Sensitivity and open-loop control of stochastic response in a noise amplifier flow: the backward-facing step

TL;DR

This paper develops a variational sensitivity analysis method for stochastic noise amplification in a backward-facing step flow, enabling targeted control strategies without full flow computations.

Contribution

It extends existing sensitivity techniques to account for stochastic and localized inlet disturbances, aiding in designing effective flow control.

Findings

Sensitivity maps align with harmonic amplification at dominant frequencies.

Passive and active controls are analyzed for specific flow parameters.

Control focus can be simplified by targeting the most dangerous perturbations.

Abstract

The two-dimensional backward-facing step flow is a canonical example of noise amplifier flow: global linear stability analysis predicts that it is stable, but perturbations can undergo large amplification in space and time as a result of non-normal effects. This amplification potential is best captured by optimal transient growth analysis, optimal harmonic forcing, or the response to sustained noise. In view of reducing disturbance amplification in these globally stable open flows, a variational technique is proposed to evaluate the sensitivity of stochastic amplification to steady control. Existing sensitivity methods are extended in two ways to achieve a realistic representation of incoming noise: (i) perturbations are time-stochastic rather than time-harmonic, (ii) perturbations are localised at the inlet rather than distributed in space. This allows for the identification of regions where small-amplitude control is the most effective, without actually computing any controlled flows. In particular, passive control by means of a small cylinder and active control by means of wall blowing/suction are analysed for Reynolds number $Re=500$ and step-to-outlet expansion ratio $\Gamma=0.5$. Sensitivity maps for noise amplification appear largely similar to sensitivity maps for optimal harmonic amplification at the most amplified frequency. This is observed at other values of $Re$ and $\Gamma$ too, and suggests that the design of steady control in this noise amplifier flow can be simplified by focusing on the most dangerous perturbation at the most dangerous frequency.