📝 SummarXiv

Abstract

Flow transition from a stable to unstable states and eventually to turbulence is a classical fluid mechanics phenomenon with a strong practical relevance. Conventional hydrodynamic stability deals with perturbation dynamics on a steady baseflow, typically in Eulerian reference frame. Common modal techniques, e.g., linear stability theory, involve linearization of governing flow equations and flow/geometrical simplifications, which can be tedious and restrictive. This paper presents a perturbation-free data-driven stability analysis technique by employing Lagrangian modal/non-modal analysis (Shinde & Gaitonde 2021), particularly the adjoint form of Lagrangian dynamics mode decomposition in the forward time direction. The proposed Lagrangian stability analysis technique (LagSAT) builds on the fact that a steady non-uniform fluid flow in the Eulerian reference frame can be perceived as an unsteady flow in the Lagrangian reference frame. LagSAT is demonstrated on classical baseflows that exhibit convective/absolute instabilities, namely, the self-similar Blasius/Falkner-Skan boundary layers, a 2D compressible flow past a cylinder, and a 2D compressible lid-driven cavity flow, producing neutral stability curves, N-factor estimate, and transient energy growth. LagSAT is naturally suitable for the global analysis of large/complex numerical/experimental baseflows with multiphysics effects.