Search results for " Simulation"

showing 10 items of 4034 documents

Bifurcations of phase portraits of a Singular Nonlinear Equation of the Second Class

2014

Abstract The soliton dynamics is studied using the Frenkel Kontorova (FK) model with non-convex interparticle interactions immersed in a parameterized on-site substrate potential. The case of a deformable substrate potential allows theoretical adaptation of the model to various physical situations. Non-convex interactions in lattice systems lead to a number of interesting phenomena that cannot be produced with linear coupling alone. In the continuum limit for such a model, the particles are governed by a Singular Nonlinear Equation of the Second Class. The dynamical behavior of traveling wave solutions is studied by using the theory of bifurcations of dynamical systems. Under different para…

PhysicsNumerical AnalysisNonlinear systemClassical mechanicsContinuum (measurement)Phase portraitDynamical systems theoryApplied MathematicsModeling and SimulationLattice (order)Parameterized complexityParametric statisticsHamiltonian systemCommunications in Nonlinear Science and Numerical Simulation
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On the correlation between phase-locking modes and Vibrational Resonance in a neuronal model

2018

International audience; We numerically and experimentally investigate the underlying mechanism leading to multiple resonances in the FitzHugh-Nagumo model driven by a bichromatic excitation. Using a FitzHugh-Nagumo circuit, we first analyze the number of spikes triggered by the system in response to a single sinusoidal wave forcing. We build an encoding diagram where different phase-locking modes are identified according to the amplitude and frequency of the sinusoidal excitation. Next, we consider the bichromatic driving which consists in a low frequency sinusoidal wave perturbed by an additive high frequency signal. Beside the classical Vibrational Resonance phenomenon, we show in real ex…

PhysicsNumerical AnalysisQuantitative Biology::Neurons and CognitionApplied MathematicsPerturbation (astronomy)phase locking modesLow frequencyneural networks01 natural sciences010305 fluids & plasmasComputational physicsCorrelationNonlinear systemnonlinear dynamicsSine waveAmplitude[NLIN.NLIN-PS]Nonlinear Sciences [physics]/Pattern Formation and Solitons [nlin.PS]Control theoryModeling and Simulation0103 physical sciencesVibrational resonance[ NLIN.NLIN-PS ] Nonlinear Sciences [physics]/Pattern Formation and Solitons [nlin.PS]010306 general physicsvibrational resonanceExcitation
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Brownian dynamics simulations with hard-body interactions: Spherical particles

2012

A novel approach to account for hard-body interactions in (overdamped) Brownian dynamics simulations is proposed for systems with non-vanishing force fields. The scheme exploits the analytically known transition probability for a Brownian particle on a one-dimensional half-line. The motion of a Brownian particle is decomposed into a component that is affected by hard-body interactions and into components that are unaffected. The hard-body interactions are incorporated by replacing the affected component of motion by the evolution on a half-line. It is discussed under which circumstances this approach is justified. In particular, the algorithm is developed and formulated for systems with spa…

PhysicsNumerical analysisFOS: Physical sciencesGeneral Physics and AstronomyProteinsComputational Physics (physics.comp-ph)Condensed Matter - Soft Condensed MatterModels BiologicalDiffusionMotionProbability theoryModels ChemicalProtein Interaction MappingBrownian dynamicsSoft Condensed Matter (cond-mat.soft)Computer SimulationStatistical physicsColloidsPhysical and Theoretical ChemistryPhysics - Computational PhysicsBrownian motionAlgorithms
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Multi-Scale Modeling of Quantum Semiconductor Devices

2006

This review is concerned with three classes of quantum semiconductor equations: Schrodinger models, Wigner models, and fluid-type models. For each of these classes, some phenomena on various time and length scales are presented and the connections between micro-scale and macro-scale models are explained. We discuss Schrodinger-Poisson systems for the simulation of quantum waveguides and illustrate the importance of using open boundary conditions. We present Wigner-based semiconductor models and sketch their mathematical analysis. In particular we discuss the Wigner-Poisson-Focker-Planck system, which is the starting point of deriving subsequently the viscous quantum hydrodynamic model. Furt…

PhysicsOpen quantum systemsymbols.namesakeSemiconductor device modelingInelastic collisionsymbolsWigner distribution functionBoundary value problemStatistical physicsSemiconductor process simulationQuantumSchrödinger's cat
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Kuznetsov-Ma Soliton Dynamics in Nonlinear Fiber Optics

2012

The Kuznetzov-Ma (KM) soliton is a solution of the nonlinear Schrodinger equation derived in 1977 but never observed experimentally. Here we report experiments showing KM soliton dynamics in nonlinear breather evolution in optical fiber.

