Litcius/Paper detail

Sparsifying the resolvent forcing mode via gradient-based optimisation

Calum S. Skene, C. Yeh, Peter J. Schmid, Kunihiko Taira

2022Journal of Fluid Mechanics30 citationsDOI

Abstract

We consider the use of sparsity-promoting norms in obtaining localised forcing structures from resolvent analysis. By formulating the optimal forcing problem as a Riemannian optimisation, we are able to maximise cost functionals whilst maintaining a unit-energy forcing. Taking the cost functional to be the energy norm of the driven response results in a traditional resolvent analysis and is solvable by a singular value decomposition (SVD). By modifying this cost functional with the $L_1$ -norm, we target spatially localised structures that provide an efficient amplification in the energy of the response. We showcase this optimisation procedure on two flows: plane Poiseuille flow at Reynolds number $Re=4000$ , and turbulent flow past a NACA 0012 aerofoil at $Re=23\,000$ . In both cases, the optimisation yields sparse forcing modes that maintain important features of the structures arising from an SVD in order to provide a gain in energy. These results showcase the benefits of utilising a sparsity-promoting resolvent formulation to uncover sparse forcings, specifically with a view to using them as actuation locations for flow control.

Topics & Concepts

ResolventForcing (mathematics)AirfoilComputer scienceSingular value decompositionNorm (philosophy)Dynamic mode decompositionApplied mathematicsTurbulenceReynolds numberHagen–Poiseuille equationFlow (mathematics)Mathematical optimizationControl theory (sociology)MathematicsAlgorithmPhysicsMathematical analysisMechanicsGeometryControl (management)LawMachine learningPolitical scienceArtificial intelligenceFluid Dynamics and Turbulent FlowsModel Reduction and Neural NetworksAerodynamics and Acoustics in Jet Flows