Search results for "Numerical Analysis"

showing 10 items of 883 documents

Numerical study of blow-up in solutions to generalized Kadomtsev-Petviashvili equations

2013

We present a numerical study of solutions to the generalized Kadomtsev-Petviashvili equations with critical and supercritical nonlinearity for localized initial data with a single minimum and single maximum. In the cases with blow-up, we use a dynamic rescaling to identify the type of the singularity. We present a discussion of the observed blow-up scenarios.

Vries equationPhysicsApplied Mathematics010102 general mathematicsMathematical analysisMathematics::Analysis of PDEsNumerical Analysis (math.NA)Type (model theory)01 natural sciencesSupercritical fluid010101 applied mathematicsNonlinear systemSingularityNonlinear Sciences::Exactly Solvable and Integrable SystemsMathematics - Analysis of PDEsFOS: MathematicsDiscrete Mathematics and CombinatoricsMathematics - Numerical Analysis0101 mathematicsNonlinear Sciences::Pattern Formation and SolitonsAnalysis of PDEs (math.AP)
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Turing instability and traveling fronts for a nonlinear reaction–diffusion system with cross-diffusion

2012

In this work we investigate the phenomena of pattern formation and wave propagation for a reaction–diffusion system with nonlinear diffusion. We show how cross-diffusion destabilizes uniform equilibrium and is responsible for the initiation of spatial patterns. Near marginal stability, through a weakly nonlinear analysis, we are able to predict the shape and the amplitude of the pattern. For the amplitude, in the supercritical and in the subcritical case, we derive the cubic and the quintic Stuart–Landau equation respectively. When the size of the spatial domain is large, and the initial perturbation is localized, the pattern is formed sequentially and invades the whole domain as a travelin…

WavefrontNumerical AnalysisQuintic Stuart–Landau equationGeneral Computer ScienceWave propagationApplied MathematicsNonlinear diffusionMathematical analysisPattern formationTheoretical Computer ScienceQuintic functionNonlinear systemAmplitudeModeling and SimulationReaction–diffusion systemPattern formationAmplitude equationMarginal stabilityMathematicsGinzburg–Landau equation
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An efficient integral equation technique for the analysis of arbitrarily shaped capacitive waveguide circuits

2011

In this paper a new and efficient integral equation formulation is presented for the analysis of arbitrarily shaped capacitive waveguide devices. The technique benefits from the symmetry of the structure in order to reduce the dimensions of the problem from three to two dimensions. For the first time, this technique formulates the waveguide capacitive discontinuity problem as a 2D scattering problem with oblique incidence, combined with an efficient calculation of the parallel plate Green's functions. Results for a capacitive impedance transformer are successfully compared with measurements for validation of the proposed theory.

Waveguide filterbusiness.industryCapacitive sensingNumerical analysisMathematical analysisMethod of moments (statistics)Condensed Matter PhysicsIntegral equationSymmetry (physics)Discontinuity (linguistics)OpticsGeneral Earth and Planetary SciencesWaveguide (acoustics)Electrical and Electronic EngineeringbusinessMathematicsRadio Science
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Optimization of conducting structures by using the homogenization method

2002

Approximation and numerical realization of a class of optimization problems with control variables represented by coefficients of linear elliptic state equations is considered. Convergence analysis of well-posed problems is performed by using one- and two-level approximation strategies. The latter is utilized in an optimization layout problem for two conductive constituents, for which the necessary steps to transfer the well-posed problem into a computational form are described and some numerical experiments are given.

Well-posed problemMathematical optimizationControl and OptimizationOptimization problemNumerical analysisControl variableThermal conductionComputer Graphics and Computer-Aided DesignHomogenization (chemistry)Computer Science ApplicationsControl and Systems EngineeringHeat transferApplied mathematicsEngineering design processSoftwareMathematicsStructural and Multidisciplinary Optimization
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Towards Stable Radial Basis Function Methods for Linear Advection Problems

2021

In this work, we investigate (energy) stability of global radial basis function (RBF) methods for linear advection problems. Classically, boundary conditions (BC) are enforced strongly in RBF methods. By now it is well-known that this can lead to stability problems, however. Here, we follow a different path and propose two novel RBF approaches which are based on a weak enforcement of BCs. By using the concept of flux reconstruction and simultaneous approximation terms (SATs), respectively, we are able to prove that both new RBF schemes are strongly (energy) stable. Numerical results in one and two spatial dimensions for both scalar equations and systems are presented, supporting our theoret…

Work (thermodynamics)AdvectionScalar (physics)Numerical Analysis (math.NA)35L65 41A05 41A30 65D05 65M12Stability (probability)Computational Mathematics10123 Institute of Mathematics510 MathematicsComputational Theory and MathematicsModeling and SimulationPath (graph theory)FOS: MathematicsApplied mathematicsRadial basis functionBoundary value problemMathematics - Numerical Analysis2605 Computational MathematicsEnergy (signal processing)Mathematics2611 Modeling and Simulation1703 Computational Theory and Mathematics
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INFLUENCE OF UNEQUAL OSCILLATOR STRENGTHS ON STIMULATED RAMAN ADIABATIC PASSAGE THROUGH BRIGHT STATE

2012

In the present work an analytical and numerical analysis of the b -STIRAP process in a medium with unequal oscillator strengths is performed. It is shown that the length of population transfer can be considerably increased by an appropriate choice of the dipole transitions.

