Ray-Based Reflectance Model for Diffraction

We present a novel method of simulating wave effects in graphics using ray--based renderers with a new function: the Wave BSDF (Bidirectional Scattering Distribution Function). Reflections from neighboring surface patches represented by local BSDFs are mutually independent. However, in many surfaces with wavelength-scale microstructures, interference and diffraction requires a joint analysis of reflected wavefronts from neighboring patches. We demonstrate a simple method to compute the BSDF for the entire microstructure, which can be used independently for each patch. This allows us to use traditional ray--based rendering pipelines to synthesize wave effects of light and sound. We exploit the Wigner Distribution Function (WDF) to create transmissive, reflective, and emissive BSDFs for various diffraction phenomena in a physically accurate way. In contrast to previous methods for computing interference, we circumvent the need to explicitly keep track of the phase of the wave by using BSDFs that include positive as well as negative coefficients. We describe and compare the theory in relation to well understood concepts in rendering and demonstrate a straightforward implementation. In conjunction with standard raytracers, such as PBRT, we demonstrate wave effects for a range of scenarios such as multi--bounce diffraction materials, holograms and reflection of high frequency surfaces.

[1]  Yinlong Sun,et al.  Rendering biological iridescences with RGB-based renderers , 2006, TOGS.

[2]  M. Levoy,et al.  Wigner distributions and how they relate to the light field , 2009, 2009 IEEE International Conference on Computational Photography (ICCP).

[3]  Marcus A. Magnor,et al.  A Bidirectional Light Field ‐ Hologram Transform , 2007, Comput. Graph. Forum.

[4]  M. Alonso,et al.  Wigner functions for nonparaxial, arbitrarily polarized electromagnetic wave fields in free space. , 2004, Journal of the Optical Society of America. A, Optics, image science, and vision.

[5]  J. Goodman Introduction to Fourier optics , 1969 .

[6]  Frédo Durand,et al.  Implicit visibility and antiradiance for interactive global illumination , 2007, ACM Trans. Graph..

[7]  Turner Whitted,et al.  An improved illumination model for shaded display , 1979, CACM.

[8]  Henrik Wann Jensen,et al.  Global Illumination using Photon Maps , 1996, Rendering Techniques.

[9]  G. Groot Gregory,et al.  Edge diffraction in Monte Carlo ray tracing , 1999, Optics + Photonics.

[10]  S. Chandler-Wilde,et al.  EFFICIENCY OF SINGLE NOISE BARRIERS , 1991 .

[11]  Thomas A. Funkhouser,et al.  Modeling acoustics in virtual environments using the uniform theory of diffraction , 2001, SIGGRAPH.

[12]  R. Kouyoumjian,et al.  A uniform geometrical theory of diffraction for an edge in a perfectly conducting surface , 1974 .

[13]  E. Wolf Coherence and radiometry , 1978 .

[14]  Hans P. Moravec 3D graphics and the wave theory , 1981, SIGGRAPH '81.

[15]  Per H. Christensen,et al.  Efficient simulation of light transport in scenes with participating media using photon maps , 1998, SIGGRAPH.

[16]  Gregory J. Ward,et al.  Measuring and modeling anisotropic reflection , 1992, SIGGRAPH.

[17]  Greg Humphreys,et al.  Physically Based Rendering: From Theory to Implementation , 2004 .

[18]  A. Walther Radiometry and coherence , 1968 .

[19]  N. Tsingos A Geometrical Approach to Modeling Reflectance Functions of Diffracting Surfaces , 2000 .

[20]  J. Goodman Statistical Properties of Laser Speckle Patterns , 1963 .

[21]  Mj Martin Bastiaans A Frequency-domain Treatment of Partial Coherence , 1977 .

[22]  Markus H. Gross,et al.  Lighting and Occlusion in a Wave‐Based Framework , 2008, Comput. Graph. Forum.

[23]  Ramesh Raskar,et al.  Augmenting Light Field to model Wave Optics effects , 2009, ArXiv.

[24]  James T. Kajiya,et al.  The rendering equation , 1998 .

[25]  Jos Stam,et al.  Diffraction shaders , 1999, SIGGRAPH.

[26]  Michael Halle,et al.  Computed holograms and holographic video display of 3D data , 2005, SIGGRAPH Courses.

[27]  Michael J. Wozny,et al.  Polarization and birefringency considerations in rendering , 1994, SIGGRAPH.

[28]  Dinesh Manocha,et al.  AD-Frustum: Adaptive Frustum Tracing for Interactive Sound Propagation , 2008, IEEE Transactions on Visualization and Computer Graphics.

[29]  Emmanuel Agu,et al.  Physically-Based Real-Time Diffraction Using Spherical Harmonics , 2006, ISVC.

[30]  R. Mathar,et al.  Fast Edge-Diffraction-Based Radio Wave Propagation Model for Graphics Hardware , 2007, 2007 2nd International ITG Conference on Antennas.

[31]  Mark S. Drew,et al.  Rendering Iridescent Colors of Optical Disks , 2000, Rendering Techniques.

[32]  James T. Kajiya,et al.  The rendering equation , 1986, SIGGRAPH.

[33]  Mj Martin Bastiaans Wigner distribution in optics , 2009 .

[34]  Mj Martin Bastiaans Application of the Wigner distribution function in optics , 1997 .

[35]  Ramesh Raskar,et al.  Rendering Wave Effects with Augmented Light Field , 2010, Comput. Graph. Forum.

[36]  Brian G. Hoover,et al.  Coherence Solution for Bidirectional Reflectance of Surfaces with Wavelength-Scale Statistics (Postprint) , 2006 .

[37]  M. Kleiner,et al.  Computation of edge diffraction for more accurate room acoustics auralization. , 2001, The Journal of the Acoustical Society of America.