Yanning Xu scite author profile

Yanning Xu

5Publications

35Citation Statements Received

103Citation Statements Given

How they've been cited

How they cite others

136

102

Affiliations

Shandong University, Ministry of Education of the People's Republic of China, Shandong University of Science and Technology

Publications

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A Stationary SVBRDF Material Modeling Method Based on Discrete Microsurface

Zhu

Wang

2019

Computer Graphics Forum

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Microfacet theory is commonly used to build reflectance models for surfaces. While traditional microfacet‐based models assume that the distribution of a surface's microstructure is continuous, recent studies indicate that some surfaces with tiny, discrete and stochastic facets exhibit glittering visual effects, while some surfaces with structured features exhibit anisotropic specular reflection. Accordingly, this paper proposes an efficient and stationary method of surface material modeling to process both glittery and non‐glittery surfaces in a consistent way. Our method comprises two steps: in the preprocessing step, we take a fixed‐size sample normal map as input, then organize 4D microfacet trees in position and normal space for arbitrary‐sized surfaces; we also cluster microfacets into 4D K‐lobes via the adaptive k‐means method. In the rendering step, moreover, surface normals can be efficiently evaluated using pre‐clustered microfacets. Our method is able to efficiently render any structured, discrete and continuous micro‐surfaces using a precisely reconstructed surface NDF. Our method is both faster and uses less memory compared to the state‐of‐the‐art glittery surface modeling works.

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Unsupervised Image Reconstruction for Gradient‐Domain Volumetric Rendering

Xu¹,

Sun

Wang³

et al. 2020

Computer Graphics Forum

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Gradient-domain rendering can highly improve the convergence of light transport simulation using the smoothness in image space. These methods generate image gradients and solve an image reconstruction problem with rendered image and the gradient images. Recently, a previous work proposed a gradient-domain volumetric photon density estimation for homogeneous participating media. However, the image reconstruction relies on traditional L1 reconstruction, which leads to obvious artifacts when only a few rendering passes are performed. Deep learning based reconstruction methods have been exploited for surface rendering, but they are not suitable for volume density estimation. In this paper, we propose an unsupervised neural network for image reconstruction of gradient-domain volumetric photon density estimation, more specifically for volumetric photon mapping, using a variant of GradNet with an encoded shift connection and a separated auxiliary feature branch, which includes volume based auxiliary features such as transmittance and photon density. Our network smooths the images on global scale and preserves the high frequency details on a small scale. We demonstrate that our network produces a higher quality result, compared to previous work. Although we only considered volumetric photon mapping, it's straightforward to extend our method for other forms, like beam radiance estimation. CCS Concepts • Computing methodologies → Neural network; Ray tracing; † Joint first author.

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Denoising Stochastic Progressive Photon Mapping Renderings Using a Multi-Residual Network

Zeng

Wang

et al. 2020

J. Comput. Sci. Technol.

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Practical level-of-detail aggregation of fur appearance

et al. 2022

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Fur appearance rendering is crucial for the realism of computer generated imagery, but is also a challenge in computer graphics for many years. Much effort has been made to accurately simulate the multiple-scattered light transport among fur fibers, but the computation cost is still very high, since the number of fur fibers is usually extremely large. In this paper, we aim at reducing the number of fur fibers while preserving realistic fur appearance. We present an aggregated fur appearance model, using one thick cylinder to accurately describe the aggregated optical behavior of a bunch of fur fibers, including the multiple scattering of light among them. Then, to acquire the parameters of our aggregated model, we use a lightweight neural network to map individual fur fiber's optical properties to those in our aggregated model. Finally, we come up with a practical heuristic that guides the simplification process of fur dynamically at different bounces of the light, leading to a practical level-of-detail rendering scheme. Our method achieves nearly the same results as the ground truth, but performs 3.8×-13.5× faster.

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A survey of photon mapping state-of-the-art research and future challenges

Kang

Meng

2016

Frontiers Inf Technol Electronic Eng

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Yanning Xu

A Stationary SVBRDF Material Modeling Method Based on Discrete Microsurface

Unsupervised Image Reconstruction for Gradient‐Domain Volumetric Rendering

Denoising Stochastic Progressive Photon Mapping Renderings Using a Multi-Residual Network

Practical level-of-detail aggregation of fur appearance

A survey of photon mapping state-of-the-art research and future challenges

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