Bachelor educational program "Physical culture and sport" must master special, substantive and core competencies, not only in the chosen specialization, but also in the basic sports, including "Swimming." It is a necessity due to the fact that the graduate program in order to protect their health and life should own at least one method of navigation. The object of study - the educational process of preparation of bachelors of physical culture and sports in the discipline "Swimming with the methodology of teaching". Subject of research - optimization of swimming training students of different sporting specializations in credit conditions in B-tem training.  The aim of this series of studies - to improve efficiency and the training methods of diving students of different sporting specializations in conditions of credit system of training by developing a set of exercises. The task: to develop sets of exercises that improve training effectiveness, taking into account levels of physical fitness and swimming sports specialization students.  Research methods. To achieve this goal, and to test the hypothesis in the set of methods was used, consisting of a theoretical analysis of the pedagogical literature, formulation of pedagogical experiment on using the developed sets of exercises and an electronic textbook for teaching, statistical data processing. Results and discussion. Studying diving course students of all specializations of sports on a specialty "Physical culture and sport" involves teaching methods bachelor sport diving. As our teacher observations, the initial level of the swimming training of students is different, which causes considerable difficulties in mastering swimming techniques and extend the learning process. Given that student training is limited to the number of allocated hours for swimming training, it requires the teacher to develop new technologies to speed up the learning process different methods of navigation.

Berthelot, G., Hellard, P., Len, S., Tafflet, M. & Toussaint, J.F. (2010). Technology and swimming: Three steps beyond physiology. A paper presented at the XIth International Symposium for Biomechanics and Medicine in Swimming. Oslo, 16–19.

Brooks, R.W., Lance, C.C. & Sawhill, J.A. (2000). The biomechanical interaction of lift and propulsion forces during swimming. Medicine and Science in Sports and Exercise, 32(5), 910-923.

Cappaert, J.M. & Rushall, B.S. (1994). Biomechanical analyses of champion swimmers. Spring Valley: Sports Science Associates, 352 p.

Counsilman, J.E. (1968). The science of Swimming. Englewood Cliffs, New York: Prentice-Hall 352 p.

Counsilman, J.E. (1970). The application of Bernoulli's principle to human propulsion in water. Bloomington. Indiana: Indiana University Publications.

Deschodt, V.J. (1999). Relative contribution of arms and legs in humans to propulsion in 25-m sprint front-crawl swimming. European Journal of Applied Physiology and Occupational Physiology, 80, 192-199.

Fernandes, R.J., Morais, P., Keskinen, K.L., Seifert, L., Chollet, D., & Vilas-Boas, J.P. (2010). Relationship between arm coordination and energy-cost in front crawl swimming. A paper presented at the XIth International Symposium for Biomechanics and Medicine in Swimming. Oslo, June 16–19, 2010.

Hay, J.G. (1993). The biomechanics of sports techniques. New York: Prentice Hall, 265 p.

Keul, S., Bieder, A., & Wahl, P. (2010). Effects of new high-tech swimsuits on passive drag. A paper presented at the XIth International Symposium for Biomechanics and Medicine in Swimming, Oslo, June 16–19.

Marinho, D.A., Barbosa, T.M., Mantripragada, N., Vilas-Boas, J.P., Rouard, A.H., Mantha, V., Rouboa, A.I. & Silva, A.J. (2010). The gliding phase in swimming: The effect of water depth. A paper presented at the XIth International Symposium for Biomechanics and Medicine in Swimming. Oslo, June 16–19.

Millet, G.P., Chollet, D., Chalies, S. & Chatard, J.C. (2002). Coordination in front crawl in elite triathletes and elite swimmers. International Journal of Sports Medicine, 23, 99-104.

Rushall, B.S. (1999). The crawl stroke kick – not propulsive but it aids progression. Carlile Coaches Forum, 5(3), 55-67.

Rushall, B.S. (2003). Biomechanics of human movement. Direct access: http://coachsci.sdsu.edu/rushall/books.htm

Rushall, B.S. (2009). The Future of Swimming: "Myths and Science". Swimming Science Bulletin, 37. Direct access: http://coachsci.sdsu.edu/swim/bullets/ASCA2009.pdf

Rushall, B.S. (2011). Swimming energy training in the 21st century: The justification for radical changes. Swimming Science Bulletin, 39. Direct access: http://coachsci.sdsu.edu/sw-im/bullets/energy39.pdf

Rushall, B.S. (2012). Energy dispersal in competitive swimming. Swimming Science Bulletin, 41, 5-7. Direct access: http://coachsci.sdsu.edu/swim/bullets/disper41.pdf

Rushall B.S. (2013). A swimming technique macrocycle. Direct access: http://coachsci.sdsu.edu/rushall/books.htm

Rushall, B.S. & Pyke, F.S. (1991). Training for sports and fitness. Melbourne, Australia: Macmillan of Australia, 253 p.

Sanders, R., Rushall, B.S., Toussaint, H., Stager, J. & Takagi, H. (2001). Bodysuit yourself: But first think about it. Direct access: http://di.iop.org/Journals/JoT/extra/20.

Schnitzle, C., Seifert, L., Ernwein, V. & Chollet, D. (2008). Arm coordination adaptations assessment in swimming. International Journal of Sports Medicine, 29, 480-487.

Sharp, R.L., & Costill, D.L. (1989). Influence of body hair removal on physiological responses during breaststroke swimming. Medicine and Science in Exercise and Sports, 21, 576-580.

Sharp, R.L., & Costill, D.L. (1990). Shaving a little time. Swimming Technique, Medicine and Science in Exercise and Sports, 4, 422-435.

Sokolovas, G. (2000). Demographic information. In The Olympic Trials Project. Direct access: http://www.usa-swimming.org/programs/ template.pl?opt=news&pubid=941.

Troup, J.P. (1992). International Center for Aquatic Research Annual: Studies by the International Center for Aquatic Research 1991-92. Colorado Springs: United States Swimming Press, 255 p.