A number of strategies can be followed for the real-time simulation of multibody systems. The main contributing factor to computational efficiency is usually the algorithm itself (the number of equations and their structure, the number of coordinates, the time integration scheme, etc.). Additional (but equally important) aspects have to do with implementation (linear solvers, sparse matrices, parallel computing, etc.). In this paper, an iterative refinement technique is introduced into a semirecursive multibody formulation. First, the formulation is summarized and its basic features are highlighted. Then, the basic goal is to iteratively solve the fundamental system of equations to obtain the accelerations. The iterative process is applied to compute corrections of the solution in an economic way, terminating as soon as a given precision is reached. We show that, upon implementation of this method, the computation time can be reduced at a very low implementation and accuracy costs. Two vehicles are simulated to prove the numerical benefits, namely a 16-degrees-of-freedom (DOF) sedan vehicle and a 40-degrees-of-freedom semitrailer truck. In short, a simple method to iteratively solve for the accelerations of vehicle systems in an efficient way is presented.
Issue Section:
Research Papers
References
1.
Bowdler
, H. J.
, Martin
, R. S.
, Peters
, G.
, and Wilkinson
, J. H.
, 1966
, “Solution of Real and Complex Systems of Linear Equations
,” Numerische Math.
, 8
(3
), pp. 217
–234
.2.
Wilkinson
, J. H.
, 1994
, Rounding Errors in Algebraic Processes
, Dover Publications
, Mineola, NY
.3.
Moler
, C. B.
, 1967
, “Iterative Refinement in Floating Point
,” J. ACM
, 14
(2
), pp. 316
–321
.4.
Forsythe
, G. E.
, and Moler
, C. B.
, 1967
, Computer Solution of Linear Algebraic Systems
, Prentice Hall
, Englewood Cliffs, NJ
.5.
Stewart
, G. W.
, 1973
, Introduction to Matrix Computations
, Academic Press
, New York
.6.
Jankowski
, M.
, and Woźniakowski
, H.
, 1977
, “Iterative Refinement Implies Numerical Stability
,” BIT Numer. Math.
, 17
(3
), pp. 303
–311
.7.
Skeel
, R. D.
, 1980
, “Iterative Refinement Implies Numerical Stability for Gaussian Elimination
,” Math. Comp.
, 35
(151
), pp. 817
–832
.8.
Higham
, N.
, 2002
, Accuracy and Stability of Numerical Algorithms
, SIAM
, Philadelphia, PA
.9.
Demmel
, J.
, Hida
, Y.
, Kahan
, W.
, Li
, X. S.
, Mukherjee
, S.
, and Riedy
, E. J.
, 2006
, “Error Bounds From Extra-Precise Iterative Refinement
,” ACM Trans. Math. Software
, 32
(2
), pp. 325
–351
.10.
Arioli
, M.
, Demmel
, J. W.
, and Duff
, I. S.
, 1989
, “Solving Sparse Linear Systems With Sparse Backward Error
,” SIAM J. Matrix Anal. Appl.
, 10
(2
), pp. 165
–190
.11.
Higham
, N. J.
, 1997
, “Iterative Refinement for Linear Systems and LAPACK
,” IMA J. Numer. Anal.
, 17
(4
), pp. 495
–509
.12.
Demmel
, J.
, Hida
, Y.
, Riedy
, E. J.
, and Li
, X. S.
, 2009
, “Extra-Precise Iterative Refinement for Overdetermined Least Squares Problems
,” ACM Trans. Math. Software
, 35
(4
), p. 28.13.
Faure
, F.
, 1999
, “Fast Iterative Refinement of Articulated Solid Dynamics
,” IEEE Trans. Visualization Comput. Graphics
, 5
(3
), pp. 268
–276
.14.
Anitescu
, M.
, and Hart
, G. D.
, 2004
, “A Fixed-Point Iteration Approach for Multibody Dynamics With Contact and Small Friction
,” Math. Program.
, 101
(1
), pp. 3
–32
.15.
Golub
, G. H.
, and Varga
, R. S.
, 1961
, “Chebyshev Semi-Iterative Methods, Successive Overrelaxation Iterative Methods, and Second Order Richardson Iterative Methods
,” Numerische Math.
, 3
(1
), pp. 147
–156
.16.
Gutknecht
, M. H.
, and Röllin
, S.
, 2002
, “The Chebyshev Iteration Revisited
,” Parallel Comput.
, 28
(2
), pp. 263
–283
.17.
Gutknecht
, M. H.
, and Strakos
, Z.
, 2000
, “Accuracy of Two Three-Term and Three Two-Term Recurrences for Krylov Space Solvers
,” SIAM J. Matrix Anal. Appl.
, 22
(1
), pp. 213
–229
.18.
Arioli
, M.
, and Scott
, J.
, 2014
, “Chebyshev Acceleration of Iterative Refinement
,” Numer. Algorithms
, 66
(3
), pp. 591
–608
.19.
