Search results for "Equations"

showing 10 items of 955 documents

Random vibration of linear and nonlinear structural systems with singular matrices: A frequency domain approach

2017

Abstract A frequency domain methodology is developed for stochastic response determination of multi-degree-of-freedom (MDOF) linear and nonlinear structural systems with singular matrices. This system modeling can arise when a greater than the minimum number of coordinates/DOFs is utilized, and can be advantageous, for instance, in cases of complex multibody systems where the explicit formulation of the equations of motion can be a nontrivial task. In such cases, the introduction of additional/redundant DOFs can facilitate the formulation of the equations of motion in a less labor intensive manner. Specifically, relying on the generalized matrix inverse theory, a Moore-Penrose (M-P) based f…

Frequency responseAcoustics and Ultrasonics02 engineering and technologyCondensed Matter PhysicAcoustics and Ultrasonic01 natural sciences0203 mechanical engineering0103 physical sciencesStochastic dynamicMechanics of Material010301 acousticsMoore–Penrose pseudoinverseMathematicsCovariance matrixMechanical EngineeringMathematical analysisLinear systemEquations of motionCondensed Matter PhysicsMoore-Penrose inverseFrequency domainNonlinear systemFrequency domain; Moore-Penrose inverse; Random vibration; Singular matrix; Stochastic dynamics; Condensed Matter Physics; Mechanics of Materials; Acoustics and Ultrasonics; Mechanical Engineering020303 mechanical engineering & transportsMechanics of MaterialsFrequency domainRandom vibrationSingular matrixRandom vibration
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A High-Resolution Penalization Method for large Mach number Flows in the presence of Obstacles

2009

International audience; A penalization method is applied to model the interaction of large Mach number compressible flows with obstacles. A supplementary term is added to the compressible Navier-Stokes system, seeking to simulate the effect of the Brinkman-penalization technique used in incompressible flow simulations including obstacles. We present a computational study comparing numerical results obtained with this method to theoretical results and to simulations with Fluent software. Our work indicates that this technique can be very promising in applications to complex flows.

General Computer ScienceComputational fluid dynamics01 natural sciencesCompressible flow010305 fluids & plasmas[SPI.MECA.MEFL]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Fluids mechanics [physics.class-ph]Physics::Fluid DynamicsShock Waves.symbols.namesakeIncompressible flow0103 physical sciencesPenalty methodComplex geometries[PHYS.MECA.MEFL]Physics [physics]/Mechanics [physics]/Fluid mechanics [physics.class-ph]0101 mathematicsBrinkman PenalizationChoked flowMathematicsbusiness.industry[SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environmentGeneral EngineeringMechanics[INFO.INFO-MO]Computer Science [cs]/Modeling and Simulation010101 applied mathematicsClassical mechanicsCompressible Navier-Stokes EquationsMach numberShock WavesMesh generationCompressibilitysymbolsbusiness[MATH.MATH-NA]Mathematics [math]/Numerical Analysis [math.NA]
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Implicit-explicit and explicit projection schemes for the unsteady incompressible Navier–Stokes equations using a high-order dG method

2017

Abstract A modified version of the projection scheme [19] is proposed, which does not show a lower limit for the time step in contrast to the limits of stability observed numerically for some projection type schemes. An advantage of the proposed scheme is that the right-hand side of the Poisson equation for the pressure is independent of the time step. An explicit version of the current scheme is also provided besides the implicit-explicit one. For the implicit-explicit version, we retain divergence of the viscous terms on the right-hand side of the Poisson equation in order to achieve a higher accuracy for low Reynolds number flows. In this way, we also ensure that the Poisson equation wit…

General Computer ScienceDiscretizationPlane (geometry)Mathematical analysisGeneral Engineering01 natural sciencesProjection (linear algebra)010305 fluids & plasmas010101 applied mathematicsIncompressible flow0103 physical sciencesNeumann boundary conditionBoundary value problem0101 mathematicsPoisson's equationNavier–Stokes equationsMathematicsComputers & Fluids
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MAST-RT0 solution of the incompressible Navier–Stokes equations in 3D complex domains

