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Xavier Granier - Wolfgang Heidrich IMAGER / University of British Columbia. A Simple Layered RGB BRDF Model. Motivations. Increase the range of possible effects For graphic content creation Work in Color Space RBG - XYZ - LMS Currently limited to linear reflection
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Xavier Granier - Wolfgang Heidrich IMAGER/University of British Columbia A Simple LayeredRGB BRDF Model
Motivations • Increase the range of possible effects • For graphic content creation • Work in Color Space RBG - XYZ - LMS • Currently limited to linear reflection • Convincing and simple model • Not a full simulation • Effect as realistic as possible
Motivations • Wavelength effects • Interference • Colour dispersion • Investigation • Framework
Overview • Previous Work • General Configuration • Glossy Case • Diffuse Case • Results • Conclusion
Overview • Previous Work • General Configuration • Glossy Case • Diffuse Case • Results • Conclusion
Uniform BRDF • Phong models [Phong75,Lafortune94-97,…] • Most commonly used • Simplified models [Ward92,Schlick94,…] • Faster / Better for Global illumination • Micro-facet [Torrance67,Ashikhmin00,…] • Physically based [He91,Hanrahan93,…] • No wavelength dependent effects
Wavelength effects • Diffraction [Stam99,Sun00,…] • Interferences • Recursive Ray-Tracing [Hirayama00-01,…] • Full model [Icart99-00,…] • Fine Spectral representation • RGB based BRDF • Interferences + Colour dispersion
Overview • Previous Work • General Configuration • Glossy Case • Diffuse Case • Results • Conclusion
Approach • Semi-transparent layer • Interferences effects • Local prism configuration • One refraction index by colour component • Non-parallel layer interfaces • Colour dispersion • RGB colour space • Commonly used in image production
Layer configuration 0 Air 1 Layer 2 Support
Resulting energy from interferences Parallel layers Uncorrelated layers Interference : Phase Change
BRDF general expression • k{r,g,b} • R (reflected BRDF) • 3 (RGB) lobe-like models • T (transmitted BRDF) • 3 (RGB) lobe-like models • Ex: using Phong models
Overview • Previous Work • General Configuration • Glossy Case • Diffuse Case • Results • Conclusion
Reflected part • Phong
Transmitted part • Assumption • No absorption • Only one reflection Transmitted term
Main Parameters • Normally r0(k)1 (air/vacuum) • Local geometric configuration : layer-normal • Material properties : exponents - indices • Fully determined by 4-12 parameters • 2-6 Exponents (control transition smoothness) • 1-3 RGB refraction indices (rB rG rR) • 1 Layer size • 0-2 Normal variation (colour dispersion)
Overview • Previous Work • General Configuration • Glossy Case • Diffuse Case • Results • Conclusion
Diffuse case Average along direction Similar expression Assumptions No colour dispersion Rd average reflected energy
Phase change for orthogonal incidence No absorption at the interface Diffuse component • Final expression
Overview • Previous Work • General Configuration • Glossy Case • Diffuse Case • Results • Conclusion
Diffuse component 67 - 73 nm 1 - 30 nm 1 - 210 nm
Layer Size Change Constant normal deviation 148-200 nm 1-30 nm 79-106 nm
Constant deviation Parallel Interfaces Constant deviation
Size / Normal correlation 1-90 nm 1-10 nm rR = 1.5 rG = 1.7 rB = 1.8
Overview • Previous Work • General Configuration • Glossy Case • Diffuse Case • Results • Conclusion
Conclusion • RGB Model • Interferences and colour dispersion • Continuous along direction • Two models • Phong - like for specularity • Diffuse • Validation • Such effects are possible in colour space
Future Work • With current model • Hardware acceleration (shader) • Try to fit some measured BRDF • Investigate other • Increase accuracy / More physical • Investigate colour spaces • Keep simplicity • Multi-layer
Acknowledgements • IMAGER/ University of British Columbia • Post-doctoral position • PIMS Post-doctoral Fellowship • Wolfgang Heidrich & Lionel Bastard • Useful comments and support
Fresnel term (Schlick approximation) Reflected part • Phong reflection