English

Twisting Somersault

Classical Physics 2018-02-01 v1 Dynamical Systems

Abstract

A complete description of twisting somersaults is given using a reduction to a time-dependent Euler equation for non-rigid body dynamics. The central idea is that after reduction the twisting motion is apparent in a body frame, while the somersaulting (rotation about the fixed angular momentum vector in space) is recovered by a combination of dynamic and geometric phase. In the simplest "kick-model" the number of somersaults mm and the number of twists nn are obtained through a rational rotation number W=m/nW = m/n of a (rigid) Euler top. This rotation number is obtained by a slight modification of Montgomery's formula [9] for how much the rigid body has rotated. Using the full model with shape changes that take a realistic time we then derive the master twisting-somersault formula: An exact formula that relates the airborne time of the diver, the time spent in various stages of the dive, the numbers mm and nn, the energy in the stages, and the angular momentum by extending a geometric phase formula due to Cabrera [3]. Numerical simulations for various dives agree perfectly with this formula where realistic parameters are taken from actual observations.

Keywords

Cite

@article{arxiv.1510.08046,
  title  = {Twisting Somersault},
  author = {Holger R. Dullin and William Tong},
  journal= {arXiv preprint arXiv:1510.08046},
  year   = {2018}
}

Comments

16 pages, 6 figures, work from PhD thesis of William Tong

R2 v1 2026-06-22T11:30:24.085Z