Neural Denoising for Deep-Z Monte Carlo Renderings

Zhang, Xianyao; Röthlin, Gerhard; Zhu, Shilin; Aydin, Tunç Ozan; Salehi, Farnood; Gross, Markus; Papas, Marios

Neural Denoising for Deep-Z Monte Carlo Renderings

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Date

2024

Authors

Zhang, Xianyao
Röthlin, Gerhard
Zhu, Shilin
Aydin, Tunç Ozan
Salehi, Farnood
Gross, Markus
Papas, Marios

Publisher

The Eurographics Association and John Wiley & Sons Ltd.

Abstract

We present a kernel-predicting neural denoising method for path-traced deep-Z images that facilitates their usage in animation and visual effects production. Deep-Z images provide enhanced flexibility during compositing as they contain color, opacity, and other rendered data at multiple depth-resolved bins within each pixel. However, they are subject to noise, and rendering until convergence is prohibitively expensive. The current state of the art in deep-Z denoising yields objectionable artifacts, and current neural denoising methods are incapable of handling the variable number of depth bins in deep-Z images. Our method extends kernel-predicting convolutional neural networks to address the challenges stemming from denoising deep-Z images. We propose a hybrid reconstruction architecture that combines the depth-resolved reconstruction at each bin with the flattened reconstruction at the pixel level. Moreover, we propose depth-aware neighbor indexing of the depth-resolved inputs to the convolution and denoising kernel application operators, which reduces artifacts caused by depth misalignment present in deep-Z images. We evaluate our method on a production-quality deep-Z dataset, demonstrating significant improvements in denoising quality and performance compared to the current state-of-the-art deep-Z denoiser. By addressing the significant challenge of the cost associated with rendering path-traced deep-Z images, we believe that our approach will pave the way for broader adoption of deep-Z workflows in future productions.

CCS Concepts: Computing methodologies->Ray tracing; Image processing

        @article{10.1111:cgf.15050
,
journal = {Computer Graphics Forum},
title = {{Neural Denoising for Deep-Z Monte Carlo Renderings
}},
author = {Zhang, Xianyao and 
Röthlin, Gerhard and 
Zhu, Shilin and 
Aydin, Tunç Ozan and 
Salehi, Farnood and 
Gross, Markus and 
Papas, Marios
},
year = {2024
},
publisher = {The Eurographics Association and John Wiley & Sons Ltd.
},
ISSN = {1467-8659
},
DOI = {10.1111/cgf.15050
}
}