A Combined Penalty and Recursive Real-Time Formulation for Multibody Dynamics

Cuadrado, Javier; Dopico, Domingo Calvo; González, Manuel; Naya, Miguel Ángel

doi:10.1115/1.1758257

Cited by 64 publications

(75 citation statements)

References 15 publications

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“…Analogously, Equation (37) shows the difference equations of the integrator which express the velocities and accelerations at the second stage as functions of the positions at the same stage, plus some positions, velocities and accelerations at the current time-step and the first stage. Therefore, Equations (36) and (37) possess the same form as the difference equations of Newmark-type integrators, which means that the strategy followed in the authors' previous works to combine the three dynamic formulations with those integrators at time-step level [1,4], may now be applied with SDIRK integrators at stage level. As said in Section 2, the motion equations for the two formulations in dependent co-ordinates were stated through an index-3 augmented Lagrangian scheme [3] …”

Section: Alternative Bmentioning

confidence: 96%

“…The three formulations being compared have previously shown an excellent aptitude for realtime purposes [1], since they are efficient, i.e. they provide very fast calculation of the function evaluation, and they are robust, which means that they can perform large time-steps without losing stability.…”

Section: The Proposed Dynamic Formulationsmentioning

confidence: 99%

“…The hybrid method [1] shares the first stage with the topological method previously described, i.e. until the equations of motion are established in relative co-ordinates, dependent in general, for the open-loop version of the mechanism.…”

Section: The Proposed Dynamic Formulationsmentioning

confidence: 99%

“…In a first work [1], the authors presented a new real-time formulation for the dynamics of multibody systems, which encompasses high ranks of efficiency, accuracy, robustness and easiness of implementation. The new method, called hybrid, was obtained as combination of a topological semi-recursive formulation based on velocity transformations [2], and a global penalty formulation for closed-loops consideration [3].…”

Section: Introductionmentioning

confidence: 99%

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Two implementations of IRK integrators for real‐time multibody dynamics

Dopico

Lugrís

González

et al. 2005

Numerical Meth Engineering

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SUMMARYRecently, several authors have proposed the use of implicit Runge-Kutta (IRK) integrators for the dynamics of multibody systems. On the other hand, Newmark-type or structural integrators have shown to be appropriate when real-time performance is demanded in that field. Therefore, the following question arises: might the IRK integrators be suitable for real-time purposes? And, provided the answer is positive: might they be preferable to the Newmark-type family? This paper reports an investigation which has been conducted by the authors in order to get insight into the two questions formulated above. Since, based on previous experiences, it can be suspected that the performance of the integrators may be dependent on the type of dynamic formulation applied, the following three formulations have been considered for the study: a global penalty formulation in dependent natural co-ordinates (many constraints), a topological semi-recursive penalty formulation in dependent relative co-ordinates (few constraints), and a topological semi-recursive formulation in independent relative co-ordinates (no constraints).As representative of the IRK family, a two-stage SDIRK integrator has been selected due to its low associated computational burden, while, on the side of the structural integrators, the trapezoidal rule has been chosen. Two alternative implementations have been proposed to combine the dynamic formulations and the SDIRK integrator.A very demanding maneuver of the whole model of a vehicle has been simulated through all the possible combinations dynamic-formulation/integrator, for different time-steps. Conclusions have been drawn based on the obtained results, which provide some practical criteria for those interested in achieving real-time performance for large and complex multibody systems.

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Section: Alternative Bmentioning

confidence: 96%

Section: The Proposed Dynamic Formulationsmentioning

confidence: 99%

Section: The Proposed Dynamic Formulationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Two implementations of IRK integrators for real‐time multibody dynamics

Dopico

Lugrís

González

et al. 2005

Numerical Meth Engineering

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“…1. Pressure rates for the volumes on both sides of the cylinder piston are derived from fluid continuity and compressibility considerations [5] (2) where V A and V B are the volumes at each side of the cylinder andV A ,V B are their speeds of variation. Q PA , Q PB represent the flow incoming to chamber A or B from the pump, Q T A , Q T B are the flows to the tank from chamber A or B, while Q BA constitutes the leakage flow and is commonly neglected.…”

Section: Introductionmentioning

confidence: 99%

An Efficient Unified Method for the Combined Simulation of Multibody and Hydraulic Dynamics: Comparison with Simplified and Co-Integration Approaches

Naya¹,

Cuadrado²,

Dopico³

et al. 2011

Archive of Mechanical Engineering

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A formulation developed at the Laboratory of Mechanical Engineering allows robust and efficient simulation of large and complex multibody systems. Simulators of cars, excavators and other systems have been developed showing that real-time simulations are possible even when facing demanding manoeuvres.Hydraulic actuators are present in many industrial applications of multibody systems, like in the case of the heavy machinery field. When simulating the dynamics of this kind of problems that combine multibody dynamics and hydraulics, two different approaches are common: to resort to kinematically guide the variable length of the actuator, thus avoiding the need to consider the dynamics of the hydraulic system; or to perform a multi-rate integration of both subsystems if a more detailed description of the problem is required, for example, when the objective of the study is to optimize the pump control.This work addresses the inclusion of hydraulic actuators dynamics in the abovementioned self-developed multibody formulation, thus leading to a unified approach. An academic example serves to compare the efficiency, accuracy and ease of implementation of the simplified (kinematic guidance), multi-rate and unified approaches. Such a comparison is the main contribution of the paper, as it may serve to provide guidelines on which approach to select depending on the problem characteristics.

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