Search results for "5R"

showing 10 items of 108 documents

Monotonicity and enclosure methods for the p-Laplace equation

2018

We show that the convex hull of a monotone perturbation of a homogeneous background conductivity in the $p$-conductivity equation is determined by knowledge of the nonlinear Dirichlet-Neumann operator. We give two independent proofs, one of which is based on the monotonicity method and the other on the enclosure method. Our results are constructive and require no jump or smoothness properties on the conductivity perturbation or its support.

Convex hull35R30 (Primary) 35J92 (Secondary)EnclosurePerturbation (astronomy)Monotonic function01 natural sciencesConstructiveMathematics - Analysis of PDEsEnclosure methodFOS: Mathematics0101 mathematicsMathematicsInclusion detectionMonotonicity methodLaplace's equationmonotonicity methodApplied Mathematics010102 general mathematicsMathematical analysista111inclusion detection010101 applied mathematicsNonlinear systemMonotone polygonp-Laplace equationAnalysis of PDEs (math.AP)enclosure method
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Enclosure method for the p-Laplace equation

2014

We study the enclosure method for the p-Calder\'on problem, which is a nonlinear generalization of the inverse conductivity problem due to Calder\'on that involves the p-Laplace equation. The method allows one to reconstruct the convex hull of an inclusion in the nonlinear model by using exponentially growing solutions introduced by Wolff. We justify this method for the penetrable obstacle case, where the inclusion is modelled as a jump in the conductivity. The result is based on a monotonicity inequality and the properties of the Wolff solutions.

Convex hullGeneralization35R30 (Primary) 35J92 (Secondary)EnclosureMathematics::Classical Analysis and ODEsInverseMonotonic function01 natural sciencesTheoretical Computer ScienceMathematics - Analysis of PDEsFOS: Mathematics0101 mathematicsMathematical PhysicsMathematicsLaplace's equationMathematics::Functional AnalysisCalderón problemApplied Mathematics010102 general mathematicsMathematical analysisComputer Science Applications010101 applied mathematicsNonlinear systemSignal ProcessingJumpp-Laplace equationenclosure methodAnalysis of PDEs (math.AP)
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New rotational levels in $^{186}$Re nucleus

2020

International audience; Excited levels of 186 Re have been studied using results of the single γ -ray spectra measurements following the thermal neutron capture reaction. Energies and intensities of more than 500 γ -transitions have been obtained with the high-resolution crystal diffraction spectrometer GAMS5 of ILL. Most of the obtained intense γ -transitions have been placed in the 186 Re level scheme. A number of new levels, as well as the depopulation for levels observed earlier in the 187 Re (p,d)186 Re reaction measurements have been proposed. Structure of 186 Re levels is interpreted in terms of two-quasiparticle plus rotor coupling model and compared with that of the neighbouring do…

DiffractionNuclear and High Energy PhysicsCore plus two-quasiparticles model[PHYS.NUCL]Physics [physics]/Nuclear Theory [nucl-th]Thermal neutron captureNUCLEAR REACTION 185Re[formula omitted]E=thermalMeasured [formula omitted]01 natural sciencesSpectral lineCrystalMeasured Eγ0103 physical sciencesmedicineγ)010306 general physicsPhysicsCouplingSpectrometer010308 nuclear & particles physics186 Re deduced levelsNUCLEAR REACTION 185 Re (nmedicine.anatomical_structureE =thermalExcited stateGAMS5 crystal diffraction spectrometerAtomic physicsNucleus186Re deduced levels
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$(BV,L^p)$-decomposition, $p=1,2$, of Functions in Metric Random Walk Spaces

2019

In this paper we study the $(BV,L^p)$-decomposition, $p=1,2$, of functions in metric random walk spaces, a general workspace that includes weighted graphs and nonlocal models used in image processing. We obtain the Euler-Lagrange equations of the corresponding variational problems and their gradient flows. In the case $p=1$ we also study the associated geometric problem and the thresholding parameters.

Discrete mathematicsApplied MathematicsImage processingWorkspaceRandom walkThresholding05C80 35R02 05C21 45C99 26A45Mathematics - Analysis of PDEsMetric (mathematics)Decomposition (computer science)FOS: MathematicsAnalysisMathematicsAnalysis of PDEs (math.AP)
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Fixed angle inverse scattering for sound speeds close to constant

2021

We study the fixed angle inverse scattering problem of determining a sound speed from scattering measurements corresponding to a single incident wave. The main result shows that a sound speed close to constant can be stably determined by just one measurement. Our method is based on studying the linearized problem, which turns out to be related to the acoustic problem in photoacoustic imaging. We adapt the modified time-reversal method from [P. Stefanov and G. Uhlmann, Thermoacoustic tomography with variable sound speed, Inverse Problems 25 (2009), 075011] to solve the linearized problem in a stable way, and use this to give a local uniqueness result for the nonlinear inverse problem.

