Summary
Cycling performance in human powered vehicles is affected by the interaction of a number of variables, including environment, mechanical and human factors. Engineers have generally focused on the design and development of faster, more efficient human-powered vehicles based on minimising aerodynamic drag, neglecting the human component. On the other hand, kinesiologists have examined cycling performance from a human perspective, but have been constrained by the structure of a standard bicycle. Therefore, a gap exists between research in the various disciplines. To maximise/optimise cycling performance in human-powered vehicles requires a bridging of this gap through interdisciplinary research.
Changes in different variables can affect the energy requirements of cycling. These variables include: (a) changes in body position, configuration, and orientation; (b) changes in seat to pedal distance; and (c) the interaction of workload, power output, and pedalling rate. Changes in these variables alter joint angles, muscle lengths, and muscle moment arm lengths, thus affecting the tension-length, force-velocity-power relationships of muhijoint muscles and the effectiveness of force production. This is ultimately manifested as a change in the energetics of cycling.
A large number of factors affect cycling performance in human-powered vehicles and a gap still exists between cycling research in various disciplines. To bridge this gap, if not completely close it, requires cooperation between disciplines and further interdisciplinary research.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Åstrand PO. Study of bicycle modifications using a motor driven treadmill-bicycle ergometer. Arbeitsphysiologie 15: 23–32, 1953
Åstrand PO, Rodahl K. Textbook of work physiology, 2nd ed., McGraw-Hill, New York, 1977
Banister EW, Jackson RC. The effect of speed and load changes on oxygen intake for equivalent power outputs during bicycle ergometry. Internationale Zeitschrift fur Angewandte Physiologie Einschliesslich 24: 284–290, 1967
Baz A. Optimization of man’s energy during underwater paddle propulsion. Ergonomics 22: 1105–1114, 1979
Benedict FG, Cathcart EP. Muscular work: a metabolic study with special reference to the efficiency of the human body as a machine, Cambridge University Press, New York, 1913
Bevegard S, Freyschuss U, Strandell T. Circulatory adaptation to, arm and leg exercise in supine and sitting position. Journal of Applied Physiology 21: 37–46, 1966
Bevegard S, Holmgren A, Jonsson B. The effect of body position on the circulation at rest and during exercise, with special reference to the influence on the stroke volume. Acta Physiologica Scandinavica 49: 279–298, 1960
Bevegard S, Holmgren A, Jonsson B. Circulatory studies in well trained athletes at rest and during heavy exercise, with special reference to stroke volume and the influence of body position. Acta Physiologica Scandinavica 57: 26–50, 1963
Bishop JM, Donald KW, Taylor SH, Wormald PN. Effect of supine leg exercise on the splanchnic A-V oxygen difference in normal subjects. Journal of Physiology 133: 9P, 1956
Bolourchi F, Hull ML, Measurement of rider induced loads during simulated bicycling. In Terauds & Barham (Eds) Biomechanics in sports II, pp. 178–198, Academic Press, San Diego, 1985
Boning D, Gonen Y, Maassen N. Relationship between work load, pedal frequency, and physical fitness. International Journal of Sports Medicine 5(2): 92–97, 1984
Boor P. Those magnificent machines. American Wheelmen 17(5): 22–23, 1981
Borysewicz E. Bicycle road racing, Velo-new Corporation, Brattleboro, Vermont, 1985
Brooke JD, Hoare J, Rosenrot P, Triggs R. Computerized system for measurement of force exerted within each pedal revolution during cycling. Physiology and Behavior 26(1): 139–143, 1981
Burke ER. Science of cycling, Human Kinetics Publishers, Champaign, 1986
