The influence of control on proper orthogonal decomposition of wall-bounded turbulent flows

Prabhu, R. D.; Collis, S. Scott; Chang, Yong

doi:10.1063/1.1333038

Cited by 53 publications

(47 citation statements)

References 26 publications

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“…In the realm of control, KL methods have been used to produce drag reduction in a turbulent channel flow by phase randomization of the structures 21 and to understand the effect of drag reduction by controlled wall normal suction and blowing. 22 In the present study, the KL framework is used to examine the differences in the turbulent structures and dynamics between turbulent pipe flow with and without spanwise wall oscillation.…”

Section: Introductionmentioning

confidence: 99%

The effect of spanwise wall oscillation on turbulent pipe flow structures resulting in drag reduction

2007

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The results of a comparative analysis based upon a Karhunen–Loève expansion of turbulent pipe flow and drag reduced turbulent pipe flow by spanwise wall oscillation are presented. The turbulent flow is generated by a direct numerical simulation at a Reynolds number Reτ=150. The spanwise wall oscillation is imposed as a velocity boundary condition with an amplitude of A+=20 and a period of T+=50. The wall oscillation results in a 27% mean velocity increase when the flow is driven by a constant pressure gradient. The peaks of the Reynolds stress and root-mean-squared velocities shift away from the wall and the Karhunen–Loève dimension of the turbulent attractor is reduced from 2763 to 1080. The coherent vorticity structures are pushed away from the wall into higher speed flow, causing an increase of their advection speed of 34% as determined by a normal speed locus. This increase in advection speed gives the propagating waves less time to interact with the roll modes. This leads to less energy transfer and a shorter lifespan of the propagating structures, and thus less Reynolds stress production which results in drag reduction.

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Section: Introductionmentioning

confidence: 99%

The effect of spanwise wall oscillation on turbulent pipe flow structures resulting in drag reduction

2007

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“…The POD basis gives an optimal representation, in terms of kinetic energy, of the database of snapshots used to build the basis itself and generated by the system. However, when the input parameters vary, the basis becomes inaccurate, as it is the case in control problems (see [18,3]). The focus of this section is to improve the representation capabilities of a POD basis of a given flow when the Reynolds number (input parameter of the system) varies in a given range, so as to provide a single ROM that is efficient for the considered range.…”

Section: Improvement Of the Pod Rom Robustnessmentioning

confidence: 99%

Low-order models. Optimal sampling and linearized control strategies

Lombardi¹,

Bergmann²,

Camarri³

et al. 2011

ournal Européen des Systèmes Automatisés

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“…The main drawback for flow control is that the POD basis is only able to give an optimal representation of the snapshots set from which it was derived. The approximation properties of the basis can be greatly degraded under variation of some input system parameters values, as control parameters [15][16][17] . For flow control purposes, some special care has to be taken to build the POD basis functions.…”

Section: Improvement Of the Functional Subspacementioning

confidence: 99%

“…Indeed, for flow control purpose, it was demonstrated [15][16][17] that POD basis functions built from a flow database generated with a given set of control parameters is not able to represent the main features of a flow generated with another set of control parameters. To overcome this problem, we propose to derive methods allowing to adapt the POD basis functions at low numerical costs.…”

Section: Reduced Order Models Based On Proper Orthogonal Decompositionmentioning

confidence: 99%

Enablers for robust POD models

Bergmann

Bruneau

Iollo

2009

Journal of Computational Physics

285

292

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This paper focuses on improving the stability as well as the approximation properties of Reduced Order Models (ROM) based on Proper Orthogonal Decomposition (POD). The ROM is obtained by seeking a solution belonging to the POD subspace and that at the same time minimizes the Navier-Stokes residuals. We propose a modified ROM that directly incorporates the pressure term in the model. The ROM is then stabilized making use of a method based on the fine scale equations. An improvement of the POD solution subspace is performed thanks to an hybrid method that couples direct numerical simulations and reduced order model simulations. The methods proposed are tested on the two-dimensional confined square cylinder wake flow in laminar regime.

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The influence of control on proper orthogonal decomposition of wall-bounded turbulent flows

Cited by 53 publications

References 26 publications

The effect of spanwise wall oscillation on turbulent pipe flow structures resulting in drag reduction

The effect of spanwise wall oscillation on turbulent pipe flow structures resulting in drag reduction

Low-order models. Optimal sampling and linearized control strategies

Enablers for robust POD models

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