González
, M.
, González
, F.
, Dopico
, D.
, and Luaces
, A.
, 2007
, “On the Effect of Linear Algebra Implementations in Real-Time Multibody System Dynamics
,” Comput. Mech.
, 41
(4
), pp. 607
–615
.20.
Hidalgo
, A. F.
, and García de Jalón
, J.
, 2015
, “Real-Time Dynamic Simulations of Large Road Vehicles Using Dense, Sparse, and Parallelization Techniques
,” ASME J. Comput. Nonlinear Dyn.
, 10
(3
), p. 031005
.21.
García de Jalón
, J.
, Álvarez
, E.
, de Ribera
, F.
, Rodríguez
, I.
, and Funes
, F.
, 2005
, “A Fast and Simple Semi-Recursive Formulation for Multi-Rigid-Body Systems
,” Advances in Computational Multibody Systems
(Computational Methods in Applied Sciences), Vol. 2
, J.
Ambrosio
, ed., Springer
, Dordrecht, The Netherlands
, pp. 1
–23
.22.
Pan
, Y.
, Callejo
, A.
, Bueno
, J. L.
, Wehage
, R. A.
, and García de Jalón
, J.
, 2017
, “Efficient and Accurate Modeling of Rigid Rods
,” Multibody Syst. Dyn.
, 40
(1
), pp. 23
–42
.23.
Callejo
, A.
, and García de Jalón
, J.
, 2015
, “Vehicle Suspension Identification Via Algorithmic Computation of State and Design Sensitivities
,” ASME J. Mech. Des.
, 137
(2
), p. 021403
.24.
Callejo
, A.
, García de Jalón
, J.
, Luque
, P.
, and Mántaras
, D. A.
, 2015
, “Sensitivity-Based, Multi-Objective Design of Vehicle Suspension Systems
,” ASME J. Comput. Nonlinear Dyn.
, 10
(3
), p. 031008
.25.
Funes
, F. J.
, and García de Jalón
, J.
, 2016
, “An Efficient Dynamic Formulation for Solving Rigid and Flexible Multibody Systems Based on Semirecursive Method and Implicit Integration
,” ASME J. Comput. Nonlinear Dyn.
, 11
(5
), p. 051001
.26.
Rodríguez
, J. I.
, Jiménez
, J. M.
, Funes
, F. J.
, and García de Jalón
, J.
, 2004
, “Recursive and Residual Algorithms for the Efficient Numerical Integration of Multi-Body Systems
,” Multibody Syst. Dyn.
, 11
(4
), pp. 295
–320
.27.
García de Jalón
, J.
, Callejo
, A.
, and Hidalgo
, A. F.
, 2012
, “Efficient Solution of Maggi's Equations
,” ASME J. Comput. Nonlinear Dyn.
, 7
(2
), p. 021003
.28.
Callejo
, A.
, Pan
, Y.
, Ricón
, J. L.
, Kövecses
, J.
, and García de Jalón
, J.
, 2016
, “Comparison of Semirecursive and Subsystem Synthesis Algorithms for the Efficient Simulation of Multibody Systems
,” ASME J. Comput. Nonlinear Dyn.
, 12
(1
), p. 011020
.29.
Jerkovsky
, W.
, 1978
, “The Structure of Multibody Dynamic Equations
,” J. Guid. Control Dyn.
, 1
(3
), pp. 173
–182
.30.
Kim
, S.
, and Vanderploeg
, M.
, 1986
, “A General and Efficient Method for Dynamic Analysis of Mechanical System Using Velocity Transformations
,” ASME J. Mech. Des.
, 108
(2
), pp. 176
–182
.31.
McPhee
, J. J.
, 1996
, “On the Use of Linear Graph Theory in Multibody System Dynamics
,” Nonlinear Dyn.
, 9
(1
), pp. 73
–90
.32.
Negrut
, D.
, Serban
, R.
, and Potra
, F. A.
, 1997
, “A Topology Based Approach to Exploiting Sparsity in Multibody Dynamics: Joint Formulation
,” Mech. Struct. Mach.
, 25
(2
), pp. 221
–241
.33.
Butcher
, J. C.
, 1963
, “Coefficients for the Study of Runge–Kutta Integration Processes
,” J. Aust. Math. Soc.
, 3
(2
), pp. 185
–201
.34.
Butcher
, J. C.
, 2008
, Numerical Methods for Ordinary Differential Equations
, Wiley
, Chichester, UK
.35.
Davies
, P. I.
, Higham
, N. J.
, and Tisseur
, F.
, 2001
, “Analysis of the Cholesky Method With Iterative Refinement for Solving the Symmetric Definite Generalized Eigenproblem
,” SIAM J. Matrix Anal. Appl.
, 23
(2
), pp. 472
–493
.36.
Pacejka
, H. B.
, 2012
, Tyre and Vehicle Dynamics
, Elsevier Butterworth-Heinemann
, Oxford, UK
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