%0 Journal Article
%T Nonlinear Violence in Nonlinear Oscillations at High Energy
%A Yair Zarmi
%J Applied Mathematics
%P 65-95
%@ 2152-7393
%D 2024
%I Scientific Research Publishing
%R 10.4236/am.2024.151007
%X This paper focuses on the characteristics of solutions of nonlinear oscillatory systems in the limit of very high oscillation energy, E; specifically, systems, in which the nonlinear driving force grows with energy much faster for <em>x</em><em>(</em><em>t</em><em>)</em> close to the turning point, <em>a(E)</em>, than at any position, <em>x(t)</em>, that is not too close to <em>a(E)</em>. This behavior dominates important aspects of the solutions. It will be called ¡°nonlinear violence¡±. In the vicinity of a turning point, the solution of a nonlinear oscillatory systems that is affected by nonlinear violence exhibits the characteristics of boundary-layer behavior (independently of whether the equation of motion of the system can or cannot be cast in the traditional form of a boundary-layer problem.): close to <em>a(E)</em>, <em>x(t)</em> varies very rapidly over a short time interval (which vanishes for <em>E</em> ¡ú ¡Þ). In traditional boundary layer systems this would be called the ¡°inner¡± solution. Outside this interval, <em>x(t)</em> soon evolves into a moderate profile (e.g. linear in time, or constant)¡ªthe ¡°outer¡± solution. In (1 + 1)-dimensional nonlinear energy-conserving oscillators, if the solution is reflection-invariant, nonlinear violence determines the characteristics of the whole solution. For large families of nonlinear oscillatory systems, as <em>E</em> ¡ú ¡Þ, the solutions for <em>x(t)</em> tend to common, indistinguishable profiles, such as periodic saw-tooth profiles or step-functions. If such profiles are observed experimentally in high-energy oscillations, it may be difficult to decipher the dynamical equations that govern the motion. The solution of motion in a central field with a non-zero angular momentum exhibits extremely fast rotation around a turning point that is affected by nonlinear violence. This provides an example for the possibility of interesting phenomena in (1 + 2)-dimensional oscillatory systems.
%K High-Energy Oscillations
%K Nonlinear Violence
%K Boundary-Layer Characteristics
%U http://www.scirp.org/journal/PaperInformation.aspx?PaperID=130842