This article is cited in
7 papers
On the 60th birthday of professor V.V. Kozlov
Partial integrability of Hamiltonian systems with homogeneous potential
A. J. Maciejewskia,
M. Przybylskabc a J. Kepler Institute of Astronomy, University of Zielona Góra, Licealna 9, PL-65–417 Zielona Góra, Poland
b Toruń Centre for Astronomy, N. Copernicus University,
Gagarina 11, PL-87–100 Toruń, Poland
c Institute of Physics, University of Zielona Góra, Licealna 9, PL-65–417 Zielona Góra, Poland
Abstract:
In this paper we consider
systems with
$n$ degrees of freedom given by the natural
Hamiltonian function of the form
\begin{equation*}
H=\frac{1}{2}{\boldsymbol p}^T{\boldsymbol M}{\boldsymbol p} +V({\boldsymbol q}),
\end{equation*}
where ${\boldsymbol q}=(q_1, \ldots, q_n)\in\mathbb C^n$, ${\boldsymbol p}=(p_1, \ldots,
p_n)\in\mathbb C^n$, are the canonical coordinates and momenta,
$\boldsymbol M$ is a
symmetric non-singular matrix, and
$V({\boldsymbol q})$ is a homogeneous function
of degree
$k\in\mathbb Z^{\star}$. We assume that the system admits
$1\leqslant
m<n$ independent and commuting first integrals
$F_{1},\ldots F_{m}$.
Our main results give easily computable and effective necessary
conditions for the existence of one more additional first integral
$F_{m+1}$ such that all integrals
$F_{1},\ldots F_{m+1}$ are
independent and pairwise commute. These conditions are derived from
an analysis of the differential Galois group of variational equations
along a particular solution of the system. We apply our result
analysing the partial integrability of a certain
$n$ body problem on a
line and the planar three body problem.
Keywords:
integrability, non-integrability criteria, monodromy group, differential Galois group, hypergeometric equation, Hamiltonian equations.
MSC: 70Hxx,
70Fxx,
70F07,
37J30 Received: 29.03.2010
Accepted: 12.04.2010
Language: English
DOI:
10.1134/S1560354710040106