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European Journal of Applied Physiology
Published in: European Journal of Applied Physiology 3-4/2003

01-10-2003 | Original Article

Energy balance of human locomotion in water

Authors: D. Pendergast, P. Zamparo, P. E. di Prampero, C. Capelli, P. Cerretelli, A. Termin, A. Craig Jr., D. Bushnell, D. Paschke, J. Mollendorf

Published in: European Journal of Applied Physiology | Issue 3-4/2003

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Abstract

In this paper a complete energy balance for water locomotion is attempted with the aim of comparing different modes of transport in the aquatic environment (swimming underwater with SCUBA diving equipment, swimming at the surface: leg kicking and front crawl, kayaking and rowing). On the basis of the values of metabolic power (Ė), of the power needed to overcome water resistance ( d) and of propelling efficiency (η P= d/ tot, where tot is the total mechanical power) as reported in the literature for each of these forms of locomotion, the energy cost per unit distance (C=Ė/v, where v is the velocity), the drag (performance) efficiency (η d= d/Ė) and the overall efficiency (η o= tot/Ė=η d P) were calculated. As previously found for human locomotion on land, for a given metabolic power (e.g. 0.5 kW=1.43 l·min−1 O2) the decrease in C (from 0.88 kJ·m−1 in SCUBA diving to 0.22 kJ·m−1 in rowing) is associated with an increase in the speed of locomotion (from 0.6 m·s−1 in SCUBA diving to 2.4 m·s−1 in rowing). At variance with locomotion on land, however, the decrease in C is associated with an increase, rather than a decrease, of the total mechanical work per unit distance (W tot, kJ·m−1). This is made possible by the increase of the overall efficiency of locomotion o= tot/Ė=W tot /C) from the slow speeds (and loads) of swimming to the high speeds (and loads) attainable with hulls and boats (from 0.10 in SCUBA diving to 0.29 in rowing).
Literature
Abbott AV, Brooks AN, Wilson DG (1995) Human-powered watercraft. In: Abbott AV, Wilson DG (eds) Human-powered vehicles. Human Kinetics, Champaigin, Ill., pp 49–67
Alexander R McN (1983) Motion in fluids. In: Animal mechanics. Blackwell Scientific, Oxford, pp 183–233
Alexander R McN (2003) Principles of animal locomotion. Princeton University Press, Princeton, N.J., pp 249–287
Berger MA, Hollander AP, De Groot G (1997) Technique and energy losses in front crawl swimming. Med Sci Sports Exerc 29:1491–1498PubMed
Capelli C, Donatelli C, Moia C, Valier C, Rosa G, di Prampero PE (1990) Energy cost and efficiency of sculling a venetian Gondola. Eur J Appl Physiol 60:175–178
Capelli C, Zamparo P, Gigalotto A, Francescato MP, Soule RG, Termin B, Pendergast DR, di Prampero PE (1995) Bioenergetics and biomechanics of front crawl swimming. J Appl Physiol 78(2):674–679PubMed
Capelli C, Pendergast DR, Termin B (1998) Energetics of swimming at maximal speeds in humans. Eur J Appl Physiol 78:385–393CrossRef
Celentano F, Cortili G, di Prampero PE, Cerretelli P (1974) Mechanical aspects of rowing. J Appl Physiol. 36:642–647
Craig AB Jr, Pendergast DR (1979) Relationships of stroke rate, distance per stroke, and velocity in competitive swimming. Med Sci Sports Exerc 11(3):278–283
Dal Monte A, Komor A (1989) Rowing and sculling mechanics. In: Vaughan CL (ed) Biomechanics of sport. CRC Press, Boca Raton, Fla., pp 53–120
Daniel T (1991) Efficiency in aquatic locomotion: limitations from single cells to animals. In: Blake RW (eds) Efficiency and economy in animal physiology. Cambridge University Press, Cambridge, pp 83–95
di Prampero PE, Cortili G, Celentano F, Cerretelli P (1971) Physiological aspect of rowing. J Appl Physiol 31:853–857PubMed
di Prampero PE, Pendergast DR, Wilson DR, Rennie DW (1974) Energetics of swimming in man. J Appl Physiol 37(1):1–5PubMed
Fenn WO (1930) Frictional and kinetic factors in the work of sprint running. Am J Physiol 92:583–611