Cafarelli E. Effect of contraction frequency on effort sensation during cycling at a constant resistance. Medicine and Science in Sports 10(4): 270–275, 1978
Carmichael JKS. The effect of cranklength on oxygen consumption when cycling at a constant work rate. Unpublished master’s thesis, Pennsylvania State University, 1981
Cavanagh PR, Kram R, The efficiency of human movement — a statement of the problem. Medicine and Science in Sports and Exercise 17: 304–308, 1985a
Cavanagh PR, Kram R. Mechanical and muscular factors affecting the efficiency of human movement. Medicine and Science in Sports and Exercise 17: 326–331, 1985b
Coast JR, Welch HG. Linear increase in optimal pedal rate with increased power output in cycle ergometry. European Journal of Applied Physiology 53(4): 339–342, 1985
Convertino VA, Goldwater DJ, Sandler H. Oxygen uptake kinetics of constant-load work: upright vs. supine exercise. Aviation Space Environmental Medicine 55(6): 501–506, 1984
Cornelius CJ, Seireg AA. Optimum human power. Soma 1(1): 21–29, 1986
Croisant PT. Efficiency of bicycle ergometer work at selected rates of limb movement for college women. Unpublished master’s thesis, University of Illinois at Urbana-Champaign, 1975
Croisant PT. Effect of pedal rate, brake load, and workrate on metabolic work and recovery. Doctoral dissertation, University of Illinois at Urbana-Champaign, 1979
Croisant PT, Boileau RA. Effect of pedal rate, brake load and power on metabolic responses to bicycle ergometer work. Ergonomics 27: 691–700, 1984
Cumming GR. Stroke volume during recovery from supine bicycle exercise. Journal of Applied Physiology 32: 575–578, 1972
Daly DJ, Cavanagh PR. Asymmetry in bicycle ergometer pedalling. Medicine and Science in Sports 8: 204–208, 1976
Davis RR, Hull ML. Measurement of pedal loading in bicycling: II. Analysis and results. Journal of Biomechanics 14(12): 857–872, 1981
Davis RR, Hull ML. Biomechanics of bicycling. In Terauds (Ed.) Biomechanics in sports, pp. 113–133, Academic Press, San Diego, 1982
Despires M. An electromyographic study of competitive road cycling conditions simulated on a treadmill. In Nelson & Morehouse (Eds) Biomechanics IV, pp. 349–355, University Park Press, Baltimore, 1974
Diaz RJ, Hagen RD, Wright JE, Horvath SM. Maximal submaximal exercise in different positions. Medicine and Science in Sports 10(3): 214–217, 1978
Dickhuth HH, Simon G, Heiss HW, Lehman M, Wybitul K. Comparative echocardiographic examinations in sitting and supine position at rest and during dynamic exercise. International Journal of Sports Medicine 2(3): 178–182, 1981
Dickinson S. The efficiency of bicycle-pedaling, as affected by speed and load. Journal of Physiology 67: 242–255, 1929
Dill DB, Seed JC, Marzulli FN. Energy expenditure in bicycle riding. Journal of Applied Physiology 7: 320–324, 1954
Drela M, Langford JS. Human-powered flight. Scientific American 253(5): 144–151, 1985
Ekelund LG. Circulatory and respiratory adaptation during prolonged exercise in the supine position. Acta Physiologica Scandinavica 68: 382–396, 1966
Ekelund LG. Circulatory and respiratory adaptation during prolonged exercise of moderate intensity in the sitting position. Acta Physiologica Scandinavica 69: 327–340, 1967a
Ekelund LG. Circulatory and respiratory adaptation during prolonged exercises. Acta Physiologica Scandinavica 70(Suppl. 292): 1–38, 1967b
Ericson MO, Nisell R. Efficiency of pedal forces during ergometer cycling. International Journal of Sports Medicine 9: 118–122, 1988
Ericson MO, Nisell R, Nemeth G. Joint motions of the lower limb during ergometer cycling. Journal of Orthopaedic and Sports Physical Therapy 26(1): 52–54, 1988
Faria IE, Cavanagh PR. The physiology and biomechanics of cycling. John Wiley & Sons, New York, 1978
Faria I, Dix C, Frazer C. Effect of body position during cycling on heart rate, pulmonary ventilation, oxygen uptake and work output. Journal of Sports Medicine and Physical Fitness 18(1): 49–56, 1978
