A Generalized Ray Formulation For Wave-Optics Rendering

TL;DR

This paper introduces a generalized wave-based ray formulation that extends classical ray optics to accurately model and render complex wave-optical light transport phenomena, enabling interactive and large-scale simulations.

Contribution

It presents a rigorous, general formalism for wave-optical rays derived from photodetection states, allowing advanced path tracing in wave optics with improved accuracy and performance.

Findings

Enables wave-optical rendering of complex scenes

Supports light of any coherence and spectral properties

Achieves interactive wave-optical light transport

Abstract

Under ray-optical light transport, the classical ray serves as a linear and local "point query" of light's behaviour. Linearity and locality are crucial to the formulation of sophisticated path tracing and sampling techniques, that enable efficient solutions to light transport problems in complex, real-world settings and environments. However, such formulations are firmly confined to the realm of ray optics, while many applications of interest -- in computer graphics and computational optics -- demand a more precise understanding of light: as waves. We rigorously formulate the generalized ray, which enables linear and weakly-local queries of arbitrary wave-optical distributions of light. Generalized rays arise from photodetection states, and therefore allow performing backward (sensor-to-source) wave-optical light transport. Our formulations are accurate and highly general: they facilitate the application of modern path tracing techniques for wave-optical rendering, with light of any state of coherence and any spectral properties. We improve upon the state-of-the-art in terms of the generality and accuracy of the formalism, ease of application, as well as performance. As a consequence, we are able to render large, complex scenes, as in Fig. 1, and even do interactive wave-optical light transport, none of which is possible with any existing method. We numerically validate our formalism, and make connection to partially-coherent light transport.