Linear stability and spectral modal decomposition of three-dimensional turbulent wake flow of a generic high-speed train

This work investigates the spatio-temporal evolution of coherentstructures in the wake of a generic high-speed train. Spectral properorthogonal decomposition is used to extract energy spectra and empiricalmodes of the fluctuating field. The spectrum of the symmetriccomponent shows overall higher energy and more pronounced low-rankbehavior compared to the antisymmetric one, with the most dominantsymmetric mode at $\omega=3.437$ characterized by vortex sheddingin the near wake and constant streamwise wavenumber structures in thefar wake. The mode bispectrum further reveals the dominant role of selfinteraction of the symmetric component, leading to first harmonic andsubharmonic triads of the fundamental frequency. Then, the stability ofthe wake flow is analyzed based on two-dimensional local analysis. Theabsolute frequency of the near-wake eigenmode is determined based onspatio-temporal analysis, then tracked along the streamwise direction tofind out the global frequency, which indicate a marginally stable globalmode oscillating at a frequency very close to the dominant SPOD mode.The global mode wavemaker is then located, and the structuralsensitivity is calculated based on the direct and adjoint modes derivedfrom a local spatial analysis, with the maximum value localized withinthe recirculation region close to the train tail. Finally, the global modeshape is computed by tracking the most spatially unstable eigenmode,and the alignment with the SPOD mode is computed as a function ofstreamwise location. By combining data-driven and theoreticalapproaches, the mechanisms of coherent structures in complex wakeflows are well identified and isolated.

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