Data-driven time-dependent bases for turbulent airfoil wake-extreme vortex gust interactions
Authors
Shaghayegh Zamani Ashtiani, Kai Fukami
Categories
Abstract
We analyze interactions between turbulent airfoil wake and an extremely strong gust using a data-driven framework with time-dependent bases. The current approach represents each snapshot with time-varying bases consisting of two-dimensional in-plane modes and one-dimensional spanwise modes, together with a reduced covariance matrix. We derive closed-form evolution equations for these time-varying components and advance them over time, requiring only a small rolling window and avoiding full-history storage. Applied to extreme vortex gust-airfoil interaction at Re=5000, we examine how in-plane modes and their associated energy level evolve across gust conditions of varying intensity and size. Before impingement, the first in-plane mode dominates; after impingement, the second mode gains energy_amplified by stronger/larger gusts. A larger leading-mode energy gap implies coherent structure and faster recovery; a smaller gap with slower decay indicates richer multiscale activity and delayed re-stabilization. These trends follow the transient lift dynamics as well, with higher amplitude and more oscillations indicated by a rise in the leading singular values. This work provides an interpretable, time-varying data-driven modal analysis of extreme gust encounter.
Data-driven time-dependent bases for turbulent airfoil wake-extreme vortex gust interactions
Categories
Abstract
We analyze interactions between turbulent airfoil wake and an extremely strong gust using a data-driven framework with time-dependent bases. The current approach represents each snapshot with time-varying bases consisting of two-dimensional in-plane modes and one-dimensional spanwise modes, together with a reduced covariance matrix. We derive closed-form evolution equations for these time-varying components and advance them over time, requiring only a small rolling window and avoiding full-history storage. Applied to extreme vortex gust-airfoil interaction at Re=5000, we examine how in-plane modes and their associated energy level evolve across gust conditions of varying intensity and size. Before impingement, the first in-plane mode dominates; after impingement, the second mode gains energy_amplified by stronger/larger gusts. A larger leading-mode energy gap implies coherent structure and faster recovery; a smaller gap with slower decay indicates richer multiscale activity and delayed re-stabilization. These trends follow the transient lift dynamics as well, with higher amplitude and more oscillations indicated by a rise in the leading singular values. This work provides an interpretable, time-varying data-driven modal analysis of extreme gust encounter.
Authors
Shaghayegh Zamani Ashtiani, Kai Fukami
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