Hagerman FC (2000) Physiology of competitive rowing. In: Garrett WE, Kirkendall DT (eds) Exercise and sport science. Lippincott Williams and Wilkins, Philadelphia, pp 843–874
Lighthill MJ (1975) Hydrodynamics of aquatic animal propulsion. In: Mathematical biofluidodynamics. Society for Industrial and Applied Mathematics, Philadelphia
Martin RB, Yeater RA, White MK (1980) A simple analytical model for the crawl stroke. J Biomech 14:539–548
Minetti AE (1998) A model equation for the prediction of mechanical internal work of terrestrial locomotion. J Biomech 31:463–468PubMed
Minetti AE, Pinkerton J, Zamparo P (2001) Form bipedalism to bicyclism: evolution in energetics and biomechanics of historical bicycles. Proc R Soc Lond B 268:1351–1360CrossRefPubMed
Pendergast DR, di Prampero PE, Craig AB Jr, Wilson DR, Rennie DW (1977) Quantitative analysis of the front crawl in men and women. J Appl Physiol: 43(3):475–479
Pendergast DR, Bushnell D, Wilson DR, Cerretelli P (1989) Energetics of kayaking. Eur J Appl Physiol 59:342–350
Pendergast DR, Tedesco M, Nawrocki DM, Fisher NM (1996) Energetics of underwater swimming with SCUBA. Med Sci Sports Exerc 28:573–580PubMed
Samimy S (2002) A theoretical and experimental analysis of diver and fin performance in underwater swimming. Masters Thesis, Department of Mechanical Engineering, University of New York at Buffalo, Buffalo, N.Y.
Sanders RH, Cappaert J, Devlin RK (1995) Wave characteristics of butterfly swimming. J Biomech 28:9–16PubMed
Sargeant AJ, Jones DA (1995) The significance of motor unit variability in sustaining mechanical output of muscle. In: Gandevia S et al. (eds) Neural and neuromuscular aspects of muscle fatigue. Plenum, New York, pp 323–338
Secher NH (1993) Physiological and biomechanical aspects of rowing. Sports Med 15:24–42PubMed
Termin B, Pendergast DR (2001) Training using the stroke frequency-velocity relationship to combine biomechanical and metabolic paradigms. J Swim Res 14:9–17
Toussaint HM, Beek PJ (1992) Biomechanics of competitive front crawl swimming. Sports Med 13:8–24PubMed
Toussaint HM, Beelen A, Rodenburg A, Sargent AJ, de Groot G, Hollander AP, van Ingen Schenau GJ (1988) Propelling efficiency of front crawl swimming. J Appl Physiol 65:2506–2512PubMed
Toussaint HM, Janssen T, Kluft M (1991) Effect of propelling surface size on the mechanics and energetics of front crawl swimming. J Biomech 24:205–211PubMed
Woledge RC, Curtin NA, Homsher E (1985) Energetic aspects of muscle contraction. Academic, London
Zamparo P (2003) Optimization and transmission efficiency in human locomotion, Doctoral Thesis, Department of Exercise and Sport Sciences, Manchester Metropolitan University, UK
Zamparo P, Antonutto G, Capelli C, Francescato MP, Girardis M, Sangoi R, Soule RG, Pendergast DR (1996) Effects of body size, body density, gender and growth on underwater torque. Scand J Med Sci Sports 6:273–280PubMed
Zamparo P, Capelli C, Guerrini G (1999) Energetics of kayaking at submaximal and maximal speeds. EurJ Appl Physiol 80:542–548CrossRef
Zamparo P, Capelli C, Cautero M, di Nino A (2000) Energy cost of front-crawl swimming at supra-maximal speeds and underwater torque in young swimmers. Eur J Appl Physiol 83:487–491CrossRefPubMed
Zamparo P, Pendergast DR, Termin B, Minetti AE (2002) How fins affect the economy and efficiency of human swimming. J Exp Biol 205:2665–2676PubMed
Metadata
Title
Energy balance of human locomotion in water
Authors
D. Pendergast
P. Zamparo
P. E. di Prampero
C. Capelli
P. Cerretelli
A. Termin
A. Craig Jr.
D. Bushnell
D. Paschke
J. Mollendorf
Publication date
01-10-2003
Publisher
Springer-Verlag
Published in
European Journal of Applied Physiology / Issue 3-4/2003
Print ISSN: 1439-6319
Electronic ISSN: 1439-6327
DOI
https://doi.org/10.1007/s00421-003-0919-y

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