The first goal of the study was to examine the relationship between maximum muscle strength and optimal drop height (DHopt), while the second goal was to examine the relationship between regression models for the prediction of DHopt and DHopt determined by variable H. A total of 30 respondents, students of the Faculty of Sport and Physical Education participated in the experiment. During the experiment, eight altitudes were randomized in the range of 0.12 to 0.82 m. The instruction was to achieve a higher jump, with a shorter duration of rebound. A positive statistically significant correlation between DHopt determined by prediction method with 1 RM / BW^0.67 and MDS (p<0.05) was calculated. When computing the DHopt connection determined by the dialing method with the maximum muscle strength of the subjects, no statistically significant correlation was obtained, but there is a positive trend. Determined by the prediction method DHopt is (0.47±0.17 m) and using the regression model with 1 RM/BW^0.67 (0.47±0.07 m) and with MDS (0.48±0.06 m). In order to explain high relationship between models, it should be noted that the muscles of knee joint have a more important role in motor tasks performed at higher intensity like during drop jump. With this in mind, DHopt in the jumping jump can be determined depending on the neuromuscular capacity to generate the maximum muscle strength of the knee of the knee in order to use the optimal intensity within the pliometric training.

Baker, D., & Nance, S. (1999). The relationship between strength and power in professional rugby league players. Journal of Strength and Conditioning Research, 13, 224-229.

Baker, D., Nance, S., & Moore, M. (2001). The load that maximizes the average mechanical power output during jump squats in power-trained athletes. Journal of Strength and Conditioning Research, 15(1), 92-97.

Bobbert, M.J. & Van Soest, A.J. (1994). Effects of muscle strengthening on vertical jump height: A simulation study. Medicine and Science in Sports and Exercise, 26, 1012-1020.

Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd Ed.). Hillsdale, NJ: Lawrence Erlbaum Associates.

Cormie, P., McCaulley, G.O., & McBride, J.M. (2007). Power versus strength-power jump squat training: influence on the load-power relationship. Medicine and Science in Sports and Exercise, 39, 996-1003.

Cormie, P., McGuigan, M.R., & Newton, R.U. (2011a). Developing maximal neuromuscular power: Part 1 - biological basis of maximal power production. Sports Medicine, 41, 17-38.

Cormie, P., McGuigan, M.R., & Newton, R.U. (2011b). Developing maximal neuromuscular power: Part 2 - training considerations for improving maximal power production. Sports Medicine, 41(2), 125-46.

Cronin, J., & Sleivert, G. (2005). Challenges in understanding the influence of maximal power training on improving athletic performance. Sports Medicine, 35, 213-234.

Đokić, M., Radenković, M., & Stanković, R. (2018). Differences in mechanical characteristics of vertical jump between athletes in sports games. Facta Universitatis, Series Physical Education and Sport, 16(1), 85-94.

Harrell, F.E. (2001). Regression modeling strategies: with applications to linear models, logistic regression, and survival analysis. New York: Springer-Verlag.

Hobara, H., Muraoka, T., Omuro, K., Gomi, K., Sakamoto, M., Inoue, K., et al. (2009). Knee stiffness is a major determinant of leg stiffness during maximal hopping. Journal of Biomechanics, 42, 1768-1771.

Jarić, S. (2002). Muscle strength testing: use of normalisation for body size. Sports Medicine, 32(10), 615-631.

Horita, T., Komi, P.V., Nicol, C., & Kyröläinen, H. (2002). Interaction between pre-landing activities and stiffness regulation of the knee joint musculoskeletal system in the drop jump: implications to performance. European Journal of Applied Physiology, 88, 76-84.

Kawamori, N., & Haff, G.G. (2004). The optimal training load for the development of muscular power. Journal of Strength and Conditioning Research, 18(3), 675-684.

Kibele, A. (1999). Technical note.Possible errors in the comparative evaluation of drop jumps from different heights. Ergonomics, 42, 1011-1014.

Komi, P.V. (1992). Strength and power in sport. London: Blackwell.

Komi, P.V., & Bosco, C. (1978). Utilization of stored elastic energy in leg extensor muscles by men and women. Medicine and Science in Sports, 10, 261-265.

Laffaye, G., & Choukou, M.A. (2010). Gender bias in the effect of dropping height on jumping performance in volleyball players. Journal of Strength and Conditioning Research, 24, 2143-2148.

Lazaridis, S.N., Bassa, E.I., Patikas, D., Hatzikotoulas, K., Lazaridis, F.K., & Kotzamanidis, C.M. (2013). Biomechanical comparison in different jumping tasks between untrained boys and men. Pediatric Exercise Science, 25, 101-113.

Makaruk, H., & Sacewicz, T. (2011). The effect of drop height and body mass on drop jump intensity. Biology and Sport, 28, 63-67.

McBride, J.M., Triplett-McBride, T., Davie, A., & Newton, R.U. (2002). The effect of heavy-vs. light-load jump squats on the development of strength, power, and speed. Journal of Strength and Conditioning Research, 16, 75-82.

Norton, K., Marfell-Jones, M., Whittingham, N., Kerr, D., Carter, L., Saddington, K., et al. (2000). Anthropometric assessment protocols. In C.J. Gore (Ed.). Physiological tests for elite athletes, (pp 66-85). Champaign, IL: Human Kinetics.

Potach, D.H., & Chu, D.A. (2000). Plyometric training. In T.R. Baechle, & R.W. Earle (Eds.). Essentials of strength training and conditioning (2nd Ed.). (pp. 427-470). Human Kinetics.

Read, M.M., & Cisar, C. (2001). The influence of varied rest interval lengths on depth jump performance. Journal of Strength and Conditioning Research, 15(3), 279-283.

Schmidtbleicher, D., Gollhofer, A., & Frick, U. (1988). Effects of a stretch-shortening typed training on the performance capability and innervation characteristics of leg extensor muscles. In de Groot et al., (Eds.), Biomechanics XI-A (pp. 185-189), Vol 7-A G. Free University Press: Amsterdam, Netherlands.

Schmidtbleicher, D. (1992). Training for power event. In P.V. Komi (Ed.). Strength and power in sport (pp. 381-395). London: Blackwell Scientific.

Stojanović, N., Čoh, M., & Bratić, M. (2016). The role of countermovement in the manifestation of explosive leg strength in vertical jumps. Facta Universitatis, Series Physical Education and Sport, 14(1), 13-22.

Taube, W., Leukel, C., Lauber, B., & Gollhofer, A. (2012). The drop height determines neuromuscular adaptations and changes in jump performance in stretch-shortening cycle training. Scandinavian Journal of Medicine & Science in Sports, 22, 671-683.

Ugrinowitsch, C., Tricoli, V., Rodacki, A., Batista, M., & Ricard, M. (2007). Influence of training background on jumping height. Journal of Strength and Conditioning Research, 21(3), 848-852.

Viitasalo, J.T., Salo, A., & Lahtinen, J. (1998). Neuromuscular functioning of athletes and non-athletes in the drop jump. European Journal of Applied Physiology and Occupational Physiology, 78, 432-440.

Voigt, M., Simonsen, E.B., Dyhre-Poulsen, P., & Klausen, K. (1994). Mechanical and muscular factors influencing the performance in maximal vertical jumping after different prestretch loads. Journal of Biomechanics, 28, 293-307.