selection of release angle and speed on success rates of jump shots in basketball. In: 5th international congress on sport sciences research and technology support, 30–31 October 2017, pp.48–45. Funchal Madeira, Portugal: SCITEPRESS.

10.

Johnson

. The physics of bowling: how good bowlers stay off the straight and narrow. s.n: St. Louis, Missouri. (2012, accessed 18 July 2021).

11.

Carruba

. Bowling ball angle of entry, https://www.bowlingball.com/BowlVersity/bowling-ball-angle-of-entry (2020, accessed 24 March 2022).

12.

Mounts

. The best entry angle for getting more strikes on a bowling lane, https://mountsbowling.com/best-entry-angle-for-strikes/ (2019, accessed 30 September 2021)

13.

Bill

. Fitting and drilling a bowling ball. Houston, Texas: s.n, 1984

14.

Siefers

. Core properties, https://www.bowlingdigital.com/bowl/node/2097 (2007, accessed 23 December 2022).

15.

Carruba

. Light, solid, and high bowling pocket strikes, https://www.bowlingball.com/BowlVersity/light-solid-and-high-bowling-pocket-strikes (2013, accessed 18 September 2022).

16.

Hoskins

. Pin-to-PAP distance. Report, USA, 2017.

17.

Donald

Nicole

Ridenour

. Pin carry study. Las Vegas, Nevada: United States Bowling Congress, 2009. (accessed 18 January 2022).

18.

Vaughan

. The best long back-end bowling balls, https://www.sportsrec.com/sand-bowling-ball-vs-polished-bowling-ball-12102913.html (2011, accessed 13 January 2022).

19.

Gurkov

. Entry angle assessment, https://www.kegeltrainingcenter.com/ktc-magazine/2016/11/2/entry-angle-assessment (2016, accessed 16 April 2022).

20.

Fuss

. Design of an instrumented bowling ball and its application to performance analysis in tenpin bowling. Sports Eng 2009; 2: 97–110.

21.

Wickington

Linthorne

. Effect of ball weight on speed, accuracy, and mechanics in fast-bowling crickets Sports (Basel) 2017; 5: 18.