Flame Reconstruction Using Synthetic Aperture Imaging

TL;DR

This paper demonstrates a novel application of synthetic aperture imaging to reconstruct three-dimensional flames, enabling non-intrusive temperature measurement and improved understanding of flame dynamics.

Contribution

It introduces the use of synthetic aperture imaging for 3D reconstruction of flames, providing a new method for non-intrusive flame analysis.

Findings

Successful 3D reconstruction of methane flames

Synthetic aperture imaging matches raw image shapes

Potential for non-intrusive temperature measurement

Abstract

Flames can be formed by burning methane (CH4). When oxygen is scarce, carbon particles nucleate into solid particles called soot. These particles emit photons, making the flame yellow. Later, methane is pre-mixed with air forming a blue flame; burning more efficiently, providing less soot and light. Imaging flames and knowing their temperature are vital to maximizing efficiency and validating numerical models. Most temperature probes disrupt the flame and create differences leading to an inaccurate measurement of the flame temperature. We seek to image the flame in three dimensions using synthetic aperture imaging. This technique has already successfully measured velocity fields of a vortex ring [1]. Synthetic aperture imaging is a technique that views one scene from multiple cameras set at different angles, allowing some cameras to view objects that are obscured by others. As the resulting images are overlapped different depths of the scene come into and out of focus, known as focal planes, similar to tomography. These focal planes can be used to extract three-dimensional information about the scene. This procedure was used to extract the outer edge of a oxygen-starved methane flame (yellow) from which the three-dimensional flame was reconstructed. When the reconstructed image was compared to the raw image from the central camera the two shapes corresponded well. This experiment in the fluid dynamics video (entry #: V041) demonstrated that a three-dimensional flame can be reconstructed by combining images from multiple cameras using synthetic aperture imaging.