Background oriented schlieren technique with fast Fourier demodulation for measuring large density-gradient fields of fluids

TL;DR

This paper introduces a fast Fourier demodulation method within the Background Oriented Schlieren technique to effectively measure large density-gradient fields in fluids, outperforming traditional methods in displacement measurement range.

Contribution

The study demonstrates that Fast Checkerboard Demodulation (FCD) enhances BOS by allowing larger displacement measurements using simple, commercially available patterns, and systematically investigates its measurement limits.

Findings

FCD measures displacement gradients 2.5 times larger than PIV.

FCD with lattice grid patterns achieves accuracy comparable to custom patterns.

The measurement limit depends on pattern parameters and Fourier space analysis.

Abstract

In order to measure the large density-gradient fields of fluids such as underwater shock waves, we employed a fast Fourier demodulation called Fast Checkerboard Demodulation (FCD) method in Background Oriented Schlieren (BOS) technique. BOS is a simple image-based measurement technique that detects the apparent displacement (local distortion) of a background image caused by the density gradient of the fluid in front of the background. The cross-correlation particle image velocimetry (PIV) method, which is commonly employed in the BOS technique for detecting the apparent displacement, uses a random-dot background, whereas FCD uses a periodic pattern as the background (e.g., checkerboard pattern, lattice grid pattern (grid scale)) to detect the apparent displacement as the phase change of the pattern in the Fourier space. In this study, we measured the apparent displacement, which is proportional to density gradient of fluid, of an underwater shock wave using FCD and PIV. The results showed that FCD can measure a displacement gradient of up to 2.5 times larger than that which PIV can measure. Furthermore, we systematically investigated the measurement limit of FCD-BOS by changing several parameters of the periodic patterns, such as the grid size. Also, we explored the related parameters in the Fourier space to understand the limitations. It is worth noting that FCD-BOS with lattice grid pattern (grid scale) can measure the apparent displacement as accurately as that with a custom-made pattern, indicating that large density-gradient fields of fluids can be measured using a simple setup with a commercially available (inexpensive) pattern.