Train yourself: self-compressing reduced-order models of turbulent flows

TL;DR

This paper introduces a novel data-free reduced-order model for turbulent flows that self-compresses using controllability modes, accurately capturing turbulence statistics without prior simulation data.

Contribution

It proposes a self-compression technique for ROMs based on controllability modes, eliminating the need for simulation data while maintaining accuracy.

Findings

Maintains accurate turbulence statistics in reduced dimensions.

Recovers spatial structures similar to POD without simulation data.

Achieves further reduction in model complexity.

Abstract

Reduced-order models (ROMs) of turbulent flows based on Galerkin projection often require many degrees of freedom to resolve the dynamics of the turbulence, or simulation data to obtain an optimal modal basis. However, obtaining simulation data is computationally expensive, and the amount of data required to obtain a converged modal basis can increase this cost. Using the linearized Navier-Stokes equations, one can achieve spatial modes through the controllability and observability Gramians, which can yield a ROM without prior simulation data. In this work, we propose a self-compression of a ROM based on controllability modes, where the time series of the modal coefficients are leveraged to reduce the dimension of the ROM. In the self-compressed ROM (SCROM), we can maintain accurate first- and second-order statistics with respect to the DNS simulation, but in a further reduced dimension. The SCROM recovers spatial structures equivalent to proper orthogonal decomposition (POD) without relying on any simulation data, recombining spatial modes from linearized equations. This method leads to a novel ROM that can represent turbulence statistics in a data-free approach in a further reduced state space.