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Sports Medicine
Published in: Sports Medicine 4/2010

01-04-2010 | Review Article

Match Analysis and the Physiological Demands of Australian Football

Authors: Mr Adrian J. Gray, David G. Jenkins

Published in: Sports Medicine | Issue 4/2010

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Abstract

Australian Football, the most popular football code in Australia, is a contact sport played by two teams of 18 players who contest play over four 20-minute quarters; the object of the game is to score the most points through goal kicking. Sixteen professional senior sides compete against each other in the Australian Football League (AFL) and, similar to other football codes, game demands at the elite level in the AFL have changed considerably in recent years. Early time-motion analysis studies highlighted the long periods of time players spent in low intensity activities (standing and walking). While recent studies utilizing global positioning systems (GPS) technology are somewhat in agreement with earlier findings, available evidence suggests that the game is getting faster. For example, ‘playing on’ after a mark (a feature of the game where players who catch the ball on the full from a kick longer than 15m are awarded a free kick) is now much quicker. Indeed, rule changes in recent years have increased the flow and speed of the game; there has been a reduction in the time taken for umpires to restart play, and for players to kick-in (after the opposition kicks a behind) or take a set shot at goal. Nomadic players (a broad term for midfielders and ruckmen because they follow play over the entire playing field) cover slightly greater distances (12 310 m) than both forwards (11 920 m) and backs (11 880 m) in a game. Compared with players in other positions, midfielders are consistently found to spend the most time at higher intensities (running and sprint efforts with movement velocities >4.44m/sec), complete more high intensity efforts (~98 per game), sustain them for longer and have shorter recovery periods between high intensity exercise bouts (~90 seconds on average). ‘Ruckmen’ have similar but less intense running profiles, while forwards and backs generally have less game involvement but have a more intermittent running profile (longer recovery periods with shorter duration high intensity exercise bouts and less time spent in constant pace running). Endurance fitness remains very important for players at the elite level of competition, as does upper and lower body strength and power. In addition, given the increasing speed at which Australian Football is now played, repeated sprint ability of players is arguably more important now than it was in previous years. There are no significant differences in these measures between playing position. Similarly, speed over 10–40m does not appear to differ between playing position. Establishing the reliability of distance and velocity-derived GPS data in highly specific game-related activities is needed; once achieved, GPS data have the potential to accurately inform coaches of the position-specific demands on their players and to drive the development of training practices that reflect the changing demands of the game.
Footnotes
1
Rovers or ruck rovers are now known as ruckmen. Followers typically ‘follow play’ across the field and are one of the midfield positions.
 