FOS: Mathematics35R30 35Q60 35J05 31B10 78A40Analysis of PDEs (math.AP)
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Monotonicity and local uniqueness for the Helmholtz equation

2017

This work extends monotonicity-based methods in inverse problems to the case of the Helmholtz (or stationary Schr\"odinger) equation $(\Delta + k^2 q) u = 0$ in a bounded domain for fixed non-resonance frequency $k>0$ and real-valued scattering coefficient function $q$. We show a monotonicity relation between the scattering coefficient $q$ and the local Neumann-Dirichlet operator that holds up to finitely many eigenvalues. Combining this with the method of localized potentials, or Runge approximation, adapted to the case where finitely many constraints are present, we derive a constructive monotonicity-based characterization of scatterers from partial boundary data. We also obtain the local…

Helmholtz equationMathematics::Number Theorylocalized potentialsBoundary (topology)Monotonic function01 natural sciencesDomain (mathematical analysis)inversio-ongelmat35R30 35J05symbols.namesakeMathematics - Analysis of PDEs35J050103 physical sciencesFOS: MathematicsUniquenessHelmholtz equation0101 mathematicsinverse coefficient problemsEigenvalues and eigenvectorsMathematicsNumerical AnalysisApplied Mathematics010102 general mathematicsMathematical analysisMathematics::Spectral Theorymonotonicitystationary Schrödinger equation35R30Helmholtz free energyBounded functionsymbols010307 mathematical physicsmonotonicity localized potentialsAnalysisAnalysis of PDEs (math.AP)
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Dimension bounds in monotonicity methods for the Helmholtz equation

2019

The article [B. Harrach, V. Pohjola, and M. Salo, Anal. PDE] established a monotonicity inequality for the Helmholtz equation and presented applications to shape detection and local uniqueness in inverse boundary problems. The monotonicity inequality states that if two scattering coefficients satisfy $q_1 \leq q_2$, then the corresponding Neumann-to-Dirichlet operators satisfy $\Lambda(q_1) \leq \Lambda(q_2)$ up to a finite-dimensional subspace. Here we improve the bounds for the dimension of this space. In particular, if $q_1$ and $q_2$ have the same number of positive Neumann eigenvalues, then the finite-dimensional space is trivial. peerReviewed

Helmholtz equationMathematics::Number Theorymontonicity methodMonotonic function01 natural sciencesinversio-ongelmatMathematics::Numerical AnalysisMathematics - Spectral TheoryMathematics - Analysis of PDEsDimension (vector space)FOS: MathematicsHelmholtz equationUniqueness0101 mathematicsSpectral Theory (math.SP)Mathematicsinverse problemsApplied Mathematics010102 general mathematicsMathematical analysisInverse problemMathematics::Spectral Theory010101 applied mathematicsComputational MathematicsNonlinear Sciences::Exactly Solvable and Integrable Systems35R30AnalysisAnalysis of PDEs (math.AP)
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Partial data inverse problems for Maxwell equations via Carleman estimates

2015

In this article we consider an inverse boundary value problem for the time-harmonic Maxwell equations. We show that the electromagnetic material parameters are determined by boundary measurements where part of the boundary data is measured on a possibly very small set. This is an extension of earlier scalar results of Bukhgeim-Uhlmann and Kenig-Sj\"ostrand-Uhlmann to the Maxwell system. The main contribution is to show that the Carleman estimate approach to scalar partial data inverse problems introduced in those works can be carried over to the Maxwell system.

Inverse problemsELECTRODYNAMICSINFORMATIONadmissible manifoldsWEIGHTSMathematics::Analysis of PDEsBoundary (topology)InverseBOUNDARY-VALUE PROBLEMCALDERON PROBLEMpartial data01 natural sciencesMATERIAL PARAMETERSinversio-ongelmatsymbols.namesakeMathematics - Analysis of PDEsFOS: Mathematics35R30 35Q61111 MathematicsMaxwellin yhtälötBoundary value problemUniqueness0101 mathematicsPartial dataMathematical PhysicsMathematicsAdmissible manifoldsApplied Mathematicsta111010102 general mathematicsMathematical analysisScalar (physics)Inverse problemCarleman estimatesSmall set010101 applied mathematicsUNIQUENESSMaxwell's equationsMaxwell equationsLOCAL DATAsymbolsAnalysisAnalysis of PDEs (math.AP)
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Landis-type conjecture for the half-Laplacian

2023

In this paper, we study the Landis-type conjecture, i.e., unique continuation property from infinity, of the fractional Schrödinger equation with drift and potential terms. We show that if any solution of the equation decays at a certain exponential rate, then it must be trivial. The main ingredients of our proof are the Caffarelli-Silvestre extension and Armitage’s Liouville-type theorem. peerReviewed

Landis conjecture half-Laplacian Caarelli- Silvestre extension Liouville-type theoremosittaisdifferentiaaliyhtälötMathematics - Analysis of PDEsApplied MathematicsGeneral Mathematicsunique continuation propertyPrimary: 35A02 35B40 35R11. Secondary: 35J05 35J15FOS: MathematicsAnalysis of PDEs (math.AP)
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Polarization tensors of planar domains as functions of the admittivity contrast

2014

(Electric) polarization tensors describe part of the leading order term of asymptotic voltage perturbations caused by low volume fraction inhomogeneities of the electrical properties of a medium. They depend on the geometry of the support of the inhomogeneities and on their admittivity contrast. Corresponding asymptotic formulas are of particular interest in the design of reconstruction algorithms for determining the locations and the material properties of inhomogeneities inside a body from measurements of current flows and associated voltage potentials on the body's surface. In this work we consider the two-dimensional case only and provide an analytic representation of the polarization t…

Leading-order termApplied Mathematics010102 general mathematicsMathematical analysis010103 numerical & computational mathematicsEllipsePolarization (waves)01 natural sciencesMathematics - Analysis of PDEsPlanarSimply connected spaceFOS: Mathematics35R30 65N21Tensor0101 mathematicsMaterial propertiesAnalysisAnalysis of PDEs (math.AP)MathematicsVoltageApplicable Analysis
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