Search results for " Simulation"

showing 10 items of 4034 documents

A novel method based on augmented Markov vector process for the time-variant extreme value distribution of stochastic dynamical systems enforced by P…

2020

Abstract The probability density function (PDF) of the time-variant extreme value process for structural responses is of great importance. Poisson white noise excitation occurs widely in practical engineering problems. The extreme value distribution of the response of systems excited by Poisson white noise processes is still not yet readily available. For this purpose, in the present paper, a novel method based on the augmented Markov vector process for the PDF of the time-variant extreme value process for a Poisson white noise driven dynamical system is proposed. Specifically, the augmented Markov vector (AMV) process is constructed by combining the extreme value process and its underlying…

Numerical AnalysisMarkov chainDynamical systems theoryComputer scienceApplied MathematicsProbability density functionWhite noisePoisson distribution01 natural sciencesStochastic dynamic system010305 fluids & plasmassymbols.namesakeAugmented Markov vector proceJoint probability distributionModeling and Simulation0103 physical sciencesPoisson white noise excitationsymbolsGeneralized extreme value distributionApplied mathematicsSettore ICAR/08 - Scienza Delle Costruzioni010306 general physicsExtreme value theoryTime-variant extreme value processCommunications in Nonlinear Science and Numerical Simulation

researchProduct

Electrophoretic properties of charged colloidal suspensions: Application of a hybrid MD/LB method

2006

Abstract Electrophoretic properties of charged colloidal suspensions are investigated using a hybrid simulation method. In this method, the colloidal particles are propagated via Newton’s equations of motion using molecular dynamics (MD), while they are coupled to a structureless solvent that is modelled by the Lattice-Boltzmann (LB) method.

Numerical AnalysisMaterials scienceGeneral Computer ScienceApplied Mathematicsdigestive oral and skin physiologyEquations of motionTheoretical Computer ScienceCondensed Matter::Soft Condensed MatterSolventElectrophoresisMolecular dynamicsColloidClassical mechanicsChemical physicsColloidal particleModeling and SimulationMathematics and Computers in Simulation

researchProduct

Numerical Study of Two Sparse AMG-methods

2003

A sparse algebraic multigrid method is studied as a cheap and accurate way to compute approximations of Schur complements of matrices arising from the discretization of some symmetric and positive definite partial differential operators. The construction of such a multigrid is discussed and numerical experiments are used to verify the properties of the method.

Numerical AnalysisMathematical optimizationDiscretizationApplied MathematicsNumerical analysisMathematicsofComputing_NUMERICALANALYSISPositive-definite matrixFinite element methodComputational MathematicsMultigrid methodModeling and SimulationComputingMethodologies_SYMBOLICANDALGEBRAICMANIPULATIONSchur complementApplied mathematicsPartial derivativeAnalysisMathematicsSparse matrixESAIM: Mathematical Modelling and Numerical Analysis

researchProduct

Well-balanced bicharacteristic-based scheme for multilayer shallow water flows including wet/dry fronts

2013

The aim of this paper is to present a new well-balanced finite volume scheme for two-dimensional multilayer shallow water flows including wet/dry fronts. The ideas, presented here for the two-layer model, can be generalized to a multilayer case in a straightforward way. The method developed here is constructed in the framework of the Finite Volume Evolution Galerkin (FVEG) schemes. The FVEG methods couple a finite volume formulation with evolution operators. The latter are constructed using the bicharacteristics of multidimensional hyperbolic systems. However, in the case of multilayer shallow water flows the required eigenstructure of the underlying equations is not readily available. Thus…

Numerical AnalysisMathematical optimizationFinite volume methodPhysics and Astronomy (miscellaneous)Applied MathematicsReliability (computer networking)Hyperbolic systemsComputer Science ApplicationsComputational MathematicsWaves and shallow waterModeling and SimulationScheme (mathematics)Applied mathematicsGalerkin methodMathematicsJournal of Computational Physics

researchProduct

Discrete multiresolution based on hermite interpolation: computing derivatives

2004

Abstract Harten’s framework for multiresolution representation of data has been extended by Warming and Beam in [SIAM J. Sci. Comp. 22 (2000) 1269] to include Hermite interpolation. It needs the point-values of the derivative, which are usually unavailable, so they have to be approximated. In this work we show that the way in which the derivatives are approximated is crucial for the success of the method, and we present a new way to compute them that makes the scheme adequate for non-smooth data.

