Study of interpolation methods for high-accuracy computations on overlapping grids

► High-accuracy Lagrange or optimized interpolation schemes are investigated. ► A DRP-type optimization is advantageous to deal with high-frequency phenomena. ► An interpolation stencil with less points than the discretization can be acceptable. ► The choice of an interpolation for multidimensional...

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Veröffentlicht in:	Computers & fluids 2012-09, Vol.68, p.112-133
Hauptverfasser:	Chicheportiche, J., Gloerfelt, X.
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Sprache:	eng
Schlagworte:	Accuracy Acoustics Aeroacoustics, atmospheric sound Algorithms Computational aeroacoustics Discretization Engineering Sciences Error analysis Exact sciences and technology Fluid mechanics Fluids mechanics Fundamental areas of phenomenology (including applications) Interpolation Mathematical models Mechanics Optimization Optimized interpolation Overlapping grids Physics Strategy
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description	► High-accuracy Lagrange or optimized interpolation schemes are investigated. ► A DRP-type optimization is advantageous to deal with high-frequency phenomena. ► An interpolation stencil with less points than the discretization can be acceptable. ► The choice of an interpolation for multidimensional curvilinear grids is discussed. ► Two aeroacoustic benchmarks are conducted to show the accuracy of the method. Overset strategy can be an efficient way to keep high-accuracy discretization by decomposing a complex geometry in topologically simple subdomains. Apart from the grid assembly algorithm, the key point of overset technique lies in the interpolation processes which ensure the communications between the overlapping grids. The family of explicit Lagrange and optimized interpolation schemes is studied. The a priori interpolation error is analyzed in the Fourier space, and combined with the error of the chosen discretization to highlight the modification of the numerical error. When high-accuracy algorithms are used an optimization of the interpolation coefficients can enhance the resolvality, which can be useful when high-frequency waves or small turbulent scales need to be supported by a grid. For general curvilinear grids in more than one space dimension, a mapping in a computational space followed by a tensorization of 1-D interpolations is preferred to a direct evaluation of the coefficient in the physical domain. A high-order extension of the isoparametric mapping is accurate and robust since it avoids the inversion of a matrix which may be ill-conditioned. A posteriori error analyses indicate that the interpolation stencil size must be tailored to the accuracy of the discretization scheme. For well discretized wavelengthes, the results show that the choice of a stencil smaller than the stencil of the corresponding finite-difference scheme can be acceptable. Besides the gain of optimization to capture high-frequency phenomena is also underlined. Adding order constraints to the optimization allows an interesting trade-off when a large range of scales is considered. Finally, the ability of the present overset strategy to preserve accuracy is illustrated by the diffraction of an acoustic source by two cylinders, and the generation of acoustic tones in a rotor–stator interaction. Some recommandations are formulated in the closing section.
doi_str_mv	10.1016/j.compfluid.2012.07.019
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Overset strategy can be an efficient way to keep high-accuracy discretization by decomposing a complex geometry in topologically simple subdomains. Apart from the grid assembly algorithm, the key point of overset technique lies in the interpolation processes which ensure the communications between the overlapping grids. The family of explicit Lagrange and optimized interpolation schemes is studied. The a priori interpolation error is analyzed in the Fourier space, and combined with the error of the chosen discretization to highlight the modification of the numerical error. When high-accuracy algorithms are used an optimization of the interpolation coefficients can enhance the resolvality, which can be useful when high-frequency waves or small turbulent scales need to be supported by a grid. For general curvilinear grids in more than one space dimension, a mapping in a computational space followed by a tensorization of 1-D interpolations is preferred to a direct evaluation of the coefficient in the physical domain. A high-order extension of the isoparametric mapping is accurate and robust since it avoids the inversion of a matrix which may be ill-conditioned. A posteriori error analyses indicate that the interpolation stencil size must be tailored to the accuracy of the discretization scheme. For well discretized wavelengthes, the results show that the choice of a stencil smaller than the stencil of the corresponding finite-difference scheme can be acceptable. Besides the gain of optimization to capture high-frequency phenomena is also underlined. Adding order constraints to the optimization allows an interesting trade-off when a large range of scales is considered. Finally, the ability of the present overset strategy to preserve accuracy is illustrated by the diffraction of an acoustic source by two cylinders, and the generation of acoustic tones in a rotor–stator interaction. 