TY - JOUR
T1 - Half-explicit timestepping schemes on velocity level based on time-discontinuous Galerkin methods
AU - Schindler, Thorsten
AU - Rezaei, Shahed
AU - Kursawe, Jochen
AU - Acary, Vincent
PY - 2015/6/5
Y1 - 2015/6/5
N2 - This paper presents a time-discretization scheme for the simulation of nonsmooth mechanical systems. These consist of rigid and flexible bodies, joints as well as contacts and impacts with dry friction. The benefit of the proposed formalism is both the consistent treatment of velocity jumps, e.g.due to impacts, and the automatic local order elevation in non-impulsive intervals at the same time. For an appropriate treatment of constraints in impulsive and non-impulsive intervals, constraints are implicitly formulated on velocity level in terms of an augmented Lagrangian technique (Alart and Curnier, 1991). They are satisfied exactly without any penetration. For efficiency reasons, all other evaluations are explicit which yields a half-explicit method (Brasey, 1994a,b; Murua, 1995, 1997; Arnold etal., 1998; Hairer etal., 2009, 2010). The numerical scheme is an extended timestepping scheme for nonsmooth dynamics according to Moreau (1999). It is based on time-discontinuous Galerkin methods to carry over higher order trial functions of event-driven integration schemes to consistent timestepping schemes for nonsmooth dynamical systems with friction and impacts. Splitting separates the portion of impulsive contact forces from the portion of non-impulsive contact forces. Impacts are included within the discontinuity of the piecewise continuous trial functions, i.e.,with first-order accuracy. Non-impulsive contact forces are integrated with respect to the local order of the trial functions. In order to satisfy the constraints, a set of nonsmooth equations has to be solved in each time step depending on the number of stages; the solution of the velocity jump together with the corresponding impulse yields another nonsmooth equation. All nonsmooth equations are treated separately by semi-smooth Newton methods. The integration scheme on acceleration level was first introduced in Schindler etal. (2013) labeled "forecasting trapezoidal rule". It was analyzed and applied to a decoupled bouncing ball example concerning principal suitability without taking friction into account. In this work, the approach is algorithmically specified, improved and applied to nonlinear multi-contact examples with friction. It is compared to other numerical schemes and it is shown that the newly proposed integration scheme yields a unified behavior for the description of contact mechanical problems. 2015 Elsevier B.V.
AB - This paper presents a time-discretization scheme for the simulation of nonsmooth mechanical systems. These consist of rigid and flexible bodies, joints as well as contacts and impacts with dry friction. The benefit of the proposed formalism is both the consistent treatment of velocity jumps, e.g.due to impacts, and the automatic local order elevation in non-impulsive intervals at the same time. For an appropriate treatment of constraints in impulsive and non-impulsive intervals, constraints are implicitly formulated on velocity level in terms of an augmented Lagrangian technique (Alart and Curnier, 1991). They are satisfied exactly without any penetration. For efficiency reasons, all other evaluations are explicit which yields a half-explicit method (Brasey, 1994a,b; Murua, 1995, 1997; Arnold etal., 1998; Hairer etal., 2009, 2010). The numerical scheme is an extended timestepping scheme for nonsmooth dynamics according to Moreau (1999). It is based on time-discontinuous Galerkin methods to carry over higher order trial functions of event-driven integration schemes to consistent timestepping schemes for nonsmooth dynamical systems with friction and impacts. Splitting separates the portion of impulsive contact forces from the portion of non-impulsive contact forces. Impacts are included within the discontinuity of the piecewise continuous trial functions, i.e.,with first-order accuracy. Non-impulsive contact forces are integrated with respect to the local order of the trial functions. In order to satisfy the constraints, a set of nonsmooth equations has to be solved in each time step depending on the number of stages; the solution of the velocity jump together with the corresponding impulse yields another nonsmooth equation. All nonsmooth equations are treated separately by semi-smooth Newton methods. The integration scheme on acceleration level was first introduced in Schindler etal. (2013) labeled "forecasting trapezoidal rule". It was analyzed and applied to a decoupled bouncing ball example concerning principal suitability without taking friction into account. In this work, the approach is algorithmically specified, improved and applied to nonlinear multi-contact examples with friction. It is compared to other numerical schemes and it is shown that the newly proposed integration scheme yields a unified behavior for the description of contact mechanical problems. 2015 Elsevier B.V.
KW - Discontinuous Galerkin method
KW - Flexible multibody system
KW - Impact
KW - Index reduction
KW - Nonsmooth dynamics
KW - Timestepping scheme
UR - http://www.scopus.com/inward/record.url?scp=84926490564&partnerID=8YFLogxK
U2 - 10.1016/j.cma.2015.03.001
DO - 10.1016/j.cma.2015.03.001
M3 - Article
AN - SCOPUS:84926490564
SN - 0045-7825
VL - 290
SP - 250
EP - 276
JO - Computer Methods in Applied Mechanics and Engineering
JF - Computer Methods in Applied Mechanics and Engineering
ER -