Andere Kunden interessierten sich auch für
![Relative Equilibria of the Curved N-Body Problem]( "Relative Equilibria of the Curved N-Body Problem")
Relative Equilibria of the Curved N-Body Problem70,99 €![Periodic Solutions of the N-Body Problem]( "Periodic Solutions of the N-Body Problem")
Periodic Solutions of the N-Body Problem24,99 €![Introduction to Hamiltonian Dynamical Systems and the N-Body Problem]( "Introduction to Hamiltonian Dynamical Systems and the N-Body Problem")
Introduction to Hamiltonian Dynamical Systems and the N-Body Problem48,99 €![Critical Point Theory for Lagrangian Systems]( "Critical Point Theory for Lagrangian Systems")
Critical Point Theory for Lagrangian Systems39,99 €![A Geometrical Study of the Elementary Catastrophes]( "A Geometrical Study of the Elementary Catastrophes")
A Geometrical Study of the Elementary Catastrophes27,99 €![Geometrical Properties of Differential Equations]( "Geometrical Properties of Differential Equations")
Geometrical Properties of Differential Equations74,99 €![Geometrical Methods in the Theory of Ordinary Differential Equations]( "Geometrical Methods in the Theory of Ordinary Differential Equations")
Geometrical Methods in the Theory of Ordinary Differential Equations154,99 €
Presenting a selection of recent developments in geometrical problems inspired by the N-body problem, these lecture notes offer a variety of approaches to study them, ranging from variational to dynamical, while developing new insights, making geometrical and topological detours, and providing historical references.
A. Guillot's notes aim to describe differential equations in the complex domain, motivated by the evolution of N particles moving on the plane subject to the influence of a magnetic field. Guillot studies such differential equations using different geometric structures on complex curves (in the sense of W. Thurston) in order to find isochronicity conditions.
R. Montgomery's notes deal with a version of the planar Newtonian three-body equation. Namely, he investigates the problem of whether every free homotopy class is realized by a periodic geodesic. The solution involves geometry, dynamical systems, and the McGehee blow-up.A novelty of the approach is the use of energy-balance in order to motivate the McGehee transformation.
A. Pedroza's notes provide a brief introduction to Lagrangian Floer homology and its relation to the solution of the Arnol'd conjecture on the minimal number of non-degenerate fixed points of a Hamiltonian diffeomorphism.
A. Guillot's notes aim to describe differential equations in the complex domain, motivated by the evolution of N particles moving on the plane subject to the influence of a magnetic field. Guillot studies such differential equations using different geometric structures on complex curves (in the sense of W. Thurston) in order to find isochronicity conditions.
R. Montgomery's notes deal with a version of the planar Newtonian three-body equation. Namely, he investigates the problem of whether every free homotopy class is realized by a periodic geodesic. The solution involves geometry, dynamical systems, and the McGehee blow-up.A novelty of the approach is the use of energy-balance in order to motivate the McGehee transformation.
A. Pedroza's notes provide a brief introduction to Lagrangian Floer homology and its relation to the solution of the Arnol'd conjecture on the minimal number of non-degenerate fixed points of a Hamiltonian diffeomorphism.