Dynamic Mode Decomposition for Large-Scale Coherent Structure Extraction in Shear Flows

Large-scale structures have been observed in many shear flows which are the fluid generated between two surfaces moving with different velocity. A better understanding of the physics of the structures (especially large-scale structures) in shear flows will help explain a diverse range of physical phenomena and improve our capability of modeling more complex turbulence flows. Many efforts have been made in order to capture such structures; however, conventional methods have their limitations, such as arbitrariness in parameter choice or specificity to certain setups. To address this challenge, we propose to use Multi-Resolution Dynamic Mode Decomposition (mrDMD), for large-scale structure extraction in shear flows. In particular, we show that the slow motion DMD modes are able to reveal large-scale structures in shear flows that also have slow dynamics. In most cases, we find that the slowest DMD mode and its reconstructed flow can sufficiently capture the large-scale dynamics in the shear flows, which leads to a parameter-free strategy for large-scale structure extraction. Effective visualization of the large-scale structures can then be produced with the aid of the slowest DMD mode. To speed up the computation of mrDMD, we provide a fast GPU-based implementation. We also apply our method to some non-shear flows that need not behave quasi-linearly to demonstrate the limitation of our strategy of using the slowest DMD mode. For non-shear flows, we show that multiple modes from different levels of mrDMD may be needed to sufficiently characterize the flow behavior.

Automated summary

Large-scale structures in shear flows play a significant role in understanding physical phenomena and modeling complex turbulence flows. To address the limitations of conventional methods, we propose the use of Multi-Resolution Dynamic Mode Decomposition (mrDMD) to extract large-scale structures in shear flows. Our method utilizes slow motion DMD modes to capture the dynamics of these structures and provides an efficient way to visualize them. We also provide a GPU-based implementation to speed up the computation of mrDMD.