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Volume 21, Issue 6
Variable Time Step Method of Dahlquist, Liniger and Nevanlinna (DLN) for a Corrected Smagorinsky Model

Farjana Siddiqua & Wenlong Pei

DOI: 10.4208/ijnam2024-1035

Int. J. Numer. Anal. Mod., 21 (2024), pp. 879-909.

Published online: 2024-10

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  • Abstract

Turbulent flows strain resources, both memory and CPU speed. A family of second-order, $G$-stable time-stepping methods proposed by Dahlquist, Liniger, and Nevanlinna (the DLN method) has great accuracy and allows large time steps, requiring less memory and fewer FLOPS. The DLN method can also be implemented adaptively. The classical Smagorinsky model, as an effective way to approximate a resolved mean velocity, has recently been corrected to represent a flow of energy from unresolved fluctuations to the resolved mean velocity. In this paper, we apply the DLN method to one corrected Smagorinsky model and provide a detailed numerical analysis of the stability and consistency. We prove that the numerical solutions under arbitrary time step sequences are unconditionally stable in the long term and converge in second order. We also provide error estimates under certain time-step conditions. Numerical tests are given to confirm the rate of convergence and also to show that the adaptive DLN algorithm helps to control numerical dissipation so that a flow of energy from unresolved fluctuations to the resolved mean velocity is visible.

  • Keywords

Eddy viscosity, corrected Smagorinsky model, complex turbulence, backscatter, the DLN method, $G$-stability, variable time-stepping.

  • AMS Subject Headings

65M12, 65M22, 65M60, 76M10

  • Copyright

COPYRIGHT: © Global Science Press

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@Article{IJNAM-21-879, author = {Siddiqua , Farjana and Pei , Wenlong}, title = {Variable Time Step Method of Dahlquist, Liniger and Nevanlinna (DLN) for a Corrected Smagorinsky Model}, journal = {International Journal of Numerical Analysis and Modeling}, year = {2024}, volume = {21}, number = {6}, pages = {879--909}, abstract = {

Turbulent flows strain resources, both memory and CPU speed. A family of second-order, $G$-stable time-stepping methods proposed by Dahlquist, Liniger, and Nevanlinna (the DLN method) has great accuracy and allows large time steps, requiring less memory and fewer FLOPS. The DLN method can also be implemented adaptively. The classical Smagorinsky model, as an effective way to approximate a resolved mean velocity, has recently been corrected to represent a flow of energy from unresolved fluctuations to the resolved mean velocity. In this paper, we apply the DLN method to one corrected Smagorinsky model and provide a detailed numerical analysis of the stability and consistency. We prove that the numerical solutions under arbitrary time step sequences are unconditionally stable in the long term and converge in second order. We also provide error estimates under certain time-step conditions. Numerical tests are given to confirm the rate of convergence and also to show that the adaptive DLN algorithm helps to control numerical dissipation so that a flow of energy from unresolved fluctuations to the resolved mean velocity is visible.

}, issn = {2617-8710}, doi = {https://doi.org/10.4208/ijnam2024-1035}, url = {http://global-sci.org/intro/article_detail/ijnam/23464.html} }
TY - JOUR T1 - Variable Time Step Method of Dahlquist, Liniger and Nevanlinna (DLN) for a Corrected Smagorinsky Model AU - Siddiqua , Farjana AU - Pei , Wenlong JO - International Journal of Numerical Analysis and Modeling VL - 6 SP - 879 EP - 909 PY - 2024 DA - 2024/10 SN - 21 DO - http://doi.org/10.4208/ijnam2024-1035 UR - https://global-sci.org/intro/article_detail/ijnam/23464.html KW - Eddy viscosity, corrected Smagorinsky model, complex turbulence, backscatter, the DLN method, $G$-stability, variable time-stepping. AB -

Turbulent flows strain resources, both memory and CPU speed. A family of second-order, $G$-stable time-stepping methods proposed by Dahlquist, Liniger, and Nevanlinna (the DLN method) has great accuracy and allows large time steps, requiring less memory and fewer FLOPS. The DLN method can also be implemented adaptively. The classical Smagorinsky model, as an effective way to approximate a resolved mean velocity, has recently been corrected to represent a flow of energy from unresolved fluctuations to the resolved mean velocity. In this paper, we apply the DLN method to one corrected Smagorinsky model and provide a detailed numerical analysis of the stability and consistency. We prove that the numerical solutions under arbitrary time step sequences are unconditionally stable in the long term and converge in second order. We also provide error estimates under certain time-step conditions. Numerical tests are given to confirm the rate of convergence and also to show that the adaptive DLN algorithm helps to control numerical dissipation so that a flow of energy from unresolved fluctuations to the resolved mean velocity is visible.

Siddiqua , Farjana and Pei , Wenlong. (2024). Variable Time Step Method of Dahlquist, Liniger and Nevanlinna (DLN) for a Corrected Smagorinsky Model. International Journal of Numerical Analysis and Modeling. 21 (6). 879-909. doi:10.4208/ijnam2024-1035
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