Title :
Practical Noise Reduction for Progressive Stochastic Ray Tracing with Perceptual Control
Author :
Schwenk, K. ; Kuijper, A. ; Behr, J. ; Fellner, Dieter W.
Abstract :
A proposed method reduces noise in stochastic ray tracing for interactive progressive rendering. The method accumulates high-variance light paths in a separate buffer, which is filtered by a high-quality edge-preserving filter. Then, this method adds a combination of the noisy unfiltered samples and the less noisy (but biased) filtered samples to the low-variance samples to form the final image. A novel per-pixel blending operator combines both contributions in a way that respects a user-defined threshold on perceived noise. This method can provide fast, reliable previews, even in the presence of complex features such as specular surfaces and high-frequency textures. At the same time, it´s consistent in that the bias due to filtering vanishes in the limit.
Keywords :
filtering theory; image resolution; interference suppression; ray tracing; rendering (computer graphics); stochastic processes; complex features; final image; high-quality edge-preserving filter; high-variance light paths; interactive progressive rendering; low-variance samples; noisy unfiltered samples; novel per-pixel blending operator; perceptual control; practical noise reduction; progressive stochastic ray tracing; separate buffer; Image edge detection; Interactive systems; Lighting; Noise abatement; Noise level; Noise measurement; Ray tracing; Rendering (computer graphics); Image edge detection; Interactive systems; Lighting; Noise abatement; Noise level; Noise measurement; Ray tracing; Rendering (computer graphics); computer graphics; illumination filtering; noise reduction; progressive rendering; stochastic ray tracing;
Journal_Title :
Computer Graphics and Applications, IEEE
DOI :
10.1109/MCG.2012.30
