Simultaneous broadband laser ranging and photonic Doppler velocimetry for dynamic compression experiments

A diagnostic was developed to simultaneously measure both the distance and velocity of rapidly moving surfaces in dynamic compression experiments, specifically non-planar experiments where integrating the velocity in one direction does not always give the material position accurately. The diagnostic...

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Bibliographic Details
Published in:Review of scientific instruments 2015-02, Vol.86 (2), p.023112-023112
Main Authors: La Lone, B M, Marshall, B R, Miller, E K, Stevens, G D, Turley, W D, Veeser, L R
Format: Article
Language:English
Subjects:
Broadband
Compression tests
Cylinders
Diagnostic systems
Distance measurement
Ejecta
Ejection
Experiments
Fiber optics
Laser ranging
Optical fibers
Photonics
Scientific apparatus & instruments
Velocimetry
Velocity
Velocity measurement
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Summary:A diagnostic was developed to simultaneously measure both the distance and velocity of rapidly moving surfaces in dynamic compression experiments, specifically non-planar experiments where integrating the velocity in one direction does not always give the material position accurately. The diagnostic is constructed mainly from fiber-optic telecommunications components. The distance measurement is based on a technique described by Xia and Zhang [Opt. Express 18, 4118 (2010)], which determines the target distance every 20 ns and is independent of the target speed. We have extended the full range of the diagnostic to several centimeters to allow its use in dynamic experiments, and we multiplexed it with a photonic Doppler velocimetry (PDV) system so that distance and velocity histories can be measured simultaneously using one fiber-optic probe. The diagnostic was demonstrated on a spinning square cylinder to show how integrating a PDV record can give an incorrect surface position and how the ranging diagnostic described here obtains it directly. The diagnostic was also tested on an explosive experiment where copper fragments and surface ejecta were identified in both the distance and velocity signals. We show how the distance measurements complement the velocity data. Potential applications are discussed.
ISSN:0034-6748
1089-7623
DOI:10.1063/1.4908306