Closed-loop separation control using machine learning

Gautier, N.; Aider, Jean-Luc; Duriez, Thomas; Noack, Bernd R.; Segond, Marc; Abel, Markus

doi:10.1017/jfm.2015.95

Cited by 183 publications

(116 citation statements)

References 41 publications

(65 reference statements)

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“…Sensor-based feedback has been shown to outperform periodic forcing for drag reduction of a D-shaped body (Pastoor et al 2008). A very general method for sensor-based feedback is provided by genetic programming control (GPC) (Gautier et al 2015;Debien et al 2016;Parezanović et al 2016). Yet, the advantages of filtering out noise has hardly been explored in GPC ).…”

Section: Discussionmentioning

confidence: 99%

“…The regression problem is solved with symbolic genetic programming using the plant (experiment) to evolve the control law. This model-free control strategy can detect and exploit nonlinear actuation mechanisms in an unsupervised manner as evidenced in several shear flow control experiments (Gautier et al 2015;Debien et al 2016;Parezanović et al 2016).…”

Section: Introductionmentioning

confidence: 98%

“…The flow is monitored with pressure sensors distributed at the rear side. We apply a model-free control strategy building on Dracopoulos & Kent (1997) and Gautier et al (2015). The optimized control laws comprise periodic forcing, multi-frequency forcing and sensor-based feedback including also time-history information feedback and combination thereof.…”

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confidence: 99%

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Drag reduction of a car model by linear genetic programming control

Noack

Cordier

et al. 2017

Exp Fluids

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We investigate open-and closed-loop active control for aerodynamic drag reduction of a car model. Turbulent flow around a blunt-edged Ahmed body is examined at Re H ≈ 3 × 10 5 based on body height. The actuation is performed with pulsed jets at all trailing edges combined with a Coanda deflection surface. The flow is monitored with pressure sensors distributed at the rear side. We apply a model-free control strategy building on Dracopoulos & Kent (1997) and Gautier et al. (2015). The optimized control laws comprise periodic forcing, multi-frequency forcing and sensor-based feedback including also time-history information feedback and combination thereof. Key enabler is linear genetic programming as simple and efficient framework for multiple inputs (actuators) and multiple outputs (sensors). The proposed linear genetic programming control can select the best open-or closed-loop control in an unsupervised manner. Approximately 33% base pressure recovery associated with 22% drag reduction is achieved in all considered classes of control laws. Intriguingly, the feedback actuation emulates periodic high-frequency forcing by selecting one pressure sensor in the optimal control law. Our control strategy is, in principle, applicable to all multiple actuators and sensors experiments.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

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Drag reduction of a car model by linear genetic programming control

Noack

Cordier

et al. 2017

Exp Fluids

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“…While some flow control methods such as extremum seeking (Henning et al 2008) and machine learning control (Gautier et al 2015) are model free, many more rely on having a mathematical model, and often a linear model, of the fluid system. For example, black-box linear models have often been used for convectively unstable flows such as the backward-facing step (Barbagallo et Modelling and feedback control of bistability in a turbulent bluff body wake 729 flows behave like a linear amplifier, thus allowing linear models to be obtained for various input-output behaviours.…”

Section: R D Brackston and Othersmentioning

confidence: 99%

Stochastic modelling and feedback control of bistability in a turbulent bluff body wake

et al. 2016

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A specific feature of three-dimensional bluff body wakes, flow bistability, is a subject of particular recent interest. This feature consists of a random flipping of the wake between two asymmetric configurations and is believed to contribute to the pressure drag of many bluff bodies. In this study we apply the modelling approach recently suggested for axisymmetric bodies by Rigas et al. (J. Fluid Mech., vol. 778, 2015, R2) to the reflectional symmetry-breaking modes of a rectilinear bluff body wake. We demonstrate the validity of the model and its Reynolds number independence through time-resolved base pressure measurements of the natural wake. Further, oscillating flaps are used to investigate the dynamics and time scales of the instability associated with the flipping process, demonstrating that they are largely independent of Reynolds number. The modelling approach is then used to design a feedback controller that uses the flaps to suppress the symmetry-breaking modes. The controller is successful, leading to a suppression of the bistability of the wake, with concomitant reductions in both lateral and streamwise forces. Importantly, the controller is found to be efficient, the actuator requiring only 24 % of the aerodynamic power saving. The controller therefore provides a key demonstration of efficient feedback control used to reduce the drag of a high-Reynolds-number three-dimensional bluff body. Furthermore, the results suggest that suppression of large-scale structures is a fundamentally efficient approach for bluff body drag reduction.

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“…In the present study, because genetic algorithm only requires the evaluation of the cost function regarding a set of control parameters, such an evolutionary algorithm is used in conjunction with experimental measurements in a feedback loop process. Here, the objective is not to define a function transfer (control law) between the sensors, and thus local or global flow conditions, and the actuator as it has been recently done in [33,34]. The present contribution interests in finding the best operating conditions over a large parameter space by coupling for the first time a numerical optimizer and tests conducted in an experimental wind-tunnel.…”

Section: /23mentioning

confidence: 99%

Multi-Input Genetic Algorithm for Experimental Optimization of the Reattachment Downstream of a Backward-Facing-Step with Surface Plasma Actuator

Bénard

Prats

Périaux

et al. 2015

46th AIAA Plasmadynamics and Lasers Conference

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The practical interest of flow control approaches is no more debated as flow control provides an effective mean for considerably increasing the performances of ground or air transport systems, among many others applications. Here a fundamental configuration is investigated by using non-thermal surface plasma discharge. A dielectric barrier discharge is installed at the step corner of a backward-facing step (Re h =30000, Re θ =1650). Wall pressure sensors are used to estimate the reattaching location downstream of the step. The primary objective of this paper is the coupling of a numerical optimizer with an experiment. More specifically, optimization by genetic algorithm is implemented experimentally in order to minimize the reattachment point downstream of the step model. Validation through inverse problem is firstly demonstrated. When coupled with the plasma actuator and the wall pressure sensors, the genetic algorithm finds the optimum forcing conditions with a good convergence rate, the best control design variables being in agreement with the literature that uses other types of control devices than plasma. Indeed, the minimum reattaching position is achieved by forcing the flow at the shear layer mode where a large spreading rate is obtained by increasing the periodicity of the vortex street and by enhancing the vortex pairing phenomena. At the best forcing conditions, the mean flow reattachment is reduced by 20%. This article, with its experiment-based approach, demonstrates the robustness of a single-objective multi-design optimization method, and its feasibility for wind tunnel experiments.

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Closed-loop separation control using machine learning

Cited by 183 publications

References 41 publications

Drag reduction of a car model by linear genetic programming control

Drag reduction of a car model by linear genetic programming control

Stochastic modelling and feedback control of bistability in a turbulent bluff body wake

Multi-Input Genetic Algorithm for Experimental Optimization of the Reattachment Downstream of a Backward-Facing-Step with Surface Plasma Actuator

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