The aim of this research was to determine which kinematic parameters generate the maximum sprint speed of the world’s fastest sprinter, Usain Bolt. The biomechanical parameters of a double sprint step, using a 2D kinematic analysis under conditions of the realization of its maximum velocity were analyzed. The APAS computer system was used for the kinematic analysis. The data was recorded with three digital cameras CASIO EX-F1 with a frequency of 300 Hz, while the cameras were connected to one another and synchronized. The measurements were performed at the international athletics competition IAAF World Challenge in Zagreb, Croatia. Bolt reached a maximum speed of 12.42 m·s^-1 in the section between 70 and 90 meters. His average stride length in this section was 2.70 m at an average frequency of 4.36 strides/s. His average contact time was 0.86 s and the average duration of his flight phase was 0.145 s. He developed a maximum vertical ground reaction force of 3956.74 N. This force corresponds to 4.1 times the weight of the athlete. The ratio between his braking and propulsion phase was 37.3% : 62.7%, which is a good indicator of an economical running technique.  The maximum speed of Usain Bolt is a combination of optimal anthropometric characteristics, motor abilities, and an extremely rational technique of sprinting gait.

Beneke, R., & Taylor, M.J. (2010). What gives Bolt the edge-AV Hill knew it already!. Journal of Biomechanics, 43(11), 2241-2243.

Beneke, R., Taylor, M. J., & Leithäuser, R. M. (2011). The Fastest Men's 100 m Sprint Final-Stature and Step Rate were Cues for Success. Medicine and Science in Sports and Exercise, 43, 688.

Brechue, W. (2011). Structure-function relationships that determine sprint performance and running in sport. International Journal of Applied Sports Science, 23 (2), 313-350.

Bruggemann, G.P., & Glad, B. (1990). Time analysis of the sprint events. Scinetific research project at the games of the XXXIV Olympiad, Seoul 1988. New Studies in Athletics, (Suppl.).

Charles, J.D., & Bejan, A. (2009). The evolution of speed, size and shape in modern athletics. Journal of Experimental Biology, 212(15), 2419-2425.

Cavagna, G.A., Komarek, L., & Mazzoleni, S. (1971). The mechanics of sprint running. Journal of Physiology, 217(3), 709-721.

Čoh, M., Tomažin, K., & Štuhec, S. (2006). The biomechanical model of the sprint start and block acceleration. Facta Universitatis Series Physical Education and Sport, 4(2), 103-114.

Donati, A. (1995). The development of stride length and stride frequency in sprinting. New Studies in Athletics, 10, 51-61.

El Pais (2013). Un poder intocable (An untouchable power). Retrieved June o2, 2018 at: https://elpais.com/deportes/2013/08/11/actualidad/1376232415_432047.html. In Spanish

Eriksen, H.K., Kristiansen, J.R., Langangen, Ø., & Wehus, I.K. (2009). How fast could Usain Bolt have run? A dynamical study. American Journal of Physics, 77(3), 224-228.

Gollhofer, A., & Kyrolainen, H. (1991). Neuromuscular control of the human leg extensor muscles in jump exercises under various stretch-load conditions. International Journal of Sports Medicine, 12, 34-40.

Gómez, J.H., Marquina, V., & Gómez, R.W. (2013). On the performance of Usain Bolt in the 100 m sprint. European Journal of Physics, 34(5), 1227.

Graubner, R., & Nixdorf, E. (2011). Biomechanical Analysis of the Sprint and Hurdles Events at the 2009 IAAF World Championship in Athletics. New Studies in Athletics, 1, 19-53.

Guissard, N., & Hainaut, K. (1992). EMG and mechanical changes during sprint start at different front block obliquities. Medicine and Science in Sport and Exercise, 24 (11), 1257-1263.

Hommel, H. (2009). Biomechanical analyses of selected events at 12th IAAF world championship in athletics. Biomechanics Report World Championships, Berlin, Germany.

Hunter, J., Marshall, R., & McNair, P. (2004) Interaction of step length and step rate during sprint running. Medicine and Science in Sport and Exercises, 36 (2), 261-271.

Ito, A., & Suzuki, M. (1992). The men’s 100 meters. New Studies in Athletics, 7, 47-52.

Komi, P. (2000). Stretch-shortening cycle: a powerful model to study normal and fatigued muscle. Journal of Biomechanics, 33 (10), 1197-2006.

Lehmann, F., & Voss, G. (1997). Innovationen fur den sprint und sprung: "Ziehende" gestaltung der stützphasen (Innovations for the sprint and jump: "Pulling" design of the support phases). Leistungssport, 6, 20-25. In German

Luhtanen, P., & Komi, P.V. (1980). Force-, power- and elasticity-velocity relationship in walking, running and jumping. European Journal of Applied Physiology, 44 (3), 279-289.

Mackala, K., & Mero, A. (2013). A Kinematics Analysis of three best 100 m performances ever. Journal of Human Kinetics, 36, 149-161.

Mann, R., & Sprague, P. (1980). A kinetic analysis of the ground leg during sprint running. Research Quarterly for Exercise and Sport, 51(2), 334-348.

Mero, A., Komi, P.V., & Gregor, R.J. (1992). Biomechanics of sprint running. Sport Medicine, 13 (6), 376-392.

Nicol, C., Avela, J., & Komi, P. (2006). The stretch-shortening cycle. Sports Medicine, 36 (11), 977-999.

Novacheck, T. (1998). The biomechanics of running, Gait and Posture, 7, 77-95.

Taylor, M.J.D., & Beneke, R. (2012). Spring mass characteristics of the fastest men on Earth. International Journal of Sports Medicine, 33(8), 667-670.

International Association of Athletics Federations-IAAF (2011). Scientific Research Project 2011, (DLV) World Championship in Athletic, Berlin, Germany. Retrieved June, 10, 2018 at the World Wide Web: w.w.w. iaaf.org

Winter, D. (2005). Biomechanics and motor control of human movement. Canada: John Wiley and Sons. Inc.