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Ïîëíàÿ âåðñèÿ
ÆÓÐÍÀËÛ // Regular and Chaotic Dynamics // Àðõèâ

Regul. Chaotic Dyn., 2006, òîì 11, âûïóñê 1, ñòðàíèöû 67–81 (Mi rcd658)

Ýòà ïóáëèêàöèÿ öèòèðóåòñÿ â 4 ñòàòüÿõ

The Lagrange–D'Alembert–Poincaré equations and integrability for the rolling disk

H. Cendra, V. Diaz

Departamento de Matemática, Universidad Nacional del Sur, Av. Alem 1253 Bahía Blanca (8000), Argentina

Àííîòàöèÿ: Classical nonholonomic systems are described by the Lagrange–d'Alembert principle. The presence of symmetry leads, upon the choice of an arbitrary principal connection, to a reduced variational principle and to the Lagrange–d'Alembert–Poincaré reduced equations. The case of rolling bodies has a long history and it has been the purpose of many works in recent times, in part because of its applications to robotics. In this paper we study the classical example of the rolling disk. We consider a natural abelian group of symmetry and a natural connection for this example and obtain the corresponding Lagrange–d'Alembert–Poincaré equations written in terms of natural reduced variables. One interesting feature of this reduced equations is that they can be easily transformed into a single ordinary equation of second order, which is a Heun's equation.

Êëþ÷åâûå ñëîâà: rolling disk, nonholonomic mechanics, integrability, Heun's equation.

MSC: 70F25, 37J60,70H33

Ïîñòóïèëà â ðåäàêöèþ: 19.04.2005
Ïðèíÿòà â ïå÷àòü: 27.07.2005

ßçûê ïóáëèêàöèè: àíãëèéñêèé

DOI: 10.1070/RD2006v011n01ABEH000335



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