BRDF models for accurate and efficient rendering of glossy surfaces

This article presents two new parametric models of the Bidirectional Reflectance Distribution Function (BRDF), one inspired by the Rayleigh-Rice theory for light scattering from optically smooth surfaces, and one inspired by micro-facet theory. The models represent scattering from a wide range of gl...

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Bibliographic Details
Published in:ACM transactions on graphics 2012-01, Vol.31 (1), p.1-14
Main Authors: Löw, Joakim, Kronander, Joel, Ynnerman, Anders, Unger, Jonas
Format: Article
Language:English
Subjects:
BRDF
Distribution functions
global illumination
gloss
Glossy
Importance sampling
Monte Carlo
Rayleigh-Rice
Reflectivity
Rendering
Representations
Scattering
Visual
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Summary:This article presents two new parametric models of the Bidirectional Reflectance Distribution Function (BRDF), one inspired by the Rayleigh-Rice theory for light scattering from optically smooth surfaces, and one inspired by micro-facet theory. The models represent scattering from a wide range of glossy surface types with high accuracy. In particular, they enable representation of types of surface scattering which previous parametric models have had trouble modeling accurately. In a study of the scattering behavior of measured reflectance data, we investigate what key properties are needed for a model to accurately represent scattering from glossy surfaces. We investigate different parametrizations and how well they match the behavior of measured BRDFs. We also examine the scattering curves which are represented in parametric models by different distribution functions. Based on the insights gained from the study, the new models are designed to provide accurate fittings to the measured data. Importance sampling schemes are developed for the new models, enabling direct use in existing production pipelines. In the resulting renderings we show that the visual quality achieved by the models matches that of the measured data.
ISSN:0730-0301
1557-7368
1557-7368
DOI:10.1145/2077341.2077350