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Autori principali: Li, Xiaofan, Wu, Chenming, Sun, Yanpeng, Zhou, Jiaming, Qu, Delin, Qu, Yansong, Bo, Weihao, Yu, Haibao, Liang, Dingkang
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.18838
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author Li, Xiaofan
Wu, Chenming
Sun, Yanpeng
Zhou, Jiaming
Qu, Delin
Qu, Yansong
Bo, Weihao
Yu, Haibao
Liang, Dingkang
author_facet Li, Xiaofan
Wu, Chenming
Sun, Yanpeng
Zhou, Jiaming
Qu, Delin
Qu, Yansong
Bo, Weihao
Yu, Haibao
Liang, Dingkang
contents Visual autoregressive models achieve remarkable generation quality through next-scale predictions across multi-scale token pyramids. However, the conventional method uses uniform scale downsampling to build these pyramids, leading to aliasing artifacts that compromise fine details and introduce unwanted jaggies and moiré patterns. To tackle this issue, we present \textbf{FVAR}, which reframes the paradigm from \emph{next-scale prediction} to \emph{next-focus prediction}, mimicking the natural process of camera focusing from blur to clarity. Our approach introduces three key innovations: \textbf{1) Next-Focus Prediction Paradigm} that transforms multi-scale autoregression by progressively reducing blur rather than simply downsampling; \textbf{2) Progressive Refocusing Pyramid Construction} that uses physics-consistent defocus kernels to build clean, alias-free multi-scale representations; and \textbf{3) High-Frequency Residual Learning} that employs a specialized residual teacher network to effectively incorporate alias information during training while maintaining deployment simplicity. Specifically, we construct optical low-pass views using defocus point spread function (PSF) kernels with decreasing radius, creating smooth blur-to-clarity transitions that eliminate aliasing at its source. To further enhance detail generation, we introduce a High-Frequency Residual Teacher that learns from both clean structure and alias residuals, distilling this knowledge to a vanilla VAR deployment network for seamless inference. Extensive experiments on ImageNet demonstrate that FVAR substantially reduces aliasing artifacts, improves fine detail preservation, and enhances text readability, achieving superior performance with perfect compatibility to existing VAR frameworks.
format Preprint
id arxiv_https___arxiv_org_abs_2511_18838
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle FVAR: Visual Autoregressive Modeling via Next Focus Prediction
Li, Xiaofan
Wu, Chenming
Sun, Yanpeng
Zhou, Jiaming
Qu, Delin
Qu, Yansong
Bo, Weihao
Yu, Haibao
Liang, Dingkang
Computer Vision and Pattern Recognition
Visual autoregressive models achieve remarkable generation quality through next-scale predictions across multi-scale token pyramids. However, the conventional method uses uniform scale downsampling to build these pyramids, leading to aliasing artifacts that compromise fine details and introduce unwanted jaggies and moiré patterns. To tackle this issue, we present \textbf{FVAR}, which reframes the paradigm from \emph{next-scale prediction} to \emph{next-focus prediction}, mimicking the natural process of camera focusing from blur to clarity. Our approach introduces three key innovations: \textbf{1) Next-Focus Prediction Paradigm} that transforms multi-scale autoregression by progressively reducing blur rather than simply downsampling; \textbf{2) Progressive Refocusing Pyramid Construction} that uses physics-consistent defocus kernels to build clean, alias-free multi-scale representations; and \textbf{3) High-Frequency Residual Learning} that employs a specialized residual teacher network to effectively incorporate alias information during training while maintaining deployment simplicity. Specifically, we construct optical low-pass views using defocus point spread function (PSF) kernels with decreasing radius, creating smooth blur-to-clarity transitions that eliminate aliasing at its source. To further enhance detail generation, we introduce a High-Frequency Residual Teacher that learns from both clean structure and alias residuals, distilling this knowledge to a vanilla VAR deployment network for seamless inference. Extensive experiments on ImageNet demonstrate that FVAR substantially reduces aliasing artifacts, improves fine detail preservation, and enhances text readability, achieving superior performance with perfect compatibility to existing VAR frameworks.
title FVAR: Visual Autoregressive Modeling via Next Focus Prediction
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2511.18838