Fluid dynamics of cricket ball swing
Abstract
Swing describes the lateral deviation of a cricket ball in its trajectory towards the batsman. Conventional swing is effective with a new, or well-preserved, ball, and the fluid dynamics governing this phenomenon was first explained in 1957. In 2012, many test-match fast bowlers are able to swing, at high speed, an older ball in the reverse direction. This reverse swing of a ball aged under match conditions has never been explained fully. A cricket ball is asymmetric with six seams of 80–90 encircling stitches, protruding approximately 1 mm proud of the surface. Both conventional and reverse swings are a consequence of asymmetrical flow separation leading to a skewed wake and a net pressure force on the ball perpendicular to the flight trajectory. Here, experimental evidence is presented for the first time showing that the formation of a laminar separation bubble is the prominent flow feature creating the flow asymmetry for reverse swing. A new flow visualisation technique to capture the fluid dynamics of boundary-layer separation using an infrared camera is also introduced here.
Get full access to this article
View all access and purchase options for this article.
References
1. Lyttelton RA. The swing of a cricket ball. Discovery 1957; 18: 186–191.
2. Barton NG. On the swing of a cricket ball in flight. P Roy Soc Lond A Mat 1982; 379: 109–131.
3. Bentley K, Varty P, Proudlove M, et al. An experimental study of cricket ball swing. Imperial College Aero. Technical note 82-106, 1982.
4. Mehta RD, Bentley K, Proudlove M, et al. Factors affecting cricket ball swing. Nature 1983; 303: 787–788.
5. Prandtl L. Über Flüssigkeitsbewegung bei sehr kleiner reibung [On the motion of fluids of very small viscosity]. In: Verhandlungen des III internationalen Mathematiker-Kongresses (ed Krazer A), Heidelberg, Germany, 8–13 August 1904, pp.484–491. Leipzig, Teubner.
6. Brown W, Mehta RD. The seamy side of swing bowling. New Sci 1993; 139: 21–24.
7. Barrett RS, Wood DH. The theory and practice of reverse swing. Sports Coach 1996; 18: 28–30.
8. Sayers AT. On the reverse swing of a cricket ball – modelling and measurements. Proc IMechE, Part C: J Mechanical Engineering Science 2001; 215: 45–55.
9. Mehta RD. An overview of cricket ball swing. Sports Eng 2005; 8: 181–192.
10. Lock GD, Edwards S, Almond DP. Flow visualization experiments demonstrating the reverse swing of a cricket ball. Proc IMechE, Part P: J Sports Engineering and Technology 2010; 224: 191–199.
11. Grant C, Anderson A, Anderson JA. Cricket ball swing-the Cooke-Lyttleton theory revisited (Proceedings of the second international conference on the engineering of sport, Sheffield, UK, July 1998). In: Haake S (ed.) The engineering of sport. Oxford: Blackwell Science, pp.371–378.
12. Achenbach E. Experiments on the flow past spheres at high Reynolds numbers. J Fluid Mech 1972; 54(3): 565–575.
13. Achenbach E. The effects of surface roughness and tunnel blockage on the flow past spheres. J Fluid Mech 1974; 65(1): 113–125.
14. Taneda S. Visual observations of the flow past a sphere at Reynolds numbers between 104 and 106. J Fluid Mech 1977; 85(1): 187–192.
15. Houghton EL, Carpenter PW. Aerodynamics for engineering students. 4th ed. London, UK: Edward Arnold, 1993.
16. Fage A. Experiments on a sphere at critical Reynolds numbers. Aeronautical Research Committee reports and memoranda, no. 1766, 1936.
Cite
Cite
Cite
OR
Download to reference manager
If you have citation software installed, you can download citation data to the citation manager of your choice
Information, rights and permissions
Information
Published In
Article first published online: October 30, 2012
Issue published: September 2013
Keywords
Authors
Metrics and citations
Metrics
Journals metrics
This article was published in Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology.
View All Journal MetricsPublication usage*
Total views and downloads: 760
*Publication usage tracking started in December 2016
Publications citing this one
Receive email alerts when this publication is cited
Web of Science: 19 view articles Opens in new tab
Crossref: 11
- An examination of how fielding outcomes in international and franchise T20 and 50-over cricket are associated with bowling performances and field positions
- Impart backspin and pitch the ball up: strategies cricket fast bowlers can employ to generate late swing
- Identifying which factors impact bowling and batting performances during the “death” phase of an innings in international men’s 50-over cricket
- Seam or swing? Identifying the most effective type of bowling variation for fast bowlers in men’s international 50-over cricket
- How do athletes cause ball flight path deviation in high-performance interceptive ball sports? A systematic review
- Innovative Design, Analysis and Development Practices in Aerospace and Automotive Engineering
- Practical perspective of cricket ball swing
- Investigation and comparison of performance of some air gun projectiles with nose shape modifications
- Spin-bowling in cricket re-visited: model trajectories for various spin-vector angles
- Aerodynamics of a golf ball with grooves
- View More
Figures and tables
Figures & Media
Tables
View Options
Access options
If you have access to journal content via a personal subscription, university, library, employer or society, select from the options below:
I am signed in as:
View my profileSign out
I can access personal subscriptions, purchases, paired institutional access and free tools such as favourite journals, email alerts and saved searches.
loading institutional access options
IOM3 members can access this journal content using society membership credentials.
IOM3 members can access this journal content using society membership credentials.
Alternatively, view purchase options below:
Purchase 24 hour online access to view and download content.
Access journal content via a DeepDyve subscription or find out more about this option.
