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Autores principales: Shu, Zishan, Wu, Juntong, Yan, Wei, Liu, Xudong, Zhang, Hongyu, Liu, Chang, Mao, Youdong, Chen, Jie
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2601.08602
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author Shu, Zishan
Wu, Juntong
Yan, Wei
Liu, Xudong
Zhang, Hongyu
Liu, Chang
Mao, Youdong
Chen, Jie
author_facet Shu, Zishan
Wu, Juntong
Yan, Wei
Liu, Xudong
Zhang, Hongyu
Liu, Chang
Mao, Youdong
Chen, Jie
contents Vision modeling has advanced rapidly with Transformers, whose attention mechanisms capture visual dependencies but lack a principled account of how semantic information propagates spatially. We revisit this problem from a wave-based perspective: feature maps are treated as spatial signals whose evolution over an internal propagation time (aligned with network depth) is governed by an underdamped wave equation. In this formulation, spatial frequency-from low-frequency global layout to high-frequency edges and textures-is modeled explicitly, and its interaction with propagation time is controlled rather than implicitly fixed. We derive a closed-form, frequency-time decoupled solution and implement it as the Wave Propagation Operator (WPO), a lightweight module that models global interactions in O(N log N) time-far lower than attention. Building on WPO, we propose a family of WaveFormer models as drop-in replacements for standard ViTs and CNNs, achieving competitive accuracy across image classification, object detection, and semantic segmentation, while delivering up to 1.6x higher throughput and 30% fewer FLOPs than attention-based alternatives. Furthermore, our results demonstrate that wave propagation introduces a complementary modeling bias to heat-based methods, effectively capturing both global coherence and high-frequency details essential for rich visual semantics. Codes are available at: https://github.com/ZishanShu/WaveFormer.
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publishDate 2026
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spellingShingle WaveFormer: Frequency-Time Decoupled Vision Modeling with Wave Equation
Shu, Zishan
Wu, Juntong
Yan, Wei
Liu, Xudong
Zhang, Hongyu
Liu, Chang
Mao, Youdong
Chen, Jie
Computer Vision and Pattern Recognition
Artificial Intelligence
Vision modeling has advanced rapidly with Transformers, whose attention mechanisms capture visual dependencies but lack a principled account of how semantic information propagates spatially. We revisit this problem from a wave-based perspective: feature maps are treated as spatial signals whose evolution over an internal propagation time (aligned with network depth) is governed by an underdamped wave equation. In this formulation, spatial frequency-from low-frequency global layout to high-frequency edges and textures-is modeled explicitly, and its interaction with propagation time is controlled rather than implicitly fixed. We derive a closed-form, frequency-time decoupled solution and implement it as the Wave Propagation Operator (WPO), a lightweight module that models global interactions in O(N log N) time-far lower than attention. Building on WPO, we propose a family of WaveFormer models as drop-in replacements for standard ViTs and CNNs, achieving competitive accuracy across image classification, object detection, and semantic segmentation, while delivering up to 1.6x higher throughput and 30% fewer FLOPs than attention-based alternatives. Furthermore, our results demonstrate that wave propagation introduces a complementary modeling bias to heat-based methods, effectively capturing both global coherence and high-frequency details essential for rich visual semantics. Codes are available at: https://github.com/ZishanShu/WaveFormer.
title WaveFormer: Frequency-Time Decoupled Vision Modeling with Wave Equation
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2601.08602