Numerical stability analysis of incompressible boundary layers over ribbed surfaces
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Kirill V. Demyanko
,
Nikita V. Klyushnev
Abstract
A technology for numerical analysis of the local biglobal stability of laminar incompressible boundary layers over streamwise-ribbed surfaces is proposed. Within its framework, the stability is studied using the locally-parallel approximation and Floquet theory. The work of the proposed technology is demonstrated by the example of a boundary layer over a streamwise-ribbed plate of finite thickness. For the considered values of ribbing parameters, it is shown that the presence of ribbing increases the growth of disturbances compared to a plate without ribbing, thereby promoting the natural laminar–turbulent transition.
Funding statement: The work was supported by the Russian Science Foundation, project No. 22–71–10028.
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Articles in the same Issue
- Frontmatter
- Numerical stability analysis of incompressible boundary layers over ribbed surfaces
- Statistical separation of mixtures in the problem of reconstructing the coefficients of an Itô stochastic process-type model of the interplanetary magnetic flux density: ℓ2-distance minimization vs likelihood maximization
- Four-dimensional variational data assimilation system for the Earth ionosphere
- Conservative second-order monotonic numerical method for solving two-dimensional continuity equation
- Preconditioners for large dense matrices in a low-rank format
- On a semi-explicit fourth-order vector compact scheme for the acoustic wave equation
- Corrigendum to: Temporally and spatially segregated discretization for a coupled electromechanical myocardium model