Work (thermodynamics)DipoleChemistryOscillator strengthNumerical analysisStimulated Raman adiabatic passagePopulation transferAtomic physicsBright stateInternational Journal of Modern Physics: Conference Series
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Some Theoretical Results About Stability for IMEX Schemes Applied to Hyperbolic Equations with Stiff Reaction Terms

2010

In this work we are concerned with certain numerical difficulties associated to the use of high order Implicit–Explicit Runge–Kutta (IMEX-RK) schemes in a direct discretization of balance laws with stiff source terms. We consider a simple model problem, introduced by LeVeque and Yee in [J. Comput. Phys 86 (1990)], as the basic test case to explore the ability of IMEX-RK schemes to produce and maintain non-oscillatory reaction fronts.

Work (thermodynamics)DiscretizationSimple (abstract algebra)Applied mathematicsMaterial derivativeHigh orderComputer Science::Numerical AnalysisHyperbolic partial differential equationStability (probability)Mathematics::Numerical AnalysisMathematics
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On the a posteriori error analysis for linear Fokker-Planck models in convection-dominated diffusion problems

2018

This work is aimed at the derivation of reliable and efficient a posteriori error estimates for convection-dominated diffusion problems motivated by a linear Fokker-Planck problem appearing in computational neuroscience. We obtain computable error bounds of the functional type for the static and time-dependent case and for different boundary conditions (mixed and pure Neumann boundary conditions). Finally, we present a set of various numerical examples including discussions on mesh adaptivity and space-time discretisation. The numerical results confirm the reliability and efficiency of the error estimates derived.

Work (thermodynamics)Discretizationelliptic partial differential equations01 natural sciencesdiffuusiodiffuusio (fysikaaliset ilmiöt)mesh-adaptivityFOS: MathematicsNeumann boundary conditionApplied mathematicsBoundary value problemMathematics - Numerical Analysis0101 mathematicsDiffusion (business)virheanalyysiMathematicsosittaisdifferentiaaliyhtälötconvection-dominated diffusion problemsApplied Mathematicsta111010102 general mathematicsComputer Science - Numerical AnalysisNumerical Analysis (math.NA)a posteriori error estimation010101 applied mathematicsparabolic partial differential equationsComputational MathematicsElliptic partial differential equationA priori and a posterioriFokker–Planck equation
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Characteristics of the polymer transport in ratchet systems

2010

Molecules with complex internal structure in time-dependent periodic potentials are studied by using short Rubinstein-Duke model polymers as an example. We extend our earlier work on transport in stochastically varying potentials to cover also deterministic potential switching mechanisms, energetic efficiency and non-uniform charge distributions. We also use currents in the non-equilibrium steady state to identify the dominating mechanisms that lead to polymer transportation and analyze the evolution of the macroscopic state (e.g., total and head-to-head lengths) of the polymers. Several numerical methods are used to solve the master equations and nonlinear optimization problems. The domina…

Work (thermodynamics)PolymersRatchetMolecular ConformationFOS: Physical sciencesRatchet effectmolecular motorsNonlinear programmingDiffusionMotionkuljetusilmiötMaster equationmolekyylimoottoritStatistical physicspolymeeritCondensed Matter - Statistical MechanicsPhysicsStochastic ProcessesStatistical Mechanics (cond-mat.stat-mech)Molecular Motor ProteinsNumerical analysisCharge (physics)ratchetsModels Theoreticalnonequilibrium phenomenaKineticsClassical mechanicsräikätepätasapainoilmiöttransport phenomenaAlgorithmsCoherence (physics)Physical Review E
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Estimating the temperature evolution of foodstuffs during freezing with a 3D meshless numerical method

2015

Abstract Freezing processes are characterised by sharp changes in specific heat capacity and thermal conductivity for temperatures close to the freezing point. This leads to strong nonlinearities in the governing PDE that may be difficult to resolve using traditional numerical methods. In this work we present a meshless numerical method, based on a local Hermite radial basis function collocation approach in finite differencing mode, to allow the solution of freezing problems. By introducing a Kirchhoff transformation and solving the governing equations in Kirchhoff space, the strength of nonlinearity is reduced while preserving the structure of the heat equation. In combination with the hig…

Work (thermodynamics)Regularized meshless methodRadial basis functionNonlinear heat conductionApplied MathematicsNumerical analysisMathematical analysisGeneral EngineeringMeshleKirchhoff transformationFreezing pointPiecewise linear functionComputational MathematicsNonlinear systemThermal conductivityFreezingSettore ING-IND/10 - Fisica Tecnica IndustrialeHeat equationPhase changeAnalysisMathematicsEngineering Analysis with Boundary Elements
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