In this paper, parallel O(log n) algorithms for computation of rigid multibody dynamics are developed. These parallel algorithms are derived by parallelization of new O(n) algorithms for the problem. The underlying feature of these O(n) algorithms is a drastically different strategy for decomposition of interbody force which leads to a new factorization of the mass matrix (M). Specifically, it is shown that a factorization of the inverse of the mass matrix in the form of the Schur Complement is derived as M(exp -1) = C - B(exp *)A(exp -1)B, wherein matrices C, A, and B are block tridiagonal matrices. The new O(n) algorithm is then derived as a recursive implementation of this factorization of M(exp -1). For the closed-chain systems, similar...
The algorithms used for solving the forward dynamics problem of a complex multibody system are essen...
An efficient O(mN) algorithm for dynamic simulation of simple closed-chain robotic mechanisms is pre...
This paper deals with the decrease in CPU time necessary for simulating multibody systems by massive...
A unifying framework for various formulations of the dynamics of open-chain rigid multibody systems ...
Abstract In this paper, it is shown how to obtain recursive dynamics algorithms for multibody system...
The development of an O(log2N) parallel algorithm for the manipulator inertia matrix is presented. I...
The analysis of the efficiency of algorithms resulting from Kane's Equation for serial and parallel ...
This paper describes a multibody dynamics algorithm formulated for parallel implementation on multip...
A multibody dynamics formulation has been developed for the purposes of real-time simulation of lar...
Parallel computation of manipulator forward dynamics is investigated. Considering three classes of a...
Rigid multibody systems have been studied extensivley due to its direct application in design and an...
In this paper an approach for the application of parallel processing to the dynamic analysis of robo...
This paper describes a new factorization of the inverse of the joint-space inertia matrix M. In this...
Computationally efficient approaches to the solution of the dynamics of multibody systems are presen...
We report on an efficient adaptive N-body method which we have recently designed and implemented. Th...
The algorithms used for solving the forward dynamics problem of a complex multibody system are essen...
An efficient O(mN) algorithm for dynamic simulation of simple closed-chain robotic mechanisms is pre...
This paper deals with the decrease in CPU time necessary for simulating multibody systems by massive...
A unifying framework for various formulations of the dynamics of open-chain rigid multibody systems ...
Abstract In this paper, it is shown how to obtain recursive dynamics algorithms for multibody system...
The development of an O(log2N) parallel algorithm for the manipulator inertia matrix is presented. I...
The analysis of the efficiency of algorithms resulting from Kane's Equation for serial and parallel ...
This paper describes a multibody dynamics algorithm formulated for parallel implementation on multip...
A multibody dynamics formulation has been developed for the purposes of real-time simulation of lar...
Parallel computation of manipulator forward dynamics is investigated. Considering three classes of a...
Rigid multibody systems have been studied extensivley due to its direct application in design and an...
In this paper an approach for the application of parallel processing to the dynamic analysis of robo...
This paper describes a new factorization of the inverse of the joint-space inertia matrix M. In this...
Computationally efficient approaches to the solution of the dynamics of multibody systems are presen...
We report on an efficient adaptive N-body method which we have recently designed and implemented. Th...
The algorithms used for solving the forward dynamics problem of a complex multibody system are essen...
An efficient O(mN) algorithm for dynamic simulation of simple closed-chain robotic mechanisms is pre...
This paper deals with the decrease in CPU time necessary for simulating multibody systems by massive...
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