Atmospheric-radiation boundary conditions for high-frequency waves in time-distance helioseismology

Fournier, Damien; Leguèbe, Michael; Hanson, Chris; Gizon, Laurent; Barucq, Hélène; Chabassier, Juliette; Duruflé, Marc

doi:10.1051/0004-6361/201731283

Cited by 12 publications

(35 citation statements)

References 13 publications

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“…When using (Atmo SAI 1), the condition can be put directly on the surface, the accuracy will be better than 10 −5 for all frequencies. The computational burden is therefore diminished drastically in terms of memory and CPU-time thanks to this new condition since the mesh can be significantly smaller for the same accuracy (see [12] for quantitative comparisons on real data). …”

Section: Exponential Decay In the Atmospherementioning

confidence: 99%

Atmospheric radiation boundary conditions for the Helmholtz equation

et al. 2018

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Abstract. This work offers some contributions to the numerical study of acoustic waves propagating in the Sun and its atmosphere. The main goal is to provide boundary conditions for outgoing waves in the solar atmosphere where it is assumed that the sound speed is constant and the density decays exponentially with radius. Outgoing waves are governed by a Dirichlet-to-Neumann map which is obtained from the factorization of the Helmholtz equation expressed in spherical coordinates. For the purpose of extending the outgoing wave equation to axisymmetric or 3D cases, different approximations are implemented by using the frequency and/or the angle of incidence as parameters of interest. This results in boundary conditions called Atmospheric Radiation Boundary Conditions (ARBC) which are tested in ideal and realistic configurations. These ARBCs deliver accurate results and reduce the computational burden by a factor of two in helioseismology applications.Résumé. Ce travail apporte quelques contributions à l'étude numérique des ondes acoustiques se propageant dans le Soleil et son atmosphère. Il se base sur la caractérisa-tion des ondes sortantes dans l'atmosphère représentée par une vitesse constante et une densité décroissant exponentiellement. Les ondes sortantes sont régies par un opérateur Dirichlet-to-Neumann qui est obtenu par la factorisation de l'équation de Helmholtz formulée dans les coordonnées sphériques. Afin d'étendre l'équation des ondes sortantes à des géométries axisymétriques ou 3D, différentes approximations sont menées en utilisant la fréquence et/ou l'angle d'incidence comme paramètres d'intérêt. Ceci mène à des conditions de frontière que nous appelons Conditions de Radiation Atmosphériques (ARBC) et qui sont testées en configuration idéalisées et réalistes. Ces conditions ARBC offrent des résultats précis et réduisent le coût de calcul d'un facteur deux pour le cas du Soleil.1991 Mathematics Subject Classification. 00A71, 35L05, 85A20, 33C55, 65M60.December 1, 2017.

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Section: Exponential Decay In the Atmospherementioning

confidence: 99%

Atmospheric radiation boundary conditions for the Helmholtz equation

et al. 2018

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“…[14]. The value at the surface of the Sun of point-source responses in (1.1) is used to simulate the solar power spectrum (ν − diagram) associated to pressure modes, see [14,15,13].…”

Section: Introductionmentioning

confidence: 99%

“…Our work focuses on the atmosphere of the Sun under ideal atmospheric assumptions. A starting point in helioseismology is to describe the interior of the Sun following the model S of [10], which assumes spherical symmetry, [13]. Next, to model the atmosphere of the Sun, there are various simplifying models, the most basic one given by a constant extension from the model S, [14, p.2].…”

Section: Introductionmentioning

confidence: 99%

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Outgoing solutions and radiation boundary conditions for the ideal atmospheric scalar wave equation in helioseismology

2020

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In this paper, we study the time-harmonic scalar equation describing the propagation of acoustic waves in the Sun’s atmosphere under ideal atmospheric assumptions. We use the Liouville change of unknown to conjugate the original problem to a Schrödinger equation with a Coulomb-type potential. This transformation makes appear a new wavenumber, k, and the link with the Whittaker’s equation. We consider two different problems: in the first one, with the ideal atmospheric assumptions extended to the whole space, we construct explicitly the Schwartz kernel of the resolvent, starting from a solution given by Hostler and Pratt in punctured domains, and use this to construct outgoing solutions and radiation conditions. In the second problem, we construct exact Dirichlet-to-Neumann map using Whittaker functions, and new radiation boundary conditions (RBC), using gauge functions in terms of k. The new approach gives rise to simpler RBC for the same precision compared to existing ones. The robustness of our new RBC is corroborated by numerical experiments.

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“…In reality, the Sun is surrounded by a corona whose base is located at about h c = 2000 km above the surface and which is highly inhomogeneous. However, it is common to neglect this complication when studying acoustic waves inside of the Sun and in the lower atmosphere, see, e.g., [5,10]. The adequacy of this simplification have been theoretically justified and numerically confirmed.…”

Section: Introductionmentioning

confidence: 99%

Global uniqueness in a passive inverse problem of helioseismology

2020

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We consider the inverse problem of recovering the spherically symmetric sound speed, density and attenuation in the Sun from the observations of the acoustic field randomly excited by turbulent convection. We show that observations at two heights above the photosphere and at two frequencies above the acoustic cutoff frequency uniquely determine the solar parameters. We also present numerical simulations which confirm this theoretical result.

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Atmospheric-radiation boundary conditions for high-frequency waves in time-distance helioseismology

Cited by 12 publications

References 13 publications

Atmospheric radiation boundary conditions for the Helmholtz equation

Atmospheric radiation boundary conditions for the Helmholtz equation

Outgoing solutions and radiation boundary conditions for the ideal atmospheric scalar wave equation in helioseismology

Global uniqueness in a passive inverse problem of helioseismology

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