2020

A new numerical methodology to solve the 3D Navier-Stokes equations for incompressible fluids within complex boundaries and unstructured body-fitted tetrahedral mesh is presented and validated with three literature and one real-case tests. We apply a fractional time step procedure where a predictor and a corrector problem are sequentially solved. The predictor step is solved applying the MAST (Marching in Space and Time) procedure, which explicitly handles the non-linear terms in the momentum equations, allowing numerical stability for Courant number greater than one. Correction steps are solved by a Mixed Hybrid Finite Elements discretization that assumes positive distances among tetrahedr…

General Computer Scienceeulerian methodMathematics::Analysis of PDEspredictor–corrector scheme02 engineering and technology01 natural sciencesnavier–stokes equationsSettore ICAR/01 - Idraulica010305 fluids & plasmasNumerical methodologyPhysics::Fluid Dynamics0203 mechanical engineeringNavier–Stokes equations 3D numerical model Eulerian method unstructured tetrahedral mesh predictor–corrector scheme Mixed Hybrid Finite elementIncompressible flow0103 physical sciencesNavier–Stokes equationsPhysicsMathematical analysisEulerian methodunstructured tetrahedral meshEngineering (General). Civil engineering (General)3d numerical modelTetrahedral meshes020303 mechanical engineering & transportsmixed hybrid finite elementModeling and SimulationCompressibilityTA1-2040Engineering Applications of Computational Fluid Mechanics
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Bounded solutions to the 1-Laplacian equation with a critical gradient term

2012

General MathematicsBounded functionMathematical analysisLaplace operator1-laplacian; degenerate elliptic equations; functions of bounded variations; gradient term with natural growthMathematicsTerm (time)Asymptotic Analysis
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Uniqueness of positive radial solutions to singular critical growth quasilinear elliptic equations

2015

In this paper, we prove that there exists at most one positive radial weak solution to the following quasilinear elliptic equation with singular critical growth \[ \begin{cases} -\Delta_{p}u-{\displaystyle \frac{\mu}{|x|^{p}}|u|^{p-2}u}{\displaystyle =\frac{|u|^{\frac{(N-s)p}{N-p}-2}u}{|x|^{s}}}+\lambda|u|^{p-2}u & \text{in }B,\\ u=0 & \text{on }\partial B, \end{cases} \] where $B$ is an open finite ball in $\mathbb{R}^{N}$ centered at the origin, $1<p<N$, $-\infty<\mu<((N-p)/p)^{p}$, $0\le s<p$ and $\lambda\in\mathbb{R}$. A related limiting problem is also considered.

General MathematicsWeak solutionta111010102 general mathematicsMathematical analysisuniquenessPohozaev identity01 natural sciences010101 applied mathematicsElliptic curveMathematics - Analysis of PDEspositive radial solutionsSingular solutionFOS: Mathematicssingular critical growthquasilinear elliptic equationsasymptotic behaviorsUniqueness0101 mathematics35A24 35B33 35B40 35J75 35J92Analysis of PDEs (math.AP)MathematicsAnnales Academiae Scientiarum Fennicae Mathematica
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On a Retarded Nonlocal Ordinary Differential System with Discrete Diffusion Modeling Life Tables

2021

In this paper, we consider a system of ordinary differential equations with non-local discrete diffusion and finite delay and with either a finite or an infinite number of equations. We prove several properties of solutions such as comparison, stability and symmetry. We create a numerical simulation showing that this model can be appropriate to model dynamical life tables in actuarial or demographic sciences. In this way, some indicators of goodness and smoothness are improved when comparing with classical techniques.

General Mathematicslattice dynamical systemslife tables010103 numerical & computational mathematics:CIENCIAS ECONÓMICAS [UNESCO]01 natural sciencesStability (probability)010104 statistics & probabilitydiscrete nonlocal diffusion problemsComputer Science (miscellaneous)Applied mathematics0101 mathematicsDiffusion (business)Engineering (miscellaneous)MathematicsDiffusion modelingSmoothness (probability theory)Computer simulationlcsh:MathematicsUNESCO::CIENCIAS ECONÓMICASlcsh:QA1-939Symmetry (physics)Ordinary differential systemordinary differential equationsOrdinary differential equationretarded equationsMathematics
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Calcium binding and ionic conduction in single conical nanopores with polyacid chains: model and experiments.

