Snapshot 3D reconstruction of liquid surfaces

Roth, Adrian; Kristensson, Elias; Berrocal, Edouard

doi:10.1364/oe.392325

Cited by 14 publications

(4 citation statements)

References 36 publications

(55 reference statements)

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“…Here, A is the background light intensity in the image, B is the amplitude of the fringes, epsilon is noise and finally φ is the phase of the fringes. In this imaged fringe pattern, all interesting information of the third dimension is found in the phase φ and to extract it a phase demodulation of the image performed, see [12] for more information on this. With the estimated phase, the third dimension, depth d(x, y), can be estimated for the surface with the following equation,…”

Section: D Reconstruction With Fp-lif and Experimental Setupmentioning

confidence: 99%

“…The scale s of how many pixels there are per meter and finally the principal image point [x 0 , y 0 ] of the camera. This is the general approach for the 3D reconstruction using FP-LIF, for more in depth information see [12]. The FP-LIF requires the use of fluorescing liquid.…”

Section: D Reconstruction With Fp-lif and Experimental Setupmentioning

confidence: 99%

“…High-speed 3D imaging of liquid breakups in sprays, showing detailed temporal surface deformation with a fairly good spatial resolution and by means of a single camera remains a challenge. With this goal in mind, we have recently developed a technique called Fringe Projection -Laser Induced Fluorescence (FP-LIF) [12]. FP-LIF is based on the Fringe Projection concept where a structured laser beam is used to illuminate a liquid structure.…”

Section: Introductionmentioning

confidence: 99%

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High-speed 3D imaging of liquid sheet surfaces using the FP-LIF technique

Roth

Sapík

Jedelský

et al. 2021

ICLASS

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Accurate visualization and understanding of liquid breakups and dynamics of liquid jets, sheets, blobs and ligaments is important for a wide range of spray applications. Here, temporally resolved 3D measurements are necessary to obtain the complete characterization these processes. The currently available 3D imaging techniques are usually based on time-averaged data and do not have the capability of 3D temporally resolving fast liquid breakup phenomena. We have developed a novel technique called Fringe Projection -Laser Induced Fluorescence, FP-LIF, with the possibility of generating snapshot 3D surface reconstructions of irregular liquid structures, such as liquid sheets, ligaments, blobs and other large liquid bodies. The advantage of this technique is that only a single camera is used for generating 3D data. In this article we push the technique one step forward by using a Photron SA-Z high-speed camera to obtain 3D reconstructions of a hollow cone liquid sheet structure at 20 000 frames per second. This liquid sheet is generated from a pressure swirl atomizer. Such new type of data, presented here, are particularly relevant for the validation and improvement of computational spray models and for acquiring detailed insight on the conical sheet development and breakup.

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Section: D Reconstruction With Fp-lif and Experimental Setupmentioning

confidence: 99%

Section: D Reconstruction With Fp-lif and Experimental Setupmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

High-speed 3D imaging of liquid sheet surfaces using the FP-LIF technique

Roth

Sapík

Jedelský

et al. 2021

ICLASS

Self Cite

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“…Ihrke et al (2005) exploited the emission from fluorescent dye dissolved in the fluid imaged from multiple viewpoints for the volumetric reconstruction of a stream of water. More recently, Roth et al (2020) combined laser-induced fluorescence (LIF) (Kinsey 1977) and the projection of a fringe pattern to reconstruct the 3D-surface of a pendent droplet with a single camera setup. Horbach and Dang (2010) used the reflection of a structured light pattern on a specular surface for a 3D reconstruction through a region-growing approach that considers local curvature features.…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional encoding of a gas–liquid interface by means of color-coded glare points

Dreisbach

Blessing

Brunn³

et al. 2023

Exp Fluids

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The present work introduces an extension of the shadowgraphy method by differently colored oblique light sources for the observation of the three-dimensional spatio-temporal dynamics of gas–liquid interfaces. The proposed expanded approach is tested and elaborated with the example of a droplet during impingement. Particularly, it is elaborated in a combined experimental/theoretical approach, how well glare points from differently colored oblique light sources can be used to encode additional 3D information of the droplet shape within a single shadowgraph image. Narrow-banded LEDs with distinct spectra and maxima in the visible light illuminate the droplet from different angles in red, green and blue light, respectively, while a high-speed RGB camera captures the images produced by each light source in the corresponding image channel, therefore creating three unique views of the droplet. In order to compensate for the mutual perturbation of the images resulting from cross-talk between the channels and the polychromatic light of the LEDs, a color correction is introduced, which is based on the transfer function between the light sources and the channels of the RGB camera. In experiments with the proposed measurement setup of a water droplet impinging onto a flat substrate it is successfully demonstrated that three unique and independent grayscale images can be reconstructed with this color correction function. The optimal illumination angles for the lateral light sources are determined experimentally, which lead to consistent glare points on the deforming gas–liquid interface throughout the dynamic process of the drop impact. An ellipsoidal droplet is considered to derive information on orientation and three-dimensional shape of a non-axisymmetrical droplet from the relative positions of the glare points and the shadowgraph contour. Thereby it is successfully demonstrated that the additional three-dimensional information encoded in the glare points can lay the groundwork for the volumetric reconstruction of the deforming gas–liquid interface during the impingement of a droplet.

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Spatial Frequency Multiplexing in Spectroscopy

Kristensson

2024

Coded Optical Imaging

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Snapshot 3D reconstruction of liquid surfaces

Cited by 14 publications

References 36 publications

High-speed 3D imaging of liquid sheet surfaces using the FP-LIF technique

High-speed 3D imaging of liquid sheet surfaces using the FP-LIF technique

Three-dimensional encoding of a gas–liquid interface by means of color-coded glare points

Spatial Frequency Multiplexing in Spectroscopy

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