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Overset strategy can be an efficient way to keep high-accuracy discretization by decomposing a complex geometry in topologically simple subdomains. Apart from the grid assembly algorithm, the key point of overset technique lies in the interpolation processes which ensure the communications between the overlapping grids. The family of explicit Lagrange and optimized interpolation schemes is studied. The a priori interpolation error is analyzed in the Fourier space, and combined with the error of the chosen discretization to highlight the modification of the numerical error. When high-accuracy algorithms are used an optimization of the interpolation coefficients can enhance the resolvality, which can be useful when high-frequency waves or small turbulent scales need to be supported by a grid. For general curvilinear grids in more than one space dimension, a mapping in a computational space followed by a tensorization of 1-D interpolations is preferred to a direct evaluation of the coefficient in the physical domain. A high-order extension of the isoparametric mapping is accurate and robust since it avoids the inversion of a matrix which may be ill-conditioned. A posteriori error analyses indicate that the interpolation stencil size must be tailored to the accuracy of the discretization scheme. For well discretized wavelengthes, the results show that the choice of a stencil smaller than the stencil of the corresponding finite-difference scheme can be acceptable. Besides the gain of optimization to capture high-frequency phenomena is also underlined. Adding order constraints to the optimization allows an interesting trade-off when a large range of scales is considered. Finally, the ability of the present overset strategy to preserve accuracy is illustrated by the diffraction of an acoustic source by two cylinders, and the generation of acoustic tones in a rotor–stator interaction. Some recommandations are formulated in the closing section.</description><subject>Accuracy</subject><subject>Acoustics</subject><subject>Aeroacoustics, atmospheric sound</subject><subject>Algorithms</subject><subject>Computational aeroacoustics</subject><subject>Discretization</subject><subject>Engineering Sciences</subject><subject>Error analysis</subject><subject>Exact sciences and technology</subject><subject>Fluid mechanics</subject><subject>Fluids mechanics</subject><subject>Fundamental areas of phenomenology (including applications)</subject><subject>Interpolation</subject><subject>Mathematical models</subject><subject>Mechanics</subject><subject>Optimization</subject><subject>Optimized interpolation</subject><subject>Overlapping grids</subject><subject>Physics</subject><subject>Strategy</subject><issn>0045-7930</issn><issn>1879-0747</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2012</creationdate><recordtype>article</recordtype><recordid>eNqFkUGL2zAQhUVpoel2f0N9KbQHuzOyI1nHsLTdhUCh7Z6FVhonCo7lSnYg_77yZsl1T8MM38x7zGPsE0KFgOLbobLhOHb97F3FAXkFsgJUb9gKW6lKkI18y1YAzbqUqob37ENKB8h9zZsV-_1nmt25CF3hh4niGHoz-TAUR5r2waWiC7HY-92-NNbO0dhzsajN0zOVikyGE8XejKMfdsUuepc-sned6RPdvtQb9vjj-9-7-3L76-fD3WZb2kY1U8nRkiNApzrkyj1JsLY1Aoyza-6EakFxK5wAIddIiE8tStFQbRCAeLeub9jXy9296fUY_dHEsw7G6_vNVi8zQBBK1PUJM_vlwo4x_JspTfrok6W-NwOFOWmUoKTMos3rKBfZUQvtclVeUBtDSpG6qw0EvYSjD_oajl7C0SCzLZU3P7-ImGRN30UzWJ-u61w0PGe1KGwuHOVHnjxFnaynIX_OR7KTdsG_qvUfbcOpFw</recordid><startdate>20120915</startdate><enddate>20120915</enddate><creator>Chicheportiche, J.</creator><creator>Gloerfelt, X.</creator><general>Elsevier Ltd</general><general>Elsevier</general><scope>IQODW</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7UA</scope><scope>C1K</scope><scope>F1W</scope><scope>H96</scope><scope>L.G</scope><scope>7SC</scope><scope>7TB</scope><scope>7U5</scope><scope>8FD</scope><scope>FR3</scope><scope>H8D</scope><scope>JQ2</scope><scope>KR7</scope><scope>L7M</scope><scope>L~C</scope><scope>L~D</scope><scope>1XC</scope><scope>VOOES</scope></search><sort><creationdate>20120915</creationdate><title>Study of interpolation methods for high-accuracy computations on overlapping grids</title><author>Chicheportiche, J. ; 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subjects	Accuracy Acoustics Aeroacoustics, atmospheric sound Algorithms Computational aeroacoustics Discretization Engineering Sciences Error analysis Exact sciences and technology Fluid mechanics Fluids mechanics Fundamental areas of phenomenology (including applications) Interpolation Mathematical models Mechanics Optimization Optimized interpolation Overlapping grids Physics Strategy
title	Study of interpolation methods for high-accuracy computations on overlapping grids
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