Large field Digital Image Plane Holography with a double cavity high speed laser

The three velocity components in a fluid plane can be measured by applying Digital Image Plane Holography. This technique is limited by the laser coherence length, which reduces its application with high speed lasers that, generally, have a very short coherence length. In addition, the use of a double cavity can also imply a small wavelength difference between the two laser beams. In this work, we present an improved Optical Path Length Enlarging Device that allows the velocity measurement, in a 2D field whose width is four times larger than the laser coherence length. The optical set-up and the procedure for measuring in a larger field (ten times the laser coherence length) were optimized, and the issues derived from the laser spatial and temporal coherence and wavelength changes were analyzed and solved. Digital Image Plane Holography with the Optical Path Length Enlarging Device and Particle Image Velocimetry were applied for measuring the whole velocity field in the central plane of a cylindrical cavity with a rotating lid, for two Reynolds numbers (800 and 2000), showing both of them a very good agreement with the numerical simulations. [GRAPHICS] .

Automated summary

The three velocity components in a fluid plane can be measured using Digital Image Plane Holography. However, this technique is limited by the laser coherence length. In this study, an improved Optical Path Length Enlarging Device was introduced to measure the velocity in a 2D field four times larger than the laser coherence length, and the issues related to laser coherence and wavelength changes were addressed. The Optical Path Length Enlarging Device and Particle Image Velocimetry were applied to measure the velocity field in the central plane of a cylindrical cavity, showing good agreement with numerical simulations.