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Main Authors: Kalita, Armin, Oller, Bryan, Paula, Thomas, Bußmann, Alexander, Marte, Sebastian, Blaj, Gabriel, Sierra, Raymond G., Mous, Sandra, Larsen, Kirk A., Cheng, Xinxin, Hayes, Matt J., Banta, Kelsey, Lisova, Stella, Nguyen, Peter, Guillet, Serge A. H., Thanasekaran, Divya, Nelson, Silke, Liang, Mengning, Adami, Stefan, Adams, Nikolaus A., Stan, Claudiu A.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.23145
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author Kalita, Armin
Oller, Bryan
Paula, Thomas
Bußmann, Alexander
Marte, Sebastian
Blaj, Gabriel
Sierra, Raymond G.
Mous, Sandra
Larsen, Kirk A.
Cheng, Xinxin
Hayes, Matt J.
Banta, Kelsey
Lisova, Stella
Nguyen, Peter
Guillet, Serge A. H.
Thanasekaran, Divya
Nelson, Silke
Liang, Mengning
Adami, Stefan
Adams, Nikolaus A.
Stan, Claudiu A.
author_facet Kalita, Armin
Oller, Bryan
Paula, Thomas
Bußmann, Alexander
Marte, Sebastian
Blaj, Gabriel
Sierra, Raymond G.
Mous, Sandra
Larsen, Kirk A.
Cheng, Xinxin
Hayes, Matt J.
Banta, Kelsey
Lisova, Stella
Nguyen, Peter
Guillet, Serge A. H.
Thanasekaran, Divya
Nelson, Silke
Liang, Mengning
Adami, Stefan
Adams, Nikolaus A.
Stan, Claudiu A.
contents Optical images of transparent three-dimensional objects can be different from a replica of the object's cross section in the image plane due to refraction at the surface or in the body of the object. Simulations of the object's image are thus needed for the visualization and validation of physical models. We report ray-tracing image simulations that achieved high physical fidelity, reproducing optical behaviors and image features not rendered in previous studies. We replicated brightfield microscopy images of drops with complex shapes and images of pressure and shock waves traveling inside them. For high physical fidelity, the simulations must replicate the spatial and angular distribution of illumination rays, and both the experiment and the simulation must be designed for accurate optical modeling. The simulations are highly sensitive to the properties of the drops and can be used to diagnose and refine fluid dynamics models. The simulated images can also be optimized to extract multiple 3D properties from experimental images. Compared to specialized single-shot 3D imaging methods, this approach has the advantage that it preserves the experimental simplicity, the high resolution, and the visual interpretability characteristic to basic optical imaging. The techniques introduced here are directly applicable to optical microscopy, so they can be used in other fields, such as microfluidics and biology, to expand the type and the accuracy of three-dimensional information that can be extracted from basic optical images.
format Preprint
id arxiv_https___arxiv_org_abs_2507_23145
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Ray-tracing image simulations of transparent objects with complex shape and inhomogeneous refractive index
Kalita, Armin
Oller, Bryan
Paula, Thomas
Bußmann, Alexander
Marte, Sebastian
Blaj, Gabriel
Sierra, Raymond G.
Mous, Sandra
Larsen, Kirk A.
Cheng, Xinxin
Hayes, Matt J.
Banta, Kelsey
Lisova, Stella
Nguyen, Peter
Guillet, Serge A. H.
Thanasekaran, Divya
Nelson, Silke
Liang, Mengning
Adami, Stefan
Adams, Nikolaus A.
Stan, Claudiu A.
Optics
Optical images of transparent three-dimensional objects can be different from a replica of the object's cross section in the image plane due to refraction at the surface or in the body of the object. Simulations of the object's image are thus needed for the visualization and validation of physical models. We report ray-tracing image simulations that achieved high physical fidelity, reproducing optical behaviors and image features not rendered in previous studies. We replicated brightfield microscopy images of drops with complex shapes and images of pressure and shock waves traveling inside them. For high physical fidelity, the simulations must replicate the spatial and angular distribution of illumination rays, and both the experiment and the simulation must be designed for accurate optical modeling. The simulations are highly sensitive to the properties of the drops and can be used to diagnose and refine fluid dynamics models. The simulated images can also be optimized to extract multiple 3D properties from experimental images. Compared to specialized single-shot 3D imaging methods, this approach has the advantage that it preserves the experimental simplicity, the high resolution, and the visual interpretability characteristic to basic optical imaging. The techniques introduced here are directly applicable to optical microscopy, so they can be used in other fields, such as microfluidics and biology, to expand the type and the accuracy of three-dimensional information that can be extracted from basic optical images.
title Ray-tracing image simulations of transparent objects with complex shape and inhomogeneous refractive index
topic Optics
url https://arxiv.org/abs/2507.23145