Artificial intelligence control of a turbulent jet

An artificial intelligence (AI) control system is developed to maximize the mixing rate of a turbulent jet. This system comprises of six independently operated unsteady minijet actuators, two hot-wire sensors placed in the jet and genetic programming for the unsupervised learning of a near-optimal c...

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Bibliographic Details
Published inJournal of fluid mechanics Vol. 897
Main Authors Zhou, Yu, Fan, Dewei, Zhang, Bingfu, Li, Ruiying, Noack, Bernd R.
Format Journal Article
LanguageEnglish
Published Cambridge, UK Cambridge University Press 25.08.2020
Subjects
Acoustics
Actuators
Artificial intelligence
Control
Control systems
Control theory
Decay rate
Experiments
Flapping
Flow structures
Flow visualization
Fluid dynamics
Genetic algorithms
JFM Papers
Learning
Machine learning
Mushrooms
Nozzle geometry
Optimal control
Optimization
Orthogonality
Physics
Planes
Sensors
Turbulence
Turbulent flow
Turbulent jets
Unsupervised learning
Velocity
Velocity distribution
Vortices
turbulence control
mixing enhancement
jets
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Summary:An artificial intelligence (AI) control system is developed to maximize the mixing rate of a turbulent jet. This system comprises of six independently operated unsteady minijet actuators, two hot-wire sensors placed in the jet and genetic programming for the unsupervised learning of a near-optimal control law. The ansatz of this law includes multi-frequency open-loop forcing, sensor feedback and nonlinear combinations thereof. Mixing performance is quantified by the decay rate of the centreline mean velocity of the jet. Intriguingly, the learning process of AI control discovers the classical forcings, i.e. axisymmetric, helical and flapping achievable from conventional control techniques, one by one in the order of increased performance, and finally converges to a hitherto unexplored forcing. Careful examination of the control landscape unveils typical control laws, generated in the learning process, and their evolutions. The best AI forcing produces a complex turbulent flow structure that is characterized by periodically generated mushroom structures, helical motion and an oscillating jet column, all enhancing the mixing rate and vastly outperforming others. Being never reported before, this flow structure is examined in various aspects, including the velocity spectra, mean and fluctuating velocity fields and their downstream evolution, and flow visualization images in three orthogonal planes, all compared with other classical flow structures. Along with the knowledge of the minijet-produced flow and its effect on the initial condition of the main jet, these aspects cast valuable insight into the physics behind the highly effective mixing of this newly found flow structure. The results point to the great potential of AI in conquering the vast opportunity space of control laws for many actuators and sensors and in optimizing turbulence.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2020.392