Angular velocimetry for fluid flows: an optical sensor using structured light and machine learning

Strong, Elizabeth F.; Anderson, Alexander Q.; Brenner, Michael P.; Heffernan, Brendan M.; Hoghooghi, Nazanin; Gopinath, Juliet T.; Rieker, Gregory B.

doi:10.1364/oe.417210

Cited by 6 publications

(1 citation statement)

References 25 publications

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“…A very similar experimental configuration has also been used in the case of light scattering in a liquid [56][57][58][59] (see Figure 8a). An OAM carrying optical beam is scattered by a rotating fluid.…”

Section: Diffusion On a Rotating Surfacementioning

confidence: 99%

Rotational Doppler Effect: A Review

Emile,

Emile

2023

Annalen der Physik

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Generally, the linear motion between the source of a wave and an observer leads to a linear Doppler effect. It is associated with the linear momentum of the wave. For electromagnetic beams having a circular polarization or an azimuthal phase distribution, the rotation between the source and the observer results in a less well‐known rotational Doppler effect. It is associated with the angular momentum of the wave. This is particularly the case for vortex beams. Here, the various physical insights that are given to explain the origin of the rotational Doppler effect is reviewed. The focus is on different cases where such an effect gives information on the rotational nature of the probed systems, and also on cases where the rotational Doppler effect is useless. Still debated issues and possible applications are then presented.

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Section: Diffusion On a Rotating Surfacementioning

confidence: 99%

Rotational Doppler Effect: A Review

Emile,

Emile

2023

Annalen der Physik

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Remote Vector Velocimetry with Fiber‐Delivered Scalar Fields

Tang,

Wan,

Zhang

et al. 2024

Laser & Photonics Reviews

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The Doppler effect reveals the law that light waves undergo frequency changes in interacting with motion, which is highly significant in velocity detection and has applications in fields such as astrophysics, aerospace, and advanced manufacturing. A typical Doppler velocimetry involves illuminating a moving object with interference fringes generated based on phase gradients while detecting the frequency shift of scattered light to determine the velocity. Beyond the spatial phase distributions, the spatial amplitude is a unique dimension of light fields that can be directly controlled, but its application prospects in motion detection are rarely revealed, particularly in both the magnitude and orientation of velocity measurements. In this work, a remote vector velocimeter based on spatially structured amplitude fields is proposed for monitoring angular velocities of objects in situ. Guided through a 40 km seven‐core fiber, the structured beams with spatially‐distributed amplitude are constructed at the remote fiber facet by adjustable mode excitation in outer cores, and the Doppler signals reflected by the target are collected and transmitted back by the inner core, enabling the remote measurement of rotational motion vectors with a probe‐signal‐integrated configuration. These results suggest the great potential of spatial amplitude fields in motion detection, the cost‐efficient and compact velocimetry may contribute to the communities of optical sensing and engineering.

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Air vortex detection using the rotational Doppler effect

Emile,

Rochefort,

Le Stradic

et al. 2024

Appl. Opt.

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A vortex generated by an air depression in a tube is investigated optically using the rotational Doppler effect. A superposition of Laguerre Gaussian beams with opposite topological charges probes the turbulence along its axis. The scattered light is frequency shifted depending on the charge and is detected and analyzed with a spectrum analyzer. A complete transversal mapping of the turbulence is performed, showing fluid rotation of the order of a few Hertz. Applications to wake turbulences in aircraft safety are then considered.

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Angular velocimetry for fluid flows: an optical sensor using structured light and machine learning

Cited by 6 publications

References 25 publications

Rotational Doppler Effect: A Review

Rotational Doppler Effect: A Review

Remote Vector Velocimetry with Fiber‐Delivered Scalar Fields

Air vortex detection using the rotational Doppler effect

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