Classical and relativistic fluids as intermediate integrals of finite dimensional mechanical systems

In a series of papers, Chang et al. proved and experimentally demonstrated a phenomenon in underactuated mechanical systems, that they termed “damping-induced self-recovery.” This paper further investigates a few features observed in these demonstrated experiments and provides additional theoretical interpretation for the same. In particular, we present a model for the infinite-dimensional fluid–stool–wheel system, that approximates its dynamics to that of the better understood finite dimensional case, and comment on the effect of the intervening fluid on the large amplitude oscillations observed in the bicycle wheel–stool experiment.

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The Impulsive Action Integral for Rigid-Body Mechanical Systems With Impacts

Journal of Computational and Nonlinear Dynamics ◽

10.1115/1.4006562 ◽

2012 ◽

Vol 7 (3) ◽

Cited By ~ 2

Author(s):

Kerim Yunt

Keyword(s):

Rigid Body ◽

Regularity Condition ◽

Mechanical Systems ◽

Momentum Balance ◽

Lagrangian System ◽

Analytical Mechanics ◽

Impulsive Action ◽

Action Integral ◽

Finite Dimensional ◽

Stationarity Conditions

There is a missing link in analytical mechanics which shows that general impactive processes are obtained by extremizing some sort of action integral for which momentum and energy are not necessarily conserved. In this work, the conditions under which general nonconserving impacts become a part of an extremizing solution for mechanical systems, which are scleronomic (not explicitly time depending) and holonomic, are investigated. The stationarity conditions of an impulsive action integral are investigated and the main theorem is proven. The general momentum balance and the total energy change over a collisional impact for a mechanical scleronomic holonomic finite-dimensional Lagrangian system are obtained in the form of stationarity conditions of a modified action integral under a regularity condition on the impactive transition sets.

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Numerical simulation of finite dimensional multibody nonsmooth mechanical systems

Applied Mechanics Reviews ◽

10.1115/1.1454112 ◽

2002 ◽

Vol 55 (2) ◽

pp. 107-150 ◽

Cited By ~ 126

Author(s):

B Brogliato ◽

AA ten Dam ◽

L Paoli ◽

F Ge´not ◽

M Abadie

Keyword(s):

Differential Equation ◽

Numerical Simulation ◽

Ordinary Differential Equation ◽

Mechanical Systems ◽

Difficult Problem ◽

Review Article ◽

Differential Algebraic Equation ◽

Complementarity Conditions ◽

Finite Dimensional ◽

Impact Phenomena

This review article focuses on the problems related to numerical simulation of finite dimensional nonsmooth multibody mechanical systems. The rigid body dynamical case is examined here. This class of systems involves complementarity conditions and impact phenomena, which make its study and numerical analysis a difficult problem that cannot be solved by relying on known Ordinary Differential Equation (ODE) or Differential Algebraic Equation (DAE) integrators only. The main techniques, mathematical tools, and existing algorithms are reviewed. The article utilizes 233 references.

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On different geometric approaches to the dynamics of finite‐dimensional mechanical systems

PAMM ◽

10.1002/pamm.201900327 ◽

2019 ◽

Vol 19 (1) ◽

Author(s):

Simon R. Eugster ◽

Giuseppe Capobianco ◽

Tom Winandy

Keyword(s):

Mechanical Systems ◽

Finite Dimensional

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2d quantum dilaton gravity as/versus a finite dimensional quantum mechanical systems

Nuclear Physics B - Proceedings Supplements ◽

10.1016/s0920-5632(97)00379-4 ◽

1997 ◽

Vol 57 (1-3) ◽

pp. 330-333 ◽

Cited By ~ 3

Author(s):

T. Strobl

Keyword(s):

Mechanical Systems ◽

Quantum Mechanical ◽

Dilaton Gravity ◽

Finite Dimensional ◽

Quantum Mechanical Systems

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Geometric description of time-dependent finite-dimensional mechanical systems

Mathematics and Mechanics of Solids ◽

10.1177/1081286520918900 ◽

2020 ◽

Vol 25 (11) ◽

pp. 2050-2075

Author(s):

Simon R. Eugster ◽

Giuseppe Capobianco ◽

Tom Winandy

Keyword(s):

State Space ◽

Degrees Of Freedom ◽

Vector Fields ◽

Mechanical Systems ◽

Second Order ◽

The State ◽

Time Dependent ◽

Finite Dimensional ◽

Affine Bundle ◽

Time Position

Using the non-standard geometric structure proposed by Loos, we present a coordinate-free formulation of the theory for time-dependent finite-dimensional mechanical systems with n degrees of freedom. The state space containing the system’s information on time, position and velocity is defined as a (2 n+1)-dimensional affine bundle over an ( n+1)-dimensional generalized space-time. The main goal is to present a geometric postulate that characterizes a second-order vector field whose integral curves describe the motions of a time-dependent finite-dimensional mechanical system. The core objects of the postulate are differential two-forms on the state space, called action forms, which are in a bijective relation with second-order vector fields. The requirements for a differential two-form to be an action form allow for a coordinate-free definition of non-potential forces, which may depend on time, position and velocity. Finally, we show that not only Lagrange’s equations but also Hamilton’s equations follow directly as mere coordinate representations of the same coordinate-free postulate.

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The Poincaré variational principle in the Lagrange–Poincaré reduction of mechanical systems with symmetry

International Journal of Geometric Methods in Modern Physics ◽

10.1142/s0219887819500683 ◽

2019 ◽

Vol 16 (05) ◽

pp. 1950068

Author(s):

S. N. Storchak

Keyword(s):

Riemannian Manifold ◽

Variational Principle ◽

Mechanical Systems ◽

Scalar Particle ◽

Orbit Space ◽

Local Dynamic ◽

Lagrange Equations ◽

Smooth Action ◽

Finite Dimensional ◽

Dependent Coordinates

The local Lagrange–Poincaré equations (the reduced Euler–Lagrange equations) for the mechanical system describing the motion of a scalar particle on a finite-dimensional Riemannian manifold with a given free isometric smooth action of a compact semi-simple Lie group are obtained. The equations are written in terms of dependent coordinates which are used to represent the local dynamic given on the orbit space of the principal fiber bundle. The derivation of the equations is performed with the help of the variational principle developed by Poincaré for mechanical systems with symmetry.

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