Faria I, Sjojaard G, Bonde-Petersen F. Oxygen cost during different pedalling speeds for constant power output. Journal of Sports Medicine and Physical Fitness 22(3): 295–299, 1982
Gaesser GA, Brooks GA. Muscular efficiency during steady-rate exercise: effects of speed and work rate. Journal of Applied Physiology 38: 1132–1139, 1975
Galbo H, Pauley PE. Cardiac function during rest and supine cycling examined with a new noninvasive technique (CED). Journal of Applied Physiology 36: 113–117, 1974
Garry RC, Wishart GM. On the existence of a most efficient speed in bicycle pedalling, and the problem of determining human muscular efficiency. Journal of Physiology 72: 426–437, 1931
Girandola RN, Henry FM. Individual differences in heavy work endurance at 60, 70 and 84 rpm ergometer pedal speed. Research Quarterly 47(4): 647–656, 1976
Gollnick PD, Piehl K, Saltin B. Selective glycogen depletion pattern in human muscle fibers after exercise of varying intensity and at varying pedalling rates. Journal of Physiology 241: 45–57, 1974
Goto S, Toyoshima S, Hoshikawa T. Study of the integrated EMG leg muscles during pedaling of various loads, frequency, and equivalent power. In Komi (Ed.) Biomechanics V-A, pp. 246–252, University Park Press, Baltimore, 1976
Granath A, Jonsson B, Strandell T. Studies on the central circulation at rest and during exercise in the supine and sitting body position in old men: preliminary report. Acta Medica Scandinavica 169: 125–126, 1961
Granath A, Jonsson B, Strandell T. Circulation in healthy old men, studied by right heart catheterization at rest and during exercise in the supine sitting position. Acta Medica Scandinavica 176: 425–446, 1964
Gregor RJ. A biomechanical analysis of lower limb action during cycling at four different loads. Doctoral dissertation, Pennsylvania State University, 1976
Gregor RJ, Cavanagh PR. A biomechanical analysis of lower limb action during cycling at four different loads. Abstract. Medicine and Science in Sports 8(1): 57, 1976
Gregor RJ, Cavanagh PR, Lafortune M. Knee flexor moments during propulsion in cycling — a creative solution to Lombard’s paradox. Journal of Biomechanics 18(5): 307–316, 1985
Gregor RJ, Green D, Garhammer JJ. An electromyographic analysis of selected muscle activity in elite competitive cyclists. In Morecki et al. (Eds) Biomechanics VII-B, pp. 537–541, University Park Press, Baltimore, 1981
Gross AC, Kyle CR, Malewicki DJ. The aerodynamics of human-powered land vehicles. Scientific American 249(6): 142–152, 1983
Gueli D, Shephard RJ. Pedal frequency in bicycle ergometry. Canadian Journal of Applied Sports Sciences 1: 137–141, 1976
Gullbring B, Holmgren A, Sjostrand T, Strandell T. The effect of blood volume variations on the pulse rate in supine and upright positions and during exercise. Acta Physiologica Scandinavica 50: 62–71, 1960
Hagberg JM, Giese MD, Mullin JP. Effect of different gear ratios on the metabolic responses of competitive cyclists to constant load steady state work. Medicine and Science in Sports 7: 74, 1975
Hagberg JM, Giese MD, Schnieder RB. Comparison of three procedures for measuring V̇O2max of competitive cyclists. European Journal of Applied Physiology 39: 47–52, 1978
Hagberg JM, Mullin JP, Giese MD, Spitznagel E. Effect of pedalling rate on submaximal exercise responses of competitive cyclists. Journal of Applied Physiology 51: 447–451, 1981
Hamley EJ, Thomas V. Physiological and postural factors in the calibration of bicycle ergometer. Journal of Physiology 191: 55–57P, 1967
Henry EJ, DeMoor J. Metabolic efficiency of exercise in relation to work load at constant speed. Journal of Applied Physiology 2: 481–487, 1950
Hoes MJAJM, Binkhorst RA, Smeekes-Kuyl AEMC, Vissers ACA. Measurement of forces exerted on pedal and crank during work on a bicycle ergometer at different loads. Internationale Zeitschrift für Angewandte Physiologie Einselliesslick Arbeitsphysiologie 26: 33–42, 1968
