Warped-Area Reparameterization of Differential Path Integrals

Author(s)

Xu, Peiyu; Bangaru, Sai; Li, Tzu-Mao; Zhao, Shuang

Abstract

Physics-based differentiable rendering is becoming increasingly crucial for tasks in inverse rendering and machine learning pipelines. To address discontinuities caused by geometric boundaries and occlusion, two classes of methods have been proposed: 1) the edge-sampling methods that directly sample light paths at the scene discontinuity boundaries, which require nontrivial data structures and precomputation to select the edges, and 2) the reparameterization methods that avoid discontinuity sampling but are currently limited to hemispherical integrals and unidirectional path tracing. We introduce a new mathematical formulation that enjoys the benefits of both classes of methods. Unlike previous reparameterization work that focused on hemispherical integral, we derive the reparameterization in the path space. As a result, to estimate derivatives using our formulation, we can apply advanced Monte Carlo rendering methods, such as bidirectional path tracing, while avoiding explicit sampling of discontinuity boundaries. We show differentiable rendering and inverse rendering results to demonstrate the effectiveness of our method.

Date issued

2023-12-04

URI

https://hdl.handle.net/1721.1/153279

Department

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory

Journal

ACM Transactions on Graphics

Publisher

ACM

Citation

Xu, Peiyu, Bangaru, Sai, Li, Tzu-Mao and Zhao, Shuang. 2023. "Warped-Area Reparameterization of Differential Path Integrals." ACM Transactions on Graphics, 42 (6).

Version: Final published version

ISSN

0730-0301