Samir Beneddine scite author profile

This article provides theoretical conditions for the use and meaning of a stability analysis around a mean flow. As such, it may be considered as an extension of the works by McKeon & Sharma (J. Fluid Mech., vol. 658, 2010, pp. 336–382) to non-parallel flows and by Turton et al. (Phys. Rev. E, vol. 91 (4), 2015, 043009) to broadband flows. Considering a Reynolds decomposition of the flow field, the spectral (or temporal Fourier) mode of the fluctuation field is found to be equal to the action on a turbulent forcing term by the resolvent operator arising from linearisation about the mean flow. The main result of the article states that if, at a particular frequency, the dominant singular value of the resolvent is much larger than all others and if the turbulent forcing at this frequency does not display any preferential direction toward one of the suboptimal forcings, then the spectral mode is directly proportional to the dominant optimal response mode of the resolvent at this frequency. Such conditions are generally met in the case of weakly non-parallel open flows exhibiting a convectively unstable mean flow. The spatial structure of the singular mode may in these cases be approximated by a local spatial stability analysis based on parabolised stability equations (PSE). We have also shown that the frequency spectrum of the flow field at any arbitrary location of the domain may be predicted from the frequency evolution of the dominant optimal response mode and the knowledge of the frequency spectrum at one or more points. Results are illustrated in the case of a high Reynolds number turbulent backward facing step flow.

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A force-based coupling scheme for peridynamics and classical elasticity

Seleson

Beneddine

Prudhomme

2013

Computational Materials Science

159

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Transonic buffet instability: From two-dimensional airfoils to three-dimensional swept wings

et al. 2019

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Robust flow control and optimal sensor placement using deep reinforcement learning

2021

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Transition scenario in hypersonic axisymmetrical compression ramp flow

et al. 2020

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Unsteady flow dynamics reconstruction from mean flow and point sensors: an experimental study

et al. 2017

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This article presents a reconstruction of the unsteady behaviour of a round jet at a Reynolds number equal to 3300, from the sole knowledge of the time-averaged flow field and one pointwise unsteady measurement. The reconstruction approach is an application of the work of Beneddine et al. (J. Fluid Mech., vol. 798, 2016, pp. 485-504) and relies on the computation of the dominant resolvent modes of the flow, using a parabolised stability equations analysis. To validate the procedure, the unsteady velocity field of the jet has been characterised by time-resolved particle image velocimetry (TR-PIV), yielding an experimental reference. We first show that the dominant resolvent modes are proportional to the experimental Fourier modes, as predicted by Beneddine et al. (J. Fluid Mech., vol. 798, 2016, pp. 485-504). From these results, it is then possible to fully reconstruct the unsteady velocity and pressure fluctuation fields, yielding a flow field that displays good agreement with the experimental reference. Finally, it is found that the robustness of the reconstruction mainly depends on the location of the pointwise unsteady measurement, which should be within energetic regions of the flow, and this robustness as well as the quality of the reconstruction can be greatly improved by considering a few pointwise measurements instead of a single one. The effects of other experimental parameters on the reconstruction, such as the size of the interrogation window used for the TR-PIV processing and the accuracy of the positioning of the sensors, are also investigated in this paper.

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Concurrent Coupling of Bond-Based Peridynamics and the Navier Equation of Classical Elasticity by Blending

Seleson

Beneddine

2015

Int J Mult Comp Eng

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Link between subsonic stall and transonic buffet on swept and unswept wings: from global stability analysis to nonlinear dynamics

et al. 2020

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Samir Beneddine

Conditions for validity of mean flow stability analysis

A force-based coupling scheme for peridynamics and classical elasticity

Transonic buffet instability: From two-dimensional airfoils to three-dimensional swept wings

Robust flow control and optimal sensor placement using deep reinforcement learning

Transition scenario in hypersonic axisymmetrical compression ramp flow

Unsteady flow dynamics reconstruction from mean flow and point sensors: an experimental study

Concurrent Coupling of Bond-Based Peridynamics and the Navier Equation of Classical Elasticity by Blending

Link between subsonic stall and transonic buffet on swept and unswept wings: from global stability analysis to nonlinear dynamics

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