Estimating density, velocity, and pressure fields in supersonic flow using physics-informed BOS

TL;DR

This paper introduces a physics-informed neural network approach for background-oriented schlieren (BOS) to accurately reconstruct density, velocity, and pressure fields in supersonic flows, surpassing traditional methods.

Contribution

The work presents the first use of a PINN for reconstructing supersonic flow fields from experimental BOS data, integrating physics constraints for improved accuracy.

Findings

Physics-informed BOS yields significantly more accurate density estimates.

The method provides velocity and pressure data not available in conventional BOS.

Demonstrated effectiveness on synthetic and experimental data.

Abstract

We report a new workflow for background-oriented schlieren (BOS), termed "physics-informed BOS," to extract density, velocity, and pressure fields from a pair of reference and distorted images. Our method uses a physics-informed neural network (PINN) to produce flow fields that simultaneously satisfy the measurement data and governing equations. For the high-speed flows of interest in this work, we specify a physics loss based on the Euler and irrotationality equations. BOS is a quantitative fluid visualization technique that is used to characterize high-speed flows. Images of a background pattern, positioned behind the target flow, are processed using computer vision and tomography algorithms to determine the density field. Crucially, BOS features a series of ill-posed inverse problems that require supplemental information (i.e., in addition to the images) to accurately reconstruct the flow. Current BOS workflows rely upon interpolation of the images or a penalty term to promote a globally- or piecewise-smooth solution. However, these algorithms are invariably incompatible with the flow physics, leading to errors in the density field. Physics-informed BOS directly reconstructs all the flow fields using a PINN that includes the BOS measurement model and governing equations. This procedure improves the accuracy of density estimates and also yields velocity and pressure data, which was not previously available. We demonstrate our approach by reconstructing synthetic data that corresponds to analytical and numerical phantoms as well as experimental measurements. Our physics-informed reconstructions are significantly more accurate than conventional BOS estimates. Further, to the best of our knowledge, this work represents the first use of a PINN to reconstruct a supersonic flow from experimental data of any kind.