Holmgren A, Jonsson B, Sjostrand T. Circulatory data in normal subjects at rest and during exercise in recumbent position, with special reference to the stroke volume at different work intensities. Acta Physiologica Scandinavica 49: 343–363, 1960
Holmgren A, Mossfeldt F, Sjostrand T, Strom G. Effect of training on work capacity, total hemoglobin, blood volume, heart volume and pulse rate in recumbent and upright postions. Acta Physiologica Scandinavica 50: 72–83, 1960
Houtz SJ, Fischer FJ. An analysis of muscle action and joint excursion during exercise on a stationary bicycle. Journal of Bone and Joint Surgery 41A(1): 123–131, 1959
Hugh-Jones P. The effect of seat position on the efficiency of bicycle pedaling. Journal of Physiology 106: 186–193, 1947
Hull ML, Davis RR. Measurement of pedal loading in bicycling: I. Instrumentation. Journal of Biomechanics 14(12): 843–855, 1981
Hull ML, Gonzalez HK. Bivariate optimization of pedalling rate and crank arm length in cycling. Journal of Biomechanics 21(10): 839–849, 1988
Hull ML, Gonzalez HK. Multivariable optimization of cycling biomechanics. In Kreighbaum et al. (Eds) Biomechanics in Sports VI, pp. 15–41, Montana State University, Bozeman, Montana, 1990
Hull ML, Gonzalez HK, Redfield R. Optimization of pedaling rate in cycling using a muscle stress-based objective function. International Journal of Sport Biomechanics 4: 1–20, 1988
Hull ML, Jorge M. A method for biomechanical analysis of bicycle pedalling. Journal of Biomechanics 18(9): 631–644, 1985
Inbar O, Dotan R, Trousil T, Dvir Z. The effect of bicycle crank-length variation upon power performance. Ergonomics 26(12): 1139–1146, 1983
Jorge M, Hull ML. Biomechanics of bicycle pedalling. In Terauds et al. (Eds) Sports biomechanics, pp. 233–246, Academic Publishers, California, 1984
Jordan L, Merrill EG. Relative efficiency as a function of pedalling rate for racing cyclists. Journal of Physiology 296: 49P–59P, 1979
Kamon E, Metz KF, Pandolf EG. Climbing and cycling with additional weights on the extremities. Journal of Applied Physiology 35: 367–370, 1973
Kirshner D. Aerodynamics vs. weight: quantifying the trade-off. Bike Tech 4(1): 5–9, 1985
Klimt F, Voigt GB. Studies for the standardisations of the pedal frequency and the crank length at the work on the bicycle-ergometer in children between 6 and 10 years of age. European Journal of Applied Physiology 33(4): 315–326, 1974
Knuttgen HG, Bonde-Petersen FB, Klausen K. Oxygen uptake and heart rate responses to exercise performed with concentric and eccentric muscle contractions. Medicine and Science in Sports 3: 1–5, 1971
Kroon H. The optimum pedaling rate. Bike Tech 2: 1–5, 1983
Kubicek F, Gaul G. Comparison of supine and sitting body position during a triangular exercise test. I. Experiences in health subjects. European Journal of Applied Physiology 36(4): 275–283, 1977
Kunstlinger U, Ludwig HG, Stegemann J. Force kinetics and oxygen consumption during bicycle ergometer work in racing cyclists and reference-group. International Journal of Sports Medicine 5: 118–119, 1984
Kyle CR. The aerodynamics of man powered land vehicles. Proceeding of the Seminar on Planning, Design, and Implementation of Bicycle Pedestrian Facilities, pp. 312–326, San Diego, California, 1974
Kyle CR. Aerodynamics the key to high speeds. Cycling 4693(8): 20–21, 1981
Kyle CR. Go with the flow: aerodynamics and cycling. Bicycling 23(4): 59–60, 62, 64–66, 1982
Kyle CR, Caiozzo VJ. Experiments in human ergometry as applied to the design of human powered vehicles. International Journal of Sports Biomechanics 2: 6–19, 1986
Kyle CR, Crawford C, Nadeau D. Factors affecting the speed of a bicycle, CSULB Engineering Report No. 73–1, California State University, Long Beach, 1973
Kyle CR, Crawford C, Nadeau D. What affects bicycle speed. Part I. Bicycling 5(7): 22–24, 1974
Kyle CR, Edelman WE. Man powered vehicle design criteria. In Sachs (Ed.) Proceedings of the Third International Conference of Vehicle System Dynamics, pp. 20–30, Swets & Zeitlinger, Amsterdam, 1975
