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Cluster-based hierarchical network model of the fluidic pinball – cartographing transient and post-transient, multi-frequency, multi-attractor behaviour

Nan Deng, Bernd R. Noack, Marek Morzyński, Luc Pastur

2022Journal of Fluid Mechanics30 citationsDOIOpen Access PDF

Abstract

We propose a self-supervised cluster-based hierarchical reduced-order modelling methodology to model and analyse the complex dynamics arising from a sequence of bifurcations for a two-dimensional incompressible flow of the fluidic pinball. The hierarchy is guided by a triple decomposition separating a slowly varying base flow, dominant shedding and secondary flow structures. All these flow components are kinematically resolved by a hierarchy of clusters. The transition dynamics between these clusters is described by a directed network, called the cluster-based hierarchical network model (HiCNM). Three consecutive Reynolds number regimes for different dynamics are considered: (i) periodic shedding at $Re=80$ , (ii) quasi-periodic shedding at $Re=105$ and (iii) chaotic shedding at $Re=130$ , involving three unstable fixed points, three limit cycles, two quasi-periodic attractors and a chaotic attractor. The HiCNM enables identification of the dynamics between multiple invariant sets in a self-supervised manner. Both the global trends and the local structures during the transition are well resolved by a moderate number of hierarchical clusters. The proposed HiCNM provides a visual representation of transient and post-transient, multi-frequency, multi-attractor behaviour and may automate the identification and analysis of complex dynamics with multiple scales and multiple invariant sets.

Topics & Concepts

AttractorVortex sheddingTransient (computer programming)Reynolds numberChaoticComputer scienceFlow (mathematics)PhysicsStatistical physicsTopology (electrical circuits)MathematicsMechanicsMathematical analysisArtificial intelligenceTurbulenceOperating systemCombinatoricsFluid Dynamics and Turbulent FlowsFluid Dynamics and Vibration AnalysisModel Reduction and Neural Networks