Automatic generation of equations of motion from graphic input of vibration model. A system for two-dimensional vibrations of multibody systems.

Abstract In the ongoing search for mathematically efficient methods of predicting the motion of vehicle and other multibody systems, and presenting the associated results, one of the avenues of continued interest is the linearization of the equations of motion. While linearization can potentially result in reduced fidelity in the model, the benefits in computational speed often make it the pragmatic choice. Linearization techniques are also useful in modal and stability analysis, model order reduction, and state and input estimation. This paper explores the application of automatic differentiation to the generation of the linearized equations of motion. Automatic differentiation allows one to numerically evaluate the derivative of any function, with no prior knowledge of the differential relationship to other functions. It exploits the fact that every computer program must evaluate every function using only elementary arithmetic operations. Using automatic differentiation, derivatives of arbitrary order can be computed, accurately to working precision, with minimal additional computational cost over the evaluation of the base function. There are several freely available software libraries that implement automatic differentiation in modern computing languages. In the paper, several example multibody systems are analyzed, and the computation times of the stiffness matrix are compared using direct evaluation and automatic differentiation. The results show that automatic differentiation can be surprisingly competitive in terms of computational efficiency.

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About the Gibbs-Appel equations for multibody systems

Vietnam Journal of Mechanics ◽

10.15625/0866-7136/28/4/5582 ◽

2006 ◽

Vol 28 (4) ◽

pp. 225-229

Author(s):

Nguyen Van Khang

Keyword(s):

Multibody Dynamics ◽

Multibody Systems ◽

Equations Of Motion ◽

Automatic Generation ◽

Matrix Form ◽

Dynamical Equations

In this paper a matrix form of Gibbs-Appel function is recommended for multibody dynamics formulations. The form proposed in this paper seems to be more clear and suitable for automatic generation of dynamical equations of motion. The advantages followed from the formulation proposed are illustrated through an example.

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Automatic generation and automatic analysis of equations of motion from the graphic input of a vibration model.

TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series C ◽

10.1299/kikaic.54.2583 ◽

1988 ◽

Vol 54 (507) ◽

pp. 2583-2590

Author(s):

Kentaro ARAMAKI ◽

Takafumi FUJITA

Keyword(s):

Equations Of Motion ◽

Automatic Generation ◽

Automatic Analysis ◽

Vibration Model

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EQUATIONS OF MOTION OF COMPLEX MULTIBODY SYSTEMS USING KINEMATICAL DIFFERENTIALS

Transactions of the Canadian Society for Mechanical Engineering ◽

10.1139/tcsme-1989-0018 ◽

1989 ◽

Vol 13 (4) ◽

pp. 113-121 ◽

Cited By ~ 23

Author(s):

M. HILLER ◽

A. KECSKEMETHY

Keyword(s):

Multibody Systems ◽

Degrees Of Freedom ◽

Multibody System ◽

Equations Of Motion ◽

Linear Equations ◽

Nonholonomic Systems ◽

Automatic Generation ◽

Minimal Order ◽

Closed Form Solutions ◽

Constraint Equations

In complex multibody systems the motion of the bodies may depend on only a few degrees of freedom. For these systems, the equations of motion of minimal order, although more difficult to obtain, give a very efficient formulation. The present paper describes an approach for the automatic generation of these equations, which avoids the use of LAGRANGE-multipliers. By a particular concept, designated “kinematical differentials”, the problem of determining the partial derivatives required to state the equations of motion is reduced to a simple re-evaluation of the kinematics. These cover the solution of the global position, velocity and acceleration problems, i.e. the motion of all bodies is determined for given generalized (independent) coordinates. For their formulation and solution, the multibody system is mapped to a network of nonlinear transformation elements which are connected by linear equations. Each transformation element, designated “kinematical transformer”, corresponds to an independent multibody loop. This mapping of the constraint equations makes it possible to find closed-form solutions to the kinematics for a wide variety of technical applications, and (via kinematical differentials) leads also to an efficient formulation of the dynamics. The equations are derived for holonomic, scleronomic systems, but can also be extended to general nonholonomic systems.

