A semi-analytical approach to molecular dynamics

Michels, Dominik L.; Desbrun, Mathieu

doi:10.1016/j.jcp.2015.10.009

Cited by 13 publications

(5 citation statements)

References 56 publications

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“…The vector Λ(t) describes external forces acting on the system at time t. We are searching for functions x(t), υ(t) = ẋ(t), and a(t) = ẍ(t) satisfying ( 12) for all t with initial conditions x(t 0 ) = x 0 and υ(t 0 ) = υ 0 . For the employment of the generalized α-method, we can write the integration scheme with respect to (12) as follows:…”

Section: A Generalized α-Methodsmentioning

confidence: 99%

“…Our approach combines the ideas of numerical exponential integration (see e.g. [8,12] and references therein) and symbolic integration of the intermediate system of nonlinear ordinary differential equations describing the dynamics of the arbitrary vector function in the general solution to the kinematic part in terms of the module of the twist vector function. The symbolic part of the integration is performed by means of Maple.…”

Section: Introductionmentioning

confidence: 99%

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Symbolic-Numeric Integration of the Dynamical Cosserat Equations

Lyakhov

Gerdt

Weber

et al. 2017

Computer Algebra in Scientific Computing

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Abstract. We devise a symbolic-numeric approach to the integration of the dynamical part of the Cosserat equations, a system of nonlinear partial differential equations describing the mechanical behavior of slender structures, like fibers and rods. This is based on our previous results on the construction of a closed form general solution to the kinematic part of the Cosserat system. Our approach combines methods of numerical exponential integration and symbolic integration of the intermediate system of nonlinear ordinary differential equations describing the dynamics of one of the arbitrary vector-functions in the general solution of the kinematic part in terms of the module of the twist vector-function. We present an experimental comparison with the well-established generalized α-method illustrating the computational efficiency of our approach for problems in structural mechanics.

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Section: A Generalized α-Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Symbolic-Numeric Integration of the Dynamical Cosserat Equations

Lyakhov

Gerdt

Weber

et al. 2017

Computer Algebra in Scientific Computing

Self Cite

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“…For quasilinear Maxwell's equations, the numerical experiments in [31] confirm this computational potential. Further, their efficiency was demonstrated in [26,28] in the application to molecular dynamics and nonlinear coupled oscillators. Besides the Krylov methods to compute a matrix function applied to a vector, a different approach is considered in [22].…”

Section: Introductionmentioning

confidence: 99%

Full discretization error analysis of exponential integrators for semilinear wave equations

Dörich¹,

Leibold²

2022

Math. Comp.

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In this article we prove full discretization error bounds for semilinear second-order evolution equations. We consider exponential integrators in time applied to an abstract nonconforming semi discretization in space. Since the fully discrete schemes involve the spatially discretized semigroup, a crucial point in the error analysis is to eliminate the continuous semigroup in the representation of the exact solution. Hence, we derive a modified variation-ofconstants formula driven by the spatially discretized semigroup which holds up to a discretization error. Our main results provide bounds for the full discretization errors for exponential Adams and explicit exponential Runge-Kutta methods. We show convergence with the stiff order of the corresponding exponential integrator in time, and errors stemming from the spatial discretization.As an application of the abstract theory, we consider an acoustic wave equation with kinetic boundary conditions, for which we also present some numerical experiments to illustrate our results.

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“…Typical examples are models in molecular dynamics (see e.g. [36]), chemical kinetics, combustion, mechanical vibrations (mass-spring-damper models), visual computing (specially in computer animation), computational fluid dynamics, meteorology, etc., just to name Vu Thai Luan Department of Mathematics, Southern Methodist University, PO Box 750156, Dallas, TX 75275-0156, USA, e-mail: vluan@smu.edu Dominik L. Michels Computational Sciences Group, Visual Computing Center, King Abdullah University of Science and Technology, Thuwal, 23955, KSA, e-mail: dominik.michels@kaust.edu.sa a few. They are usually formulated as systems of stiff differential equations which can be cast in the general form…”

Section: Introductionmentioning

confidence: 99%

Explicit Exponential Rosenbrock Methods and their Application in Visual Computing

Luan,

Michels

2018

Preprint

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We introduce a class of explicit exponential Rosenbrock methods for the time integration of large systems of stiff differential equations. Their application with respect to simulation tasks in the field of visual computing is discussed where these time integrators have shown to be very competitive compared to standard techniques. In particular, we address the simulation of elastic and nonelastic deformations as well as collision scenarios focusing on relevant aspects like stability and energy conservation, large stiffnesses, high fidelity and visual accuracy.

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A semi-analytical approach to molecular dynamics

Cited by 13 publications

References 56 publications

Symbolic-Numeric Integration of the Dynamical Cosserat Equations

Symbolic-Numeric Integration of the Dynamical Cosserat Equations

Full discretization error analysis of exponential integrators for semilinear wave equations

Explicit Exponential Rosenbrock Methods and their Application in Visual Computing

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