Mechanics of non-holonomic systems. A New Class of control systems

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Mechanics of non-holonomic systems. A New Class of control systems. / Soltakhanov, Sh.Kh.; Yushkov, M.P.; Zegzhda, S.A.

Springer Nature, 2009. 329 p.

Research output: Book/Report/Anthology › Book

BibTeX

@book{babed9ab740e4d829e11be1b2917ae81,

title = "Mechanics of non-holonomic systems. A New Class of control systems",

abstract = "A general approach to the derivation of equations of motion of as holonomic, as nonholonomic systems with the constraints of any order is suggested. The system of equations of motion in the generalized coordinates is regarded as a one vector relation, represented in a space tangential to a manifold of all possible positions of system at given instant. The tangential space is partitioned by the equations of constraints into two orthogonal subspaces. In one of them for the constraints up to the second order, the motion low is given by the equations of constraints and in the other one for ideal constraints, it is described by the vector equation without reactions of connections. In the whole space the motion low involves Lagrangian multipliers. It is shown that for the holonomic and nonholonomic constraints up to the second order, these multipliers can be found as the function of time, positions of system, and its velocities. The application of Lagrangian multipliers for holonomic systems permits us to construct",

author = "Sh.Kh. Soltakhanov and M.P. Yushkov and S.A. Zegzhda",

year = "2009",

language = "English",

isbn = "978-3-540-85846-1",

publisher = "Springer Nature",

address = "Germany",

}

RIS

TY - BOOK

T1 - Mechanics of non-holonomic systems. A New Class of control systems

AU - Soltakhanov, Sh.Kh.

AU - Yushkov, M.P.

AU - Zegzhda, S.A.

PY - 2009

Y1 - 2009

N2 - A general approach to the derivation of equations of motion of as holonomic, as nonholonomic systems with the constraints of any order is suggested. The system of equations of motion in the generalized coordinates is regarded as a one vector relation, represented in a space tangential to a manifold of all possible positions of system at given instant. The tangential space is partitioned by the equations of constraints into two orthogonal subspaces. In one of them for the constraints up to the second order, the motion low is given by the equations of constraints and in the other one for ideal constraints, it is described by the vector equation without reactions of connections. In the whole space the motion low involves Lagrangian multipliers. It is shown that for the holonomic and nonholonomic constraints up to the second order, these multipliers can be found as the function of time, positions of system, and its velocities. The application of Lagrangian multipliers for holonomic systems permits us to construct

AB - A general approach to the derivation of equations of motion of as holonomic, as nonholonomic systems with the constraints of any order is suggested. The system of equations of motion in the generalized coordinates is regarded as a one vector relation, represented in a space tangential to a manifold of all possible positions of system at given instant. The tangential space is partitioned by the equations of constraints into two orthogonal subspaces. In one of them for the constraints up to the second order, the motion low is given by the equations of constraints and in the other one for ideal constraints, it is described by the vector equation without reactions of connections. In the whole space the motion low involves Lagrangian multipliers. It is shown that for the holonomic and nonholonomic constraints up to the second order, these multipliers can be found as the function of time, positions of system, and its velocities. The application of Lagrangian multipliers for holonomic systems permits us to construct

M3 - Book

SN - 978-3-540-85846-1

BT - Mechanics of non-holonomic systems. A New Class of control systems

PB - Springer Nature

ER -

ID: 4279038