English

Prescribed energy connecting orbits for gradient systems

Dynamical Systems 2019-01-23 v1 Analysis of PDEs Classical Analysis and ODEs

Abstract

We are concerned with conservative systems q¨=V(q),  qRN\ddot{q}=\nabla V(q), \; q\in\mathbb{R}^N for a general class of potentials VC1(RN)V\in C^1(\mathbb{R}^N). Assuming that a given sublevel set {Vc}\{V\leq c\} splits in the disjoint union of two closed subsets Vc\mathcal{V}^c_- and V+c\mathcal{V}^c_+, for some cRc\in\mathbb{R}, we establish the existence of bounded solutions qcq_c to the above system with energy equal to c-c whose trajectories connect Vc\mathcal{V}^c_- and V+c\mathcal{V}^c_+. The solutions are obtained through an energy constrained variational method, whenever mild coerciveness properties are present in the problem. The connecting orbits are classified into brake, heteroclinic or homoclinic type, depending on the behavior of V\nabla V on V±c\partial\mathcal{V}^c_{\pm}. Next, we illustrate applications of the existence result to double-well potentials VV, and for potentials associated to systems of Duffing type and of multiple-pendulum type. In each of the above cases we prove some convergence results of the family of solutions (qc)(q_c).

Keywords

Cite

@article{arxiv.1901.06951,
  title  = {Prescribed energy connecting orbits for gradient systems},
  author = {Francesca Alessio and Piero Montecchiari and Andres Zuniga},
  journal= {arXiv preprint arXiv:1901.06951},
  year   = {2019}
}

Comments

34 pages, 2 figures, submitted to a journal for publication. KEYWORDS: conservative systems, energy constraints, variational methods, brake orbits, homoclinic orbits, heteroclinic orbits, convergence of solutions

R2 v1 2026-06-23T07:17:34.939Z