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dc.contributor.authorFalster, Viggoen_US
dc.contributor.authorJarabo, Adriánen_US
dc.contributor.authorFrisvad, Jeppe Revallen_US
dc.contributor.editorEisemann, Elmar and Jacobson, Alec and Zhang, Fang-Lueen_US
dc.date.accessioned2020-10-29T18:50:45Z
dc.date.available2020-10-29T18:50:45Z
dc.date.issued2020
dc.identifier.issn1467-8659
dc.identifier.urihttps://doi.org/10.1111/cgf.14140
dc.identifier.urihttps://diglib.eg.org:443/handle/10.1111/cgf14140
dc.description.abstractMost models for bidirectional surface scattering by arbitrary explicitly defined microgeometry are either based on geometric optics and include multiple scattering but no diffraction effects or based on wave optics and include diffraction but no multiple scattering effects. The few exceptions to this tendency are based on rigorous solution of Maxwell's equations and are computationally intractable for surface microgeometries that are tens or hundreds of microns wide. We set up a measurement equation for combining results from single scattering scalar diffraction theory with multiple scattering geometric optics using Monte Carlo integration. Since we consider an arbitrary surface microgeometry, our method enables us to compute expected bidirectional scattering of the metasurfaces with increasingly smaller details seen more and more often in production. In addition, we can take a measured microstructure as input and, for example, compute the difference in bidirectional scattering between a desired surface and a produced surface. In effect, our model can account for both diffraction colors due to wavelength-sized features in the microgeometry and brightening due to multiple scattering. We include scalar diffraction for refraction, and we verify that our model is reasonable by comparing with the rigorous solution for a microsurface with half ellipsoids.en_US
dc.publisherThe Eurographics Association and John Wiley & Sons Ltd.en_US
dc.subjectComputing methodologies
dc.subjectReflectance modeling
dc.titleComputing the Bidirectional Scattering of a Microstructure Using Scalar Diffraction Theory and Path Tracingen_US
dc.description.seriesinformationComputer Graphics Forum
dc.description.sectionheadersMaterials and Shading Models
dc.description.volume39
dc.description.number7
dc.identifier.doi10.1111/cgf.14140
dc.identifier.pages231-242


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  • 39-Issue 7
    Pacific Graphics 2020 - Symposium Proceedings

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