Lafortune MA, Cavanagh PR. Force effectiveness during cycling. Abstract. Medicine and Science in Sports and Exercise 12(2): 95, 1980
Lafortune MA, Cavanagh PR. Effectiveness and efficiency during bicycle riding. In Matsui & Kobayashi (Eds) Biomechanics VII-B, pp. 928–936, Human Kinetics Publisher, Champaign, 1983
Lafortune MA, Cavanagh PR, Valiant GA, Burke ER. A study of the riding mechanics of elite cyclists. Abstract. Medicine and Science in Sports and Exercise 15(2): 113, 1983
Lollgen H, Graham T, Sjogaard G. Muscle metabolites, force, and perceived exertion bicycling at varying pedal rates. Medicine and Science in Sports and Exercise 12(5): 345–351, 1980
Malewicki DJ. Aerodynamics: who will win the DuPont Prize? Drag vs power at 65 mi/hr. Bike Tech 3(5): 1–8, 1984
Martin S. The annual assault on human powered speed records. Bike World 8: 34–37, 1979
McCartney N, Heigenhauser GJR, Sargent AJ, Jones NL. A constant-velocity cycle ergometer for the study of dynamic muscle function. Journal of Applied Physiology 55: 212–217, 1983
McKay GA, Banister EW. A comparison of maximum oxygen uptake determination by bicycle ergometry at various pedalling frequencies and by treadmill running at various speeds. European Journal of Applied Physiology 35: 191–200, 1976
ME Staff Report. Human-powered flight. Mechanical Engineering 106(9): 46–55, 1984
Merrill EG, White JA. Physiological efficiency of constant power output at varying pedal rates. Journal of Sports Sciences 2: 25–34, 1984
Metz LD, Moeinzadeh MH, White LR. Leg motion during standard and supine recumbent bicycle pedalling. Part II: Biomechanical observations and results. Journal of Biomechanics, in press, 1990
Metz LD, Moeinzadeh MH, White LR, Groppel JL. Biomechanical aspects of supine recumbent bicycles. In Adrian & Deutsch (Eds) Biomechanics: the 1984 Olympic Scientific Congress proceedings, pp. 289–295, Microfilm Publications, University of Oregon, Eugene, Oregon, 1986
Michielli DW, Stricevic M. Various pedaling frequencies at equivalent power outputs: effect on heart rate response. New York State Journal of Medicine 77: 744–746, 1977
Moffatt RJ, Stamford BA. Effects of pedalling rate changes on maximal oxygen uptake and perceived effort during bicycle ergometer work. Medicine and Science in Sports 10: 27–31, 1978
Montgomery S, Titlow LW, Johnson DJ. Estimates of maximal oxygen consumption from a stand-up bicycle test. Journal of Sport Medicine and Physical Fitness 18: 271–276, 1978
Nonweiler T. The air resistance of racing cyclist. Report 106, The College of Aeronautics, Cranfield, England, 1956
Nonweiler T. Power output of racing cyclists. Engineering 183(4757): 586, 1957
Nordeen KS. The effect of bicycle seat height variation upon oxygen consumption and both experimental and simulated lower limb kinematics. Unpublished master’s thesis, Pennsylvania State University, 1976
Nordeen KS, Cavanagh PR. Simulation of lower limb kinematics during cycling. In Komi (Ed.) Biomechanics V-B, pp. 26–33, University Park Press, Baltimore, 1976
Nordeen-Snyder KS. The effect of bicycle seat height variation upon oxygen consumption and lower limb kinematics. Medicine and Science in Sports 9: 113–117, 1977
Pandolf KB, Noble BJ. The effect of pedaling speed and resistance changes on perceived exertion for equivalent power outputs on the bicycle ergometer. Medicine and Science in Sports 5: 132–136, 1973
Patterson RP, Pearson JL. The influence of flyweight and pedalling frequency on the biomechanics and physiological responses to bicycle exercise. Ergonomics 26: 659–668, 1983
Pugh LGCE. The relation of oxygen intake and speed in competition cycling and comparative observations on the bicycle ergometer. Journal of Physiology 241: 795–808, 1974
Redfield R, Hull ML. Joint moments and pedalling rates in bicycling. In Terauds et al. (Eds) Sports biomechanics, pp. 247–258, Academic Press, San Diego, 1984
