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Autori principali: Song, Xiaowei, Zheng, Jv, Yuan, Shiran, Gao, Huan-ang, Zhao, Jingwei, He, Xiang, Gu, Weihao, Zhao, Hao
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2403.19615
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author Song, Xiaowei
Zheng, Jv
Yuan, Shiran
Gao, Huan-ang
Zhao, Jingwei
He, Xiang
Gu, Weihao
Zhao, Hao
author_facet Song, Xiaowei
Zheng, Jv
Yuan, Shiran
Gao, Huan-ang
Zhao, Jingwei
He, Xiang
Gu, Weihao
Zhao, Hao
contents In this paper, we present a Scale-adaptive method for Anti-aliasing Gaussian Splatting (SA-GS). While the state-of-the-art method Mip-Splatting needs modifying the training procedure of Gaussian splatting, our method functions at test-time and is training-free. Specifically, SA-GS can be applied to any pretrained Gaussian splatting field as a plugin to significantly improve the field's anti-alising performance. The core technique is to apply 2D scale-adaptive filters to each Gaussian during test time. As pointed out by Mip-Splatting, observing Gaussians at different frequencies leads to mismatches between the Gaussian scales during training and testing. Mip-Splatting resolves this issue using 3D smoothing and 2D Mip filters, which are unfortunately not aware of testing frequency. In this work, we show that a 2D scale-adaptive filter that is informed of testing frequency can effectively match the Gaussian scale, thus making the Gaussian primitive distribution remain consistent across different testing frequencies. When scale inconsistency is eliminated, sampling rates smaller than the scene frequency result in conventional jaggedness, and we propose to integrate the projected 2D Gaussian within each pixel during testing. This integration is actually a limiting case of super-sampling, which significantly improves anti-aliasing performance over vanilla Gaussian Splatting. Through extensive experiments using various settings and both bounded and unbounded scenes, we show SA-GS performs comparably with or better than Mip-Splatting. Note that super-sampling and integration are only effective when our scale-adaptive filtering is activated. Our codes, data and models are available at https://github.com/zsy1987/SA-GS.
format Preprint
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institution arXiv
publishDate 2024
record_format arxiv
spellingShingle SA-GS: Scale-Adaptive Gaussian Splatting for Training-Free Anti-Aliasing
Song, Xiaowei
Zheng, Jv
Yuan, Shiran
Gao, Huan-ang
Zhao, Jingwei
He, Xiang
Gu, Weihao
Zhao, Hao
Computer Vision and Pattern Recognition
In this paper, we present a Scale-adaptive method for Anti-aliasing Gaussian Splatting (SA-GS). While the state-of-the-art method Mip-Splatting needs modifying the training procedure of Gaussian splatting, our method functions at test-time and is training-free. Specifically, SA-GS can be applied to any pretrained Gaussian splatting field as a plugin to significantly improve the field's anti-alising performance. The core technique is to apply 2D scale-adaptive filters to each Gaussian during test time. As pointed out by Mip-Splatting, observing Gaussians at different frequencies leads to mismatches between the Gaussian scales during training and testing. Mip-Splatting resolves this issue using 3D smoothing and 2D Mip filters, which are unfortunately not aware of testing frequency. In this work, we show that a 2D scale-adaptive filter that is informed of testing frequency can effectively match the Gaussian scale, thus making the Gaussian primitive distribution remain consistent across different testing frequencies. When scale inconsistency is eliminated, sampling rates smaller than the scene frequency result in conventional jaggedness, and we propose to integrate the projected 2D Gaussian within each pixel during testing. This integration is actually a limiting case of super-sampling, which significantly improves anti-aliasing performance over vanilla Gaussian Splatting. Through extensive experiments using various settings and both bounded and unbounded scenes, we show SA-GS performs comparably with or better than Mip-Splatting. Note that super-sampling and integration are only effective when our scale-adaptive filtering is activated. Our codes, data and models are available at https://github.com/zsy1987/SA-GS.
title SA-GS: Scale-Adaptive Gaussian Splatting for Training-Free Anti-Aliasing
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2403.19615