Numerical AnalysisMathematical optimizationHermite splineApplied MathematicsMonotone cubic interpolationBirkhoff interpolationMultivariate interpolationCubic Hermite splineNearest-neighbor interpolationHermite interpolationModeling and SimulationApplied mathematicsMathematicsInterpolationCommunications in Nonlinear Science and Numerical Simulation

researchProduct

Comparison between adaptive and uniform discontinuous Galerkin simulations in dry 2D bubble experiments

2013

Accepted by the Journal of Computational Physics Adaptive mesh refinement generally aims to increase computational efficiency without compromising the accuracy of the numerical solution. However it is an open question in which regions the spatial resolution can actually be coarsened without affecting the accuracy of the result. This question is investigated for a specific example of dry atmospheric convection, namely the simulation of warm air bubbles. For this purpose a novel numerical model is developed that is tailored towards this specific application. The compressible Euler equations are solved with a Discontinuous Galerkin method. Time integration is done with an IMEXmethod and the dy…

Numerical AnalysisMathematical optimizationPhysics and Astronomy (miscellaneous)Mathematical modelAdaptive mesh refinementApplied MathematicsNumerical analysisAdaptive Mesh RefinementCompressible flowComputer Science ApplicationsEuler equationsDry Warm Air BubbleComputational Mathematicssymbols.namesakeMeteorologyIMEXDiscontinuous Galerkin methodModeling and SimulationDiscontinuous GalerkinsymbolsApplied mathematicsGalerkin methodNavier–Stokes equationsMathematicsJournal of Computational Physics

researchProduct

Constructing adaptive generalized polynomial chaos method to measure the uncertainty in continuous models: A computational approach

2015

Due to errors in measurements and inherent variability in the quantities of interest, models based on random differential equations give more realistic results than their deterministic counterpart. The generalized polynomial chaos (gPC) is a powerful technique used to approximate the solution of these equations when the random inputs follow standard probability distributions. But in many cases these random inputs do not have a standard probability distribution. In this paper, we present a step-by-step constructive methodology to implement directly a useful version of adaptive gPC for arbitrary distributions, extending the applicability of the gPC. The paper mainly focuses on the computation…

Numerical AnalysisMathematical optimizationPolynomial chaosGeneral Computer ScienceDifferential equationApplied MathematicsComputingConstructiveMeasure (mathematics)Theoretical Computer ScienceCHAOS (operating system)Generalized polynomialRandom differential equationsModeling and SimulationConvergence (routing)Applied mathematicsProbability distributionMATEMATICA APLICADAAdaptive polynomial chaosMathematics

researchProduct

A semi-Lagrangian AMR scheme for 2D transport problems in conservation form

2013

In this paper, we construct a semi-Lagrangian (SL) Adaptive-Mesh-Refinement (AMR) solver for 1D and 2D transport problems in conservation form. First, we describe the a-la-Harten AMR framework: the adaptation process selects a hierarchical set of grids with different resolutions depending on the features of the integrand function, using as criteria the point value prediction via interpolation from coarser meshes, and the appearance of large gradients. We integrate in time by reconstructing at the feet of the characteristics through the Point-Value Weighted Essentially Non-Oscillatory (PV-WENO) interpolator. We propose, then, an extension to the 2D setting by making the time integration dime…

Numerical AnalysisMathematical optimizationSpeedupPhysics and Astronomy (miscellaneous)Adaptive mesh refinementApplied MathematicsFunction (mathematics)SolverComputer Science ApplicationsComputational MathematicsStrang splittingModeling and SimulationApplied mathematicsPolygon meshConservation formMathematicsInterpolationJournal of Computational Physics

researchProduct

Fractional differential equations solved by using Mellin transform

2014

In this paper, the solution of the multi-order differential equations, by using Mellin Transform, is proposed. It is shown that the problem related to the shift of the real part of the argument of the transformed function, arising when the Mellin integral operates on the fractional derivatives, may be overcame. Then, the solution may be found for any fractional differential equation involving multi-order fractional derivatives (or integrals). The solution is found in the Mellin domain, by solving a linear set of algebraic equations, whose inverse transform gives the solution of the fractional differential equation at hands.

Numerical AnalysisMellin transformApplied MathematicsMathematical analysisRamanujan's master theoremIntegral equationFractional differential equationFractional calculusWiener–Hopf methodsymbols.namesakeMathematics - Analysis of PDEsSelf-similarity of inverse Mellin transform.Modeling and SimulationLaplace transform applied to differential equationssymbolsMellin inversion theoremFOS: MathematicsTwo-sided Laplace transformMellin transformMathematicsAnalysis of PDEs (math.AP)

researchProduct

Mellin transform approach for the solution of coupled systems of fractional differential equations

2015

In this paper, the solution of a multi-order, multi-degree-of-freedom fractional differential equation is addressed by using the Mellin integral transform. By taking advantage of a technique that relates the transformed function, in points of the complex plane differing in the value of their real part, the solution is found in the Mellin domain by solving a linear set of algebraic equations. The approximate solution of the differential (or integral) equation is restored, in the time domain, by using the inverse Mellin transform in its discretized form.

Numerical AnalysisMellin transformLaplace transformApplied MathematicsMathematical analysisMulti degree of freedom systemsRamanujan's master theoremIntegral equationFractional differential equationWiener–Hopf methodsymbols.namesakeModeling and SimulationLaplace transform applied to differential equationsComputingMethodologies_SYMBOLICANDALGEBRAICMANIPULATIONsymbolsMellin inversion theoremTwo-sided Laplace transformMellin transformMathematicsCommunications in Nonlinear Science and Numerical Simulation

researchProduct