Jiří Vorba scite author profile

Our Our Our BDPT Our -2 TP Our -5 TP Our -30 TP L1 error (abs. difference) Time [minutes]Bidirectional path tracing (BDPT) Our guided BDPT Figure 1: We render a scene featuring difficult visibility with bidirectional path tracing (BDPT) guided by our parametric distributions learned on-line in a number of training passes (TP). The insets show equal-time (1h) comparisons of images obtained with different numbers of training passes. The results reveal that the time spent on additional training passes is quickly amortized by the superior performance of the subsequent guided rendering. AbstractMonte Carlo techniques for light transport simulation rely on importance sampling when constructing light transport paths. Previous work has shown that suitable sampling distributions can be recovered from particles distributed in the scene prior to rendering. We propose to represent the distributions by a parametric mixture model trained in an on-line (i.e. progressive) manner from a potentially infinite stream of particles. This enables recovering good sampling distributions in scenes with complex lighting, where the necessary number of particles may exceed available memory. Using these distributions for sampling scattering directions and light emission significantly improves the performance of state-of-the-art light transport simulation algorithms when dealing with complex lighting.

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Product Importance Sampling for Light Transport Path Guiding

Herholz

Elek

Vorba

et al. 2016

Computer Graphics Forum

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Path guiding in production

Vorba¹,

Hanika²,

Herholz

et al. 2019

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Adjoint-driven Russian roulette and splitting in light transport simulation

Vorba

Křivánek

2016

ACM Trans. Graph.

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While Russian roulette (RR) and splitting are considered fundamental importance sampling techniques in neutron transport simulations, they have so far received relatively little attention in light transport. In computer graphics, RR and splitting are most often based solely on local reflectance properties. However, this strategy can be far from optimal in common scenes with non-uniform light distribution as it does not accurately predict the actual path contribution. In our approach, like in neutron transport, we estimate the expected contribution of a path as the product of the path weight and a pre-computed estimate of the adjoint transport solution. We use this estimate to generate so-called weight window which keeps the path contribution roughly constant through RR and splitting. As a result, paths in unimportant regions tend to be terminated early while in the more important regions they are spawned by splitting. This results in substantial variance reduction in both path tracing and photon tracing-based simulations. Furthermore, unlike the standard computer graphics RR, our approach does not interfere with importance-driven sampling of scattering directions, which results in superior convergence when such a technique is combined with our approach. We provide a justification of this behavior by relating our approach to the zero-variance random walk theory.

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A Spatial Target Function for Metropolis Photon Tracing

et al. 2016

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International audienceThe human visual system is sensitive to relative differences in luminance, but light transport simulation algorithms based on Metropolis sampling often result in a highly nonuniform relative error distribution over the rendered image. Although this issue has previously been addressed in the context of the Metropolis light transport algorithm, our work focuses on Metropolis photon tracing. We present a new target function (TF) for Metropolis photon tracing that ensures good stratification of photons leading to pixel estimates with equalized relative error. We develop a hierarchical scheme for progressive construction of the TF from paths sampled during rendering. In addition to the approach taken in previous work, where the TF is defined in the image plane, ours can be associated with compact spatial regions. This allows us to take advantage of illumination coherence to more robustly estimate the TF while adapting to geometry discontinuities. To sample from this TF, we design a new replica exchange Metropolis scheme. We apply our algorithm in progressive photon mapping and show that it often outperforms alternative approaches in terms of image quality by a large margin

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A Spatial Target Function for Metropolis Photon Tracing

et al. 2017

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The human visual system is sensitive to relative differences in luminance, but light transport simulation algorithms based on Metropolis sampling often result in a highly nonuniform relative error distribution over the rendered image. Although this issue has previously been addressed in the context of the Metropolis light transport algorithm, our work focuses on Metropolis photon tracing. We present a new target function (TF) for Metropolis photon tracing that ensures good stratification of photons leading to pixel estimates with equalized relative error. We develop a hierarchical scheme for progressive construction of the TF from paths sampled during rendering. In addition to the approach taken in previous work, where the TF is defined in the image plane, ours can be associated with compact spatial regions. This allows us to take advantage of illumination coherence to more robustly estimate the TF while adapting to geometry discontinuities. To sample from this TF, we design a new replica exchange Metropolis scheme. We apply our algorithm in progressive photon mapping and show that it often outperforms alternative approaches in terms of image quality by a large margin.

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Path tracing in Production: The Path of Water

Droske¹,

Hanika

Vorba³

et al. 2023

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Advances in Monte Carlo rendering

Keller

Grittmann

Vorba³

et al. 2020

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Jiří Vorba

On-line learning of parametric mixture models for light transport simulation

Product Importance Sampling for Light Transport Path Guiding

Path guiding in production

Adjoint-driven Russian roulette and splitting in light transport simulation

A Spatial Target Function for Metropolis Photon Tracing

A Spatial Target Function for Metropolis Photon Tracing

Path tracing in Production: The Path of Water

Advances in Monte Carlo rendering

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