A single-camera synthetic Schlieren method for the measurement of free liquid surfaces

TL;DR

This paper presents a novel single-camera synthetic Schlieren technique for measuring free liquid surface heights, capable of capturing dynamic topography without prior surface reference, using light refraction and nonlinear equation solving.

Contribution

The method introduces a reference-free, real-time measurement approach for liquid surface topography based on light refraction and nonlinear equation solving.

Findings

Accurately measured surface ripples and dam-break flows

Demonstrated effectiveness without known reference surface height

Analyzed measurement uncertainties and limitations

Abstract

A single-camera synthetic Schlieren method is introduced to measure the height of a dynamic free liquid surface in a container with a flat bottom. Markers placed on the bottom, seen through the free surface, are virtually displaced due to light refraction at the surface. According to Snell's law, the marker displacements depend on the refractive indices of the transparent liquid and the air, and on the surface height and its spatial gradients. We solve the resulting governing nonlinear equation with the Newton-Raphson method to obtain the surface height. Our method does not require a reference surface height, which allows the measurement of surfaces topography in situations where the liquid depth is unknown. We demonstrate the accuracy of the method by performing experiments of surface ripples and dam-break flows and discuss the measurement uncertainty, errors and limitations.