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SSVIF: Self-Supervised Segmentation-Oriented Visible and Infrared Image Fusion.

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    This study introduces a self-supervised framework for visible and infrared image fusion (VIF) that enhances segmentation tasks. The new method achieves strong performance without requiring labeled data, outperforming traditional VIF approaches.

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    Area of Science:

    • Computer Vision
    • Image Processing
    • Machine Learning

    Background:

    • Visible and infrared image fusion (VIF) is crucial for tasks like scene segmentation and object detection.
    • Traditional VIF methods focus on fused image quality, while application-oriented methods optimize downstream task performance.
    • Application-oriented VIF methods typically require labor-intensive, labeled datasets for training.

    Purpose of the Study:

    • To develop a self-supervised training framework for segmentation-oriented VIF (SSVIF) that eliminates the need for labeled downstream task data.
    • To enable VIF models to learn high-level semantic features without segmentation labels.

    Main Methods:

    • Proposed a self-supervised training framework (SSVIF) for segmentation-oriented VIF.
    • Introduced a novel self-supervised task: cross-segmentation consistency, leveraging feature-level and pixel-level fusion segmentation consistency.
    • Designed a two-stage training strategy and dynamic weight adjustment for effective joint learning.

    Main Results:

    • Extensive experiments on public datasets validated the effectiveness of the SSVIF framework.
    • SSVIF, trained on unlabeled data, outperformed traditional VIF methods.
    • SSVIF achieved performance comparable to supervised segmentation-oriented VIF methods.

    Conclusions:

    • The proposed SSVIF framework offers an effective self-supervised approach for segmentation-oriented VIF.
    • SSVIF significantly reduces the data acquisition burden by eliminating the need for labeled datasets.
    • This work advances self-supervised learning in image fusion for improved performance in downstream vision tasks.