2012

Calcium binding to fixed charge groups confined over nanoscale regions is relevant to ion equilibrium and transport in the ionic channels of the cell membranes and artificial nanopores. We present an experimental and theoretical description of the dissociation equilibrium and transport in a single conical nanopore functionalized with pH-sensitive carboxylic acid groups and phosphonic acid chains. Different phenomena are simultaneously present in this basic problem of physical and biophysical chemistry: (i) the divalent nature of the phosphonic acid groups fixed to the pore walls and the influence of the pH and calcium on the reversible dissociation equilibrium of these groups; (ii) the asym…

General Physics and AstronomyIonic bondingFunctionalizedDissociation (chemistry)Conical nanoporeNanoscale regionschemistry.chemical_compoundNanoporesI - V curveIonic conductivityGeneral Materials ScienceConical nanoporesPhosphonate groupCalcium concentrationChemistryGeneral EngineeringPH effectsPartition functionsIonic channelsIon equilibriumReversible dissociationChemical physicsFunctional groupsThermodynamicsDesalination membranesIon bindingPorosityDissociationBiophysical chemistryDissociation equilibriaInorganic chemistrychemistry.chemical_elementWater filtrationCalciumIonNernst-Planck equationsApplied potentialsIon bindingCarboxylationPhosphonic acidsComputer SimulationCarboxylateParticle SizeControlled drug releaseCurrent voltage curveIonsBinding SitesFixed charge densityPH sensitiveCarboxylic acidsDesalinationPhosphonic acid groupsPoly acidsElectric ConductivityCarboxylic acid groupsFixed ChargesNanostructuresCell membranesCurrent-voltage curvesModels ChemicalQuantum theoryFISICA APLICADACalciumBiological ion channelsCalcium bindingIonic currentCytologyPore wallStatistical mechanicsAcidsACS nano
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NUMERICAL ALGORITHMS

2013

For many systems of differential equations modeling problems in science and engineering, there are natural splittings of the right hand side into two parts, one non-stiff or mildly stiff, and the other one stiff. For such systems implicit-explicit (IMEX) integration combines an explicit scheme for the non-stiff part with an implicit scheme for the stiff part. In a recent series of papers two of the authors (Sandu and Zhang) have developed IMEX GLMs, a family of implicit-explicit schemes based on general linear methods. It has been shown that, due to their high stage order, IMEX GLMs require no additional coupling order conditions, and are not marred by order reduction. This work develops a …

General linear methodsMathematical optimizationIMEX methods; general linear methods; error analysis; order conditions; stability analysisIMEX methodsDifferential equationSCHEMESorder conditionsMathematics AppliedExtrapolationStability (learning theory)QUADRATIC STABILITYstability analysisPARABOLIC EQUATIONSSYSTEMSNORDSIECK METHODSFOS: MathematicsApplied mathematicsMathematics - Numerical AnalysisRUNGE-KUTTA METHODSMULTISTEP METHODSerror analysisMathematicsCONSTRUCTIONSeries (mathematics)Applied MathematicsNumerical analysisComputer Science - Numerical AnalysisStability analysisORDEROrder conditionsNumerical Analysis (math.NA)Computer Science::Numerical AnalysisRunge–Kutta methodsGeneral linear methodsError analysisORDINARY DIFFERENTIAL-EQUATIONSOrdinary differential equationgeneral linear methodsMathematics
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Non-Local Scattering Kernel and the Hydrodynamic Limit

2007

In this paper we study the interaction of a fluid with a wall in the framework of the kinetic theory. We consider the possibility that the fluid molecules can penetrate the wall to be reflected by the inner layers of the wall. This results in a scattering kernel which is a non-local generalization of the classical Maxwell scattering kernel. The proposed scattering kernel satisfies a global mass conservation law and a generalized reciprocity relation. We study the hydrodynamic limit performing a Knudsen layer analysis, and derive a new class of (weakly) nonlocal boundary conditions to be imposed to the Navier-Stokes equations.

GeneralizationMathematical analysisStatistical and Nonlinear PhysicsKnudsen layerStokes flowBoltzmann equationPhysics::Fluid Dynamicssymbols.namesakeNonlocal boundary conditions Fluid dynamic limit Navier-Stokes Boltzmann equationsClassical mechanicsStokes' lawKinetic theory of gasessymbolsLimit (mathematics)Conservation of massMathematical PhysicsMathematicsJournal of Statistical Physics
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