Literature
1.
Norton KI, Craig NP, Olds TS. The evolution of Australian Football. J Sci Med Sport 1999; 2 (4): 389–404PubMedCrossRef
2.
Orchard J, Seward H. AFL injury report: season 2007. Melbourne (VIC): Australian Football League, 2008
3.
Hoskins WT, Pollard H. Injuries in Australian rules football: a review of the literature. Australas Chiropr Osteopathy 2003; 11 (2): 49–56PubMed
4.
Stewart B. Boom time football, 1946–1975. In: Hess R, Stewart B, editors. More than a game: the real story of Australian rules football. Carlton (VIC): Melbourne University Press, 1998: 165–99
5.
AFL. Laws of Australian Football 2008. Melbourne (VIC): Australian Football League, 2008
6.
Nettleton B, Sandstrom ER. Skill and conditioning in Australian Rules Football. Aust J Phys Educ 1963; 29: 17–30
7.
Jaques TD, Pavia GR. An analysis of the movement patterns of players in an Australian Rules league football match. Aust J Sports Med 1974; 5 (10): 10–21
8.
Pyke FS, Smith RS. Football: the scientific way. Perth (WA): The University of Western Australia Press, 1975
9.
Hahn A, Taylor N, Hunt B, et al. Physiological relationships between training activities and match play in Australian Football rovers. Sports Coach 1979; 3 (3): 3–8
10.
McKenna MJ, Patrick JD, Sandstrom ER. Computer-video analysis of activity patterns in Australian Rules Football. In: Reilly T, editor. Science and football. London: Routledge, 1988
11.
Schokman P, Sparrow WA, Le Rossignol P. The use of a movement and skills analysis system to measure player performances in Australian Football: an intervention case study. Melbourne (VIC): Australian Football League, 2003
12.
Dawson B, Hopkinson R, Applby B, et al. Player movement patterns and game activities in the Australian Football League. J Sci Med Sport 2004; 7 (3): 278–91PubMedCrossRef
13.
Anderson A. AFL annual report: football operations. Melbourne (VIC): Australian Football League, 2005
14.
Norton KI. Laws of Australian Football discussion paper. Melbourne (VIC): Australian Football League, 2007
15.
Wisbey B, Montgomery P. Quantifying AFL player game demands using GPS tracking. Florey (ACT): FitSense Australia, 16–7
16.
Wisbey B, Montgomery P. Quantifying changes in AFL game demands using GPS tracking. Florey (ACT): Fit-Sense Australia, 2007
17.
Wisbey B, Montgomery P, Pyne DB. Quantifying changes in AFL player game demands using GPS tracking: 2007 AFL season. Florey (ACT): FitSense Australia, 2008
18.
Wisbey B, Rattray B, Pyne DB. Quantifying changes in AFL player game demands using GPS tracking: 2008 AFL season. Florey (ACT): FitSense Australia, 2008
19.
Champion Data Game Statistics. Melbourne (VIC): Australian Football League, 2009
20.
Norton K. Modeling the effect of a restriction on the number of interchanges in the AFL. Melbourne (VIC): Australian Football League, 2007
21.
Edgecomb SJ, Norton KI. Comparison of global positioning and computer-based tracking systems for measuring player movement distance during Australian Football. J Sci Med Sport 2006; 9 (1): 25–32PubMedCrossRef
22.
Macleod H, Morris J, Nevill A, et al. The validity of a nondifferential global positioning system for assessing player movement patterns in field hockey. J Sports Sci 2009; 27 (2): 121–8PubMedCrossRef
23.
Townshend AD, Worringham CJ, Stewart IB. Assessment of speed and position during human locomotion using nondifferential GPS. Med Sci Sports Exerc 2008; 40 (1): 124–32PubMed
24.
Witte TH, Wilson AM. Accuracy of non-differential GPS for the determination of speed over ground. J Biomech 2004; 37 (12): 1891–8PubMedCrossRef
25.
Burgess D, Naughton G. Quantifying the gap between under 18 and senior AFL football [abstract]. J Sci Med Sport 2003; 6 (4): 525
26.
Gabbett TJ, King T, Jenkins D. Applied physiology of rugby league. Sports Med 2008; 38 (2): 119–38PubMedCrossRef
27.
Spencer M, Bishop D, Dawson B, et al. Physiological and metabolic responses of repeated-sprint activities. Sports Med 2005; 35 (12): 1025–44PubMedCrossRef
28.
Karvonen J, Vuorimaa T. Heart rate and exercise intensity during sports activities: practical application. Sports Med 1988; 5 (5): 303–12PubMedCrossRef
29.
30.
Stagno KM, Thatcher R, van Someren KA. A modified TRIMP to quantify the in season training load of team sport players. J Sports Sci 2007; 25 (6): 629–34PubMedCrossRef
31.
Buttifant D. Physiological and performance characteristics of Australian Football League players. J Sports Sci 1999; 17: 808–9
32.
Young WB, Newton RU, Doyle TLA, et al. Physiological and anthropometric characteristics of starters and nonstarters and playing positions in elite Australian Rules Football: a case study. J Sci Med Sport 2005; 8 (3): 333–45PubMedCrossRef
33.
Keogh J. The use of physical fitness scores and anthropometric data to predict selection in an elite under 18 Australian Rules football team. J Sci Med Sport 1999; 2 (2): 125–33PubMedCrossRef
34.
Pyne DB, Gardner AS, Sheehan K, et al. Fitness testing and career progression in AFL football. J Sci Med Sport 2005; 8 (3): 321–32PubMedCrossRef
35.
Pyne DB, Gardner AS, Sheehan K, et al. Positional differences in fitness and anthropometric characteristics in Australian Football. J Sci Med Sport 2006; 9 (1-2): 143–50PubMedCrossRef
36.
Young WB, Pryor L. Relationship between pre-season anthropometric and fitness measures and indicators of playing performance in elite junior Australian Rules Football. J Sci Med Sport 2007; 10 (1): 110–8PubMedCrossRef
37.
Krustrup P, Mohr M, Amstrup T, et al. The Yo-Yo intermittent recovery test: physiological response, reliability and validity. Med Sci Sports Exerc 2003; 35 (4): 697–705PubMedCrossRef
38.
Williams C, Reid RM, Coutts R. Observations on the aerobic power of university rugby players and professional soccer players. Br J Sports Med 1973; 7: 390–1CrossRef
39.
Boyle PM, Mahoney CA, Wallace W. The competitive demands of elite male field hockey. J Sports Med Phys Fitness 1994; 34: 235–41PubMed
40.
Duthie G, Pyne DB, Hooper S. Applied physiology and game analysis of rugby union. Sports Med 2003; 33 (13): 973–91PubMedCrossRef
41.
Young WB, Russell A, Burge P, et al. The use of sprint tests for assessment of speed qualities of elite Australian Rules footballers. Int J Sport Phys and Perf 2008; 3 (2): 199–206
42.
Pyne DB, Saunders PU, Montgomery PG, et al. Relationships between repeated sprint testing, speed, and endurance. J Strength Cond Res 2008; 22 (5): 1633–7PubMedCrossRef
43.
Bradley PS, Portas MD. The relationship between preseason range of motion and muscle strain injury in elite soccer players. J Strength Cond Res 2007; 21 (4): 1155–60PubMed
44.
Jansson E, Dudley GA, Norman B, et al. Relationship of recovery from intense exercise to the oxidative potential of skeletal muscle. Acta Phys Scand 1990; 139 (1-2): 147–52CrossRef
Metadata
Title
Match Analysis and the Physiological Demands of Australian Football
Authors
Mr Adrian J. Gray
David G. Jenkins
Publication date
01-04-2010
Publisher
Springer International Publishing
Published in
Sports Medicine / Issue 4/2010
Print ISSN: 0112-1642
Electronic ISSN: 1179-2035
DOI
https://doi.org/10.2165/11531400-000000000-00000

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