Holographic Radiance Cascades for 2D Global Illumination

TL;DR

Holographic Radiance Cascades is a novel 2D global illumination algorithm that achieves real-time, high-quality results using a multi-level radiance probe system and short ray intervals, outperforming traditional methods.

Contribution

The paper introduces a single-shot, scene-agnostic radiance transfer method for 2D global illumination that runs in real-time with high visual fidelity.

Findings

Achieves visually indistinguishable results from reference solutions.

Runs at 1.85ms for 512x512 images on an RTX 3080.

Operates at 7.67ms for 1024x1024 images, demonstrating real-time performance.

Abstract

Efficiently calculating global illumination has always been one of the greatest challenges in computer graphics. Algorithms for approximating global illumination have always struggled to run in realtime for fully dynamic scenes, and have had to rely heavily on stochastic raytracing, spatialtemporal denoising, or undersampled representations, resulting in much lower quality of lighting compared to reference solutions. Even though the problem of calculating global illumination in 2D is significantly simpler than that of 3D, most contemporary approaches still struggle to accurately approximate 2D global illumination under realtime constraints. We present Holographic Radiance Cascades: a new single-shot scene-agnostic radiance transfer algorithm for global illumination, which is capable of achieving results visually indistinguishable from the 2D reference solution at realtime framerates. Our method uses a multi-level radiance probe system, and computes rays via combining short ray intervals as a replacement for conventional raytracing. It runs at constant cost for a given scene size, taking 1.85ms for a 512x512 pixel image and 7.67ms for 1024x1024 on an RTX 3080 Laptop.