Nonmechanical compact probe for cross-sectional velocity measurement based on differential laser Doppler velocimetry

In this study, we propose and demonstrate a nonmechanical compact probe for cross-sectional velocity measurement based on differential laser Doppler velocimetry. The system introduces a method that combines simultaneous multipoint measurement using spatial encoding and nonmechanical scanning of meas...

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Bibliographic Details
Published in:Review of scientific instruments 2017-04, Vol.88 (4), p.045001-045001
Main Authors: Maru, K., Katsumi, S., Matsuda, R.
Format: Article
Language:English
Subjects:
Aluminum
Coding
Fiber optics
Laser doppler velocimeters
Lithium niobates
Optical fibers
Phase shifters
Velocimetry
Velocity distribution
Velocity measurement
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Summary:In this study, we propose and demonstrate a nonmechanical compact probe for cross-sectional velocity measurement based on differential laser Doppler velocimetry. The system introduces a method that combines simultaneous multipoint measurement using spatial encoding and nonmechanical scanning of measurement points, in which spatially encoded measurement points aligned along the transverse direction are scanned in the axial direction by changing the wavelength. The use of a waveguide-type LiNbO3 phase shifter array for serrodyne frequency shifting is feasible for the system based on fiber optics with an easily handled probe. To miniaturize the probe, a multimode fiber is introduced in the receiving optics and the parameters of the lens system in the transmitting optics are optimized. For the experiment, an eight-channel probe was assembled on an aluminum plate with an 8 cm Ă— 8 cm area size. The experimental results reveal that the cross-sectional two-dimensional velocity distribution was successfully measured using the easily handled compact probe for the first time.
ISSN:0034-6748
1089-7623
DOI:10.1063/1.4979563