Position-free Multiple-bounce Computations for Smith Microfacet BSDFs
Abstract
Bidirectional Scattering Distribution Functions (BSDFs) encode how a material reflects or transmits the incoming light. The most commonly used model is the Microfacet BSDF. It computes material response from the micro-geometry of the surface assuming a single bounce on specular microfacets. The original model ignores multiple bounces on the micro-geometry, resulting in energy loss, especially with large roughness. In this paper, we present a position-free formulation of multiple bounces inside the micro-geometry, which eliminates this energy loss. We use an explicit mathematical definition of path space that describes single and multiple bounces in a uniform way. We then study the behavior of light on the different vertices and segments in path space, leading to an accurate and reciprocal multiple-bounce description of BSDFs. We also present practical, unbiased Monte-Carlo estimators to compute multiple scattering. Our method is less noisy than existing algorithms for computing multiple scattering. It is almost noise-free with a very-low sampling rate, from 2 to 4 samples per pixel.
Cite
@article{arxiv.2109.14398,
title = {Position-free Multiple-bounce Computations for Smith Microfacet BSDFs},
author = {Beibei Wang and Wenhua Jin and Jiahui Fan and Jian Yang and Nicolas Holzschuch and Ling-Qi Yan},
journal= {arXiv preprint arXiv:2109.14398},
year = {2021}
}