English

Commuting planar polynomial vector fields for conservative Newton systems

Dynamical Systems 2020-11-17 v1 Commutative Algebra Classical Analysis and ODEs Rings and Algebras

Abstract

We study the problem of characterizing polynomial vector fields that commute with a given polynomial vector field on a plane. It is a classical result that one can write down solution formulas for an ODE that corresponds to a planar vector field that possesses a linearly independent commuting vector field. This problem is also central to the question of linearizability of vector fields. Let fK[x]f \in K[x], where KK is a field of characteristic zero, and dd the derivation that corresponds to the differential equation x¨=f(x)\ddot x = f(x) in a standard way. Let also HH be the Hamiltonian polynomial for dd, that is H=12y2f(x)dxH=\frac{1}{2}y^2-\int{f(x)dx}. It is known that the set of all polynomial derivations that commute with dd forms a K[H]K[H]-module MdM_d. In this paper, we show that, for every such dd, the module MdM_d is of rank 11 if and only if deg  f2\text{deg}\; f\geqslant 2. For example, the classical elliptic equation x¨=6x2+a\ddot x = 6x^2+a, where aCa \in \mathbb{C}, falls into this category.

Keywords

Cite

@article{arxiv.1802.00831,
  title  = {Commuting planar polynomial vector fields for conservative Newton systems},
  author = {Joel Nagloo and Alexey Ovchinnikov and Peter Thompson},
  journal= {arXiv preprint arXiv:1802.00831},
  year   = {2020}
}
R2 v1 2026-06-23T00:09:13.665Z