Linear iterative method for closed-loop control of quasiperiodic flows

Leclercq, Colin; Demourant, Fabrice; Poussot-Vassal, Charles; Sipp, Denis

doi:10.1017/jfm.2019.112

Cited by 39 publications

(47 citation statements)

References 102 publications

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“…It should be mentioned that the largest drag increase among all DNS runs was observed for ∠Â d = 3π/4 and y + d = [20,25]. The Re τ of these runs increased by more than a factor of 2 and the simulations developed numerical instabilities due to insufficient grid resolution before a statistically steady state was reached.…”

Section: A Comparison Between the Rank-1 Resolvent Model And Dnsmentioning

confidence: 91%

“…Yeh and Taira [24] used the gains of the uncontrolled resolvent operator as proxy to identify adequate control parameters for separation control over an airfoil and showed that parameter combinations with high uncontrolled gain correspond to favorable controller settings. Leclerq et al [25] considered and controlled a two-dimensional incompressible open-cavity flow using structured H ∞ synthesis on a sequence of linear flow models, where each flow model of the sequence is based on the resolvent operator about the mean of the previous controlled flow. Their study shows that the controller is able to successfully suppress the oscillations in a sequence of five controllers.…”

Section: B Opposition Control and Low-order Modelingmentioning

confidence: 99%

“…The varying-phase opposition control scheme (9) introduced in the preceding section is used as a test to evaluate the capabilities of the resolvent model for controller design. To this end, a total of 50 varying-phase opposition control runs covering a parameter range of five sensor locations y + d = [5,10,15,20,25] and ten phase shifts ∠Â d = [−3π/4, −π/2, −3π/8, −π/4, −π/8, 0, π/8, π/4, π/2, 3π/4] were performed in the subsampled resolvent model and the DNS. The raw DR data were subsequently interpolated using bilinear splines and normalized with the respective maximum DR to generate the two contour maps of ξ shown in Fig.…”

Section: A Comparison Between the Rank-1 Resolvent Model And Dnsmentioning

confidence: 99%

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Predicting the response of turbulent channel flow to varying-phase opposition control: Resolvent analysis as a tool for flow control design

2019

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The present study evaluates the capabilities of a low-order flow model based on the resolvent analysis of McKeon and Sharma [B. J. McKeon and A. S. Sharma, J. Fluid Mech. 658, 336 (2010)] for the purpose of controller design for drag reduction in wall-bounded turbulent flows. To this end, we first show that the model is able to approximate the change in mean wall shear stress, which is commonly used as measure for drag reduction. We also derive an analytical expression that decomposes the drag reduction in internal flows into terms that can be predicted directly by the model and terms that allow for quantification of model error if high-fidelity data are available. We then show by example of varyingphase opposition control in a low-Reynolds-number turbulent channel flow that the drag reduction predicted by the resolvent model captures the trend observed in direct numerical simulation (DNS) over a wide range of controller parameters. The DNS results confirm the resolvent model prediction that the attainable drag reduction strongly depends on the relative phase between sensor measurement and actuator response, which raises interesting flow physics questions for future studies. The good agreement between the resolvent model and DNS further reveals that resolvent analysis, which at its heart is a linear technique, is able to approximate the response of the full nonlinear system to control. We also show that in order to make accurate predictions the model only needs to resolve a small subset of the DNS wave numbers and that the controlled resolvent modes obey the Reynoldsnumber scaling laws of the uncontrolled resolvent operator derived by Moarref et al. [R. Moarref et al., J. Fluid Mech. 734, 275 (2013)]. As a consequence, our results suggest that resolvent analysis can provide a suitable flow model to design feedback flow control schemes for the purpose of drag reduction in incompressible wall-bounded turbulent flows even at technologically relevant Reynolds numbers.

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Section: A Comparison Between the Rank-1 Resolvent Model And Dnsmentioning

confidence: 91%

Section: B Opposition Control and Low-order Modelingmentioning

confidence: 99%

Section: A Comparison Between the Rank-1 Resolvent Model And Dnsmentioning

confidence: 99%

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Predicting the response of turbulent channel flow to varying-phase opposition control: Resolvent analysis as a tool for flow control design

2019

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“…The response of coaxial two-fluid atomizers to a wide range of swirling and non-swirling gas co-flows has been investigated extensively (Aliseda et al, 2008;Eggers and Villermaux, 2008;Lasheras et al, 1998;Marmottant and Villermaux, 2004), providing the theoretical and experimental basis for this feedback control work. Additionally, over the last decade data reduction methods have been extensively applied for the reduced order description and control of fluid flows (Blanchard and Sapsis, 2019;Grenga et al, 2018;Hervé et al, 2012;Huang et al, 2017;Krolick and Owkes, 2018;Leclercq et al, 2019;Mohan and Gaitonde, 2017;Rabault et al, 2019;Rowley and Dawson, 2017;Schmid et al, 2011;Tallet et al, 2016). Here, we present a method to perform feedback closed-loop control of a spray atomizer where the control input consists of measurements of light attenuation across the depth of the spray at 10 gas diameters downstream of the nozzle and where the control actuation is on the swirl and no-swirl gas flow rates (defined over ranges that span the desired momentum ratios and swirl ratios of interest).…”

Section: Introductionmentioning

confidence: 99%

Feedback Control of Coaxial Atomization Based on the Spray Liquid Distribution

et al. 2019

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We demonstrate a novel implementation of real-time feedback control on the structure of the spray produced by a two-fluid coaxial atomizer. The ratio of angular to longitudinal gas flow rates, called swirl ratio, as well as the total amount of gas coflow are used as the actuation at the nozzle. The swirling and swirl-free gas flow rate are individually set by the control algorithm, with the control objective set based on an optical absorbance radial profile that is related to the liquid volume fraction across the spray. We analyzed the liquid volume fraction profiles measured in open loop by means of singular value decomposition and principal component analysis (PCA) and found that the different states of the spray across a wide range of operating conditions can be described with fidelity by three principal components. The control algorithm maps the resulting state PCA projections to the control variables. Real time control of the spray is achieved over a wide range of operating conditions (gas-to-liquid momentum 1 − 20 and swirl ratios 0 − 1).

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“…Ψ in (3.2)) (Bagheri et al 2009)? (ii) Can the GLE work on non-modal (Chen & Rowley 2011), quasi-periodic (Leclercq et al 2019) or multi-mode systems (Carini, Auteri & Giannetti 2015)? (iii) Can nonlinear effects be ignored (Leclercq et al 2019)?…”

Section: Discussionmentioning

confidence: 99%