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A Symbolic Approach for Automatic Generation of the Equations of Motion of Multibody Systems

Multibody System Dynamics ◽

10.1023/b:mubo.0000044319.63215.22 ◽

2004 ◽

Vol 12 (2) ◽

pp. 147-172 ◽

Cited By ~ 39

Author(s):

R. Lot ◽

M. Da Lio

Keyword(s):

Multibody Systems ◽

Equations Of Motion ◽

Automatic Generation ◽

Symbolic Approach

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Two-dimensional leaps in near-critical flow over isolated orography

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2005.1530 ◽

2005 ◽

Vol 461 (2064) ◽

pp. 3747-3763 ◽

Cited By ~ 3

Author(s):

E.R Johnson ◽

G.G Vilenski

Keyword(s):

Unsteady Flow ◽

Equations Of Motion ◽

Fold Increase ◽

Flow Speed ◽

Two Dimensional ◽

Subcritical Flow ◽

One Dimensional ◽

Petviashvili Equation ◽

Lee Wave ◽

Supercritical Flows

This paper describes steady two-dimensional disturbances forced on the interface of a two-layer fluid by flow over an isolated obstacle. The oncoming flow speed is close to the linear longwave speed and the layer densities, layer depths and obstacle height are chosen so that the equations of motion reduce to the forced two-dimensional Korteweg–de Vries equation with cubic nonlinearity, i.e. the forced extended Kadomtsev–Petviashvili equation. The distinctive feature noted here is the appearance in the far lee-wave wake behind obstacles in subcritical flow of a ‘table-top’ wave extending almost one-dimensionally for many obstacles widths across the flow. Numerical integrations show that the most important parameter determining whether this wave appears is the departure from criticality, with the wave appearing in slightly subcritical flows but being destroyed by two-dimensional effects behind even quite long ridges in even moderately subcritical flow. The wave appears after the flow has passed through a transition from subcritical to supercritical over the obstacle and its leading and trailing edges resemble dissipationless leaps standing in supercritical flow. Two-dimensional steady supercritical flows are related to one-dimensional unsteady flows with time in the unsteady flow associated with a slow cross-stream variable in the two-dimensional flows. Thus the wide cross-stream extent of the table-top wave appears to derive from the combination of its occurrence in a supercritical region embedded in the subcritical flow and the propagation without change of form of table-top waves in one-dimensional unsteady flow. The table-top wave here is associated with a resonant steepening of the transition above the obstacle and a consequent twelve-fold increase in drag. Remarkably, the table-top wave is generated equally strongly and extends laterally equally as far behind an axisymmetric obstacle as behind a ridge and so leads to subcritical flows differing significantly from linear predictions.

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Closed-form time derivatives of the equations of motion of rigid body systems

Multibody System Dynamics ◽

10.1007/s11044-021-09796-8 ◽

2021 ◽

Author(s):

Andreas Müller ◽

Shivesh Kumar

Keyword(s):

Rigid Body ◽

Closed Form ◽

Multibody Systems ◽

Equations Of Motion ◽

Alternative Formulation ◽

Dynamics Of Rigid Body ◽

Control Forces ◽

And Control ◽

Derivatives Of ◽

Insight Into

AbstractDerivatives of equations of motion (EOM) describing the dynamics of rigid body systems are becoming increasingly relevant for the robotics community and find many applications in design and control of robotic systems. Controlling robots, and multibody systems comprising elastic components in particular, not only requires smooth trajectories but also the time derivatives of the control forces/torques, hence of the EOM. This paper presents the time derivatives of the EOM in closed form up to second-order as an alternative formulation to the existing recursive algorithms for this purpose, which provides a direct insight into the structure of the derivatives. The Lie group formulation for rigid body systems is used giving rise to very compact and easily parameterized equations.

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EQUIVALENCE OF TWO-DIMENSIONAL GRAVITIES

Modern Physics Letters A ◽

10.1142/s0217732390001414 ◽

1990 ◽

Vol 05 (16) ◽

pp. 1251-1258 ◽

Cited By ~ 4

Author(s):

NOUREDDINE MOHAMMEDI

Keyword(s):

Gauge Theory ◽

Explicit Solution ◽

Light Cone ◽

Equations Of Motion ◽

Two Dimensional ◽

Induced Gravity ◽

Light Cone Gauge ◽

Dimensional Gravity ◽

The Relationship ◽

Chern Simons

We find the relationship between the Jackiw-Teitelboim model of two-dimensional gravity and the SL (2, R) induced gravity. These are shown to be related to a two-dimensional gauge theory obtained by dimensionally reducing the Chern-Simons action of the 2+1 dimensional gravity. We present an explicit solution to the equations of motion of the auxiliary field of the Jackiw-Teitelboim model in the light-cone gauge. A renormalization of the cosmological constant is also given.

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