PhysicsOptical fiberComputer simulationBreatherNonlinear opticslaw.inventionNonlinear systemsymbols.namesakeNonlinear Sciences::Exactly Solvable and Integrable SystemslawQuantum mechanicssymbolsPeregrine solitonSolitonNonlinear Sciences::Pattern Formation and SolitonsNonlinear Schrödinger equationAdvanced Photonics Congress
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Experimental observation of modal attraction in optical fibers

2002

We investigate experimentally nonlinear optical attractors based on four-photon mixing interaction of counterpropagating waves in optical fibers.

PhysicsOptical fiberComputer simulationbusiness.industryCross-phase modulationPhysics::OpticsAttractionlaw.inventionOpticsModallawBrillouin scatteringAttractorPhysics::Atomic PhysicsbusinessMixing (physics)Nonlinear Guided Waves and Their Applications
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Tensor Network Annealing Algorithm for Two-Dimensional Thermal States

2019

Tensor network methods have become a powerful class of tools to capture strongly correlated matter, but methods to capture the experimentally ubiquitous family of models at finite temperature beyond one spatial dimension are largely lacking. We introduce a tensor network algorithm able to simulate thermal states of two-dimensional quantum lattice systems in the thermodynamic limit. The method develops instances of projected entangled pair states and projected entangled pair operators for this purpose. It is the key feature of this algorithm to resemble the cooling down of the system from an infinite temperature state until it reaches the desired finite-temperature regime. As a benchmark we …

PhysicsOptical latticeQuantum PhysicsStrongly Correlated Electrons (cond-mat.str-el)General Physics and AstronomyQuantum simulatortensor network methodsFOS: Physical sciences01 natural sciencesSquare latticequantum statistical mechanicsCondensed Matter - Strongly Correlated ElectronsExact solutions in general relativityquantum information0103 physical sciencesThermodynamic limit539strongly correlated systemsIsing modelQuantum information010306 general physicsQuantum statistical mechanicsQuantum Physics (quant-ph)Algorithmquantum simulationPhysical Review Letters
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Physics of Near-Field Optical Images

2005

PhysicsOpticsComputer simulationOptical microscopelawAtomic force microscopybusiness.industryDetection theoryOptical polarizationNear and far fieldbusinessLithographylaw.inventionCLEO/Europe Conference on Lasers and Electro-Optics
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On the dynamics of dislocation patterning

1997

Recent computer simulations on dislocation patterning have provided remarkable results in accordance with empirical laws. Moreover, several analytical models on dislocation dynamics have provided qualitative insight on dislocation patterning. However, a model, based on partial differential equations, which gives a dynamical evolution of dislocation patterns in function of measurable variables still missing. Here, we give a re-formulation of a model proposed some years ago. From this formulation, we obtained that the onset of a dislocation instability is related to the applied stress. The analytical and numerical results reported are partial and studies on this direction are under developmen…

PhysicsPartial differential equationDiffusion equationComputer simulationMechanical EngineeringCondensed Matter PhysicsInstabilityStress (mechanics)Condensed Matter::Materials ScienceClassical mechanicsMechanics of MaterialsReaction–diffusion systemGeneral Materials ScienceStatistical physicsDislocationBifurcationMaterials Science and Engineering: A
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Synchronized rotation in swarms of magnetotactic bacteria.

2017

Self-organizing behavior has been widely reported in both natural and artificial systems, typically distinguishing between temporal organization (synchronization) and spatial organization (swarming). Swarming has been experimentally observed in systems of magnetotactic bacteria under the action of external magnetic fields. Here we present a model of ensembles of magnetotactic bacteria in which hydrodynamic interactions lead to temporal synchronization in addition to the swarming. After a period of stabilization during which the bacteria form a quasiregular hexagonal lattice structure, the entire swarm begins to rotate in a direction opposite to the direction of the rotation of the magnetic …

PhysicsPeriodicityMagnetotactic bacteriaRotationMovementSwarming (honey bee)Swarm behaviourRotationBacterial Physiological Phenomena01 natural sciencesModels BiologicalQuantitative Biology::Cell Behavior010305 fluids & plasmasMagnetic fieldMagnetic Fields0103 physical sciencesArtificial systemsHydrodynamicsHexagonal latticeComputer SimulationTemporal organization010306 general physicsBiological systemPhysical review. E
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