Swimming stroke

Human swimming typically consists of repeating a specific body motion or swimming stroke to propel that body forward. There are many kinds of strokes, each defining a different swimming style or crawl.

In high school, collegiate, and Olympic swimming, there are two undulating strokes (breaststroke, and butterfly,) and two alternating strokes (freestyle and backstroke.)

Most strokes involve rhythmic and coordinated movements of all major body parts — torso, arms, legs, hands, feet, and head. Breathing typically must be synchronized with the strokes, too. It is possible however to swim by moving only legs without arms or only arms without legs; such strokes may be used for special purposes, for training or exercise, or by amputees (paralympians) and paralytics.

Swimming styles

Special purpose styles

A number of strokes are only used for special purposes, e.g. to manipulate an object (a swimmer in distress, a ball), or just to stay afloat.

Underwater swimming

Any style with underwater recovery can be swum under water for certain distances depending on the need for air. Underwater swimming on the back has the additional problem of water entering the nose. To avoid this, the swimmer can breathe out through the nose or wear a nose clip. Some swimmers can close their nostrils with the upper lip or with the compressor naris muscles.

Undulatory swimming

Swimming hydrodinamics have significiantly applied BCF to techniques. In addition research on undulatory motion, undulatory Body-caudal fin anguilliform, and undulatroy Median-paired fin give interesting conclusions. These natural modes are seen as alternative to BCF techniques introducing some missing elements as buoyancy, gliding and floating to complement the scale of man’s hydrodynamics. [6]

Study draws conclusion from hydrodynamic properties of caphalodops as implied to human kinetics, discerning significant patterns, as floating, puddle, undulation or swim efficiency. In biomechanical aspect meduzoi and aguilliform shows positive results: low Reynolds number, low viscous forces, stability, great luminar flow, linear momentum and efficient velocity.

Lifesaving strokes

Without forward motion

See also

References

  1. Cosmo, Lepota. Natural modes of swimming: new swimming styles, how to swim with efficient buoyant velocity, International Swimming Coaching E-Conference 2014, 16-19 November 2014, Day 3, ISOSC
  2. Ibid.
  3. Dalton, F. E. (1918). Swimming scientifically taught, Funk and Wagnalls Company, New York and London
  4. Ibid.
  5. Encyclopedia of Marine Mammals, p. 1142, at Google Books
  6. 31. Lindsey, C. C. (1978) Form, function and locomotory habits in fish, in Fish Physiology VII Locomotion , W. S. Hoar and D. J. Randall, Eds. New York: Academic, 1–100
  7. 1 2 https://web.archive.org/web/20110613082530/http://www.usscouts.org/macscouter/CubScouts/PowWow99/Web99.pdf
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