上海市医学图像处理与计算机辅助手术重点实验室

上海市医学图像处理与计算机辅助手术重点实验室

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    • 复旦大学-博学而笃志,切问而近思
    • 复旦大学上海医学院-上海市医学图像处理与计算机辅助手术重点实验室

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    [AAAI'25] MoRe: Class Patch Attention Needs Regularization for Weakly Supervised Semantic Segmentation

    发表时间:2024-12-16

    MoRe: Class Patch Attention Needs Regularization for Weakly Supervised Semantic Segmentation

     

    Zhiwei Yang,  Yucong Meng,  Kexue Fu,  Shuo Wang,  Zhijian Song 

     

    The Association for the Advancement of Artificial Intelligence (AAAI 2025) 


    Abstract

    Weakly Supervised Semantic Segmentation (WSSS) with image-level labels typically uses Class Activation Maps (CAM) to achieve dense predictions. Recently, Vision Transformer (ViT) has provided an alternative to generate localization maps from class-patch attention. However, due to insufficient constraints on modeling such attention, we observe that the Localization Attention Maps (LAM) often struggle with the artifact issue, i.e., patch regions with minimal semantic relevance are falsely activated by class tokens. In this work, we propose MoRe to address this issue and further explore the potential of LAM. Our findings suggest that imposing additional regularization on class-patch attention is necessary. To this end, we first view the attention as a novel directed graph and propose the Graph Category Representation module to implicitly regularize the interaction among class-patch entities. It ensures that class tokens dynamically condense the related patch information and suppress unrelated artifacts at a graph level. Second, motivated by the observation that CAM from classification weights maintains smooth localization of objects, we devise the Localization-informed Regularization module to explicitly regularize the class-patch attention. It directly mines the token relations from CAM and further supervises the consistency between class and patch tokens in a learnable manner. Extensive experiments are conducted on PASCAL VOC and MS COCO, validating that MoRe effectively addresses the artifact issue and achieves state-of-the-art performance, surpassing recent single-stage and even multi-stage methods.