Open AccessA Differential Algebraic Method to Approximate Nonsmooth Mechanical Systems by Ordinary Differential Equations
Author(s) -
Xiaogang Xiong,
Ryo Kikuuwe,
Motoji Yamamoto
Publication year - 2013
Publication title -
journal of applied mathematics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.307
H-Index - 43
eISSN - 1687-0042
pISSN - 1110-757X
DOI - 10.1155/2013/320276
Subject(s) - mathematics , classification of discontinuities , differential inclusion , ode , ordinary differential equation , differential algebraic geometry , differential algebraic equation , algebraic number , differential equation , smoothing , differential (mechanical device) , algebraic equation , mechanical system , mathematical analysis , nonlinear system , computer science , physics , statistics , quantum mechanics , artificial intelligence , thermodynamics
Nonsmooth mechanical systems, which are mechanical systems involving dry friction and rigid unilateral contact, are usually described as differential inclusions (DIs), that is, differential equations involving discontinuities. Those DIs may be approximated by ordinary differential equations (ODEs) by simply smoothing the discontinuities. Such approximations, however, can produce unrealistic behaviors because the discontinuous natures of the original DIs are lost. This paper presents a new algebraic procedure to approximate DIs describing nonsmooth mechanical systems by ODEs with preserving the discontinuities. The procedure is based on the fact that the DIs can be approximated by differential algebraic inclusions (DAIs), and thus they can be equivalently rewritten as ODEs. The procedure is illustrated by some examples of nonsmooth mechanical systems with simulation results obtained by the fourth-order Runge-Kutta method
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