What is the biomechanics of swimming?

swimming can be described as physical movement of movement through water, although it is much more than that. Swimming can be an instrument for survival, art, sport or absolutely challenge. Biomechanics is a field of movement and examines the movements of the human body as if it were a mechanical object. Biomechanics swimming is therefore a study of proposals involved in swimming.

In order to understand the biomechanics of swimming, it is useful to gain basic knowledge of work components, as well as procedures that most biomechanical professionals perform to analyze movement. Movement comes down into muscles, bones, connective tissue and nervous system that controls them. In principle, the nervous system dictates movements that are performed by contraction of muscle or muscle group. These movements occur by pulling the muscles on the bones and all the structures involved are associated with tendons, ligaments and other connective tissues.

When a person sail water, he monitors the formula of movement and uses muscles specific to swimming. Not all types of swimming are the same but mostIna uses similar muscles. Among the many muscles involved in biomechanics swimming include diaphragm, leg muscles, nuclear muscles and back and shoulder muscles.

Biomechanics of swimming attempts to summarize, understand and analyze swimming as a whole or even in their specific aspects. The method used to achieve this objective does not differ than other scientific investigations. It usually begins with a problem or question and attempts to solve it with experimental measures.

For example, the Olympic swimmer must be faster to win the medal in the upcoming games. This individual can train more harder than anyone else and be physically very talented, but in the non -Boder to maximize his potential, he must find a way to be more efficient in the water. Biomechanics of swimming could help to solve this puzzle by getting insight to the person's movement.

maybe you could get video and shots analyzed toE revealed a defect on the wall. The identification of this defect could help the athlete accelerate and use it to the top of the stage at the next Olympic Games. This is one practical way of organic swimming biomechanics.