Redfield R, Hull, ML. On the relation between joint moments and pedalling rates at constant power in bicycling. Journal of Biomechanics 19(4): 317–329, 1986a
Redfield R, Hull ML. Prediction of pedal forces in bicycling using optimization methods. Journal of Biomechanics 19(7): 523–540, 1986b
Reeves JT, Grover RF, Filley GF, Blount SGJ. Circulatory changes in man during mild supine exercise. Journal of Applied Physiology 16: 279–282, 1961
Sargent AJ, Charters A, Davies CTM, Reeves ES. Measurement of forces applied and work performed in pedalling a stationary bicycle ergometer. Ergonomics 21: 49–53, 1978
Sargent AJ, Davies CTM. Forces applied to cranks of a bicycle ergometer during one- and two-leg cycling. Journal of Applied Physiology 42: 514–518, 1977
Seabury JJ, Adams WC, Ramsey MR. The influence of pedalling rate and power output on energy expenditure during bicycle ergometry. In Adams (Ed.) Studies of metabolic energy expenditure in bicycling, Report No. 75–2, Civil Engineering Department, University of California, Davis, 1975
Seabury JJ, Adams WC, Ramsey MR. Influence of pedalling rate and power output on energy expenditure during bicycle ergometry. Ergonomics 20: 491–498, 1977
Shennum PL, deVries HA. The effect of saddle height on oxygen consumption during bicycle ergometer work. Medicine and Science in Sports 8: 119–121, 1976
Simpson J. Proper crank arm lengths: resolution of the revolutions. Bike World 8(5): 29–31, 1979
Soden PD, Adeyefa BA. Forces applied to a bicycle during normal cycling. International Sports Sciences 1(9): 738–739, 1979a
Soden PD, Adeyefa BA. Forces applied to a bicycle during normal cycling. Journal of Biomechanics 12: 527–541, 1979b
Stamford BA. Perceptual and physiological responses to equivalent power outputs performed on a bicycle ergometer at varying pedalling rates. Doctoral dissertation, University of Pittsburgh, 1973
Stenberg J, Åstrand PO, Ekblom B, Royce J, Saltin B. Hemodynamic response to work with different muscle groups, sitting and supine. Journal of Applied Physiology 22: 61–70, 1967
Thomas V. Saddle height. Cycling 7: 24, 1967a
Thomas V. Saddle height — conflicting views. Cycling 4: 17, 1967b
Thomas V. Scientific setting of saddle position. American Cycling 6(4): 12–13, 1967c
Timmons DR. The effect of supine and upright positions on the hemodynamic and metabolic performance of bicycle exercise. Unpublished master’s thesis, University of Wisconsin, LaCrosse, 1981
Titlow LW, Ishee JH, Anders A. Effects of knee angle on submaximal bicycle ergometry. Journal of Sports Medicine and Physical Fitness 26(1): 52–54, 1986
Too D. The effect of body position, configuration, and orientation on cycling performance. Doctoral dissertation, University of Ilinois at Urbana-Champaign, 1988
Too D. The effect of body position/configuration on anaerobic power and capacity of cycling. Abstract. Medicine and Science in Sports and Exercise 21(2) (Suppl.): S79, 1989a
Too D. The effect of body orientation on cycling performance. In Morrison (Ed.) Proceedings of the VIIth International Symposium of the Society of Biomechanics in Sports, pp. 53–60, Footscray Institute of Technology, Victoria, Australia, 1989b
Too D. The effect of body configuration on cycling performance. In Kreighbaum et al. (Eds) Biomechanics in Sports VI, pp. 51–58, Montana State University, Bozeman, Montana, 1990
Whitt FR. Crank length and pedalling efficiency. Cycling Touring (Dec–Jan): 12, 1969
Whitt FR. A note on the estimation of the energy expenditure of sporting cyclists. Ergonomics 14: 419–424, 1971
Whitt FR, Wilson DG. Bicycling science, 2nd ed., MIT Press, Cambridge, 1982
Wilson SS. Bicycle technology. Scientific American 228(3): 81–91, 1973
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Too, D. Biomechanics of Cycling and Factors Affecting Performance. Sports Med 10, 286–302 (1990). https://doi.org/10.2165/00007256-199010050-00002
Published:
Issue Date:
DOI: https://doi.org/10.2165/00007256-199010050-00002