Physics-Grounded Attached Shadow Detection Using Approximate 3D Geometry and Light Direction

• URL: http://arxiv.org/abs/2512.06179v1
• Date: Fri, 05 Dec 2025 22:01:27 GMT
• Title: Physics-Grounded Attached Shadow Detection Using Approximate 3D Geometry and Light Direction
• Authors: Shilin Hu, Jingyi Xu, Sagnik Das, Dimitris Samaras, Hieu Le,
• Abstract summary: Attached shadows occur on the surface of objects where light cannot reach because of self-occlusion.<n>We introduce a framework that jointly detects cast and attached shadows by reasoning about their mutual relationship with scene illumination and geometry.<n>Our system consists of a shadow detection module that predicts both shadow types separately, and a light estimation module that infers the light direction from the detected shadows.
• Score: 46.19532675330894
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Attached shadows occur on the surface of the occluder where light cannot reach because of self-occlusion. They are crucial for defining the three-dimensional structure of objects and enhancing scene understanding. Yet existing shadow detection methods mainly target cast shadows, and there are no dedicated datasets or models for detecting attached shadows. To address this gap, we introduce a framework that jointly detects cast and attached shadows by reasoning about their mutual relationship with scene illumination and geometry. Our system consists of a shadow detection module that predicts both shadow types separately, and a light estimation module that infers the light direction from the detected shadows. The estimated light direction, combined with surface normals, allows us to derive a geometry-consistent partial map that identifies regions likely to be self-occluded. This partial map is then fed back to refine shadow predictions, forming a closed-loop reasoning process that iteratively improves both shadow segmentation and light estimation. In order to train our method, we have constructed a dataset of 1,458 images with separate annotations for cast and attached shadows, enabling training and quantitative evaluation of both. Experimental results demonstrate that this iterative geometry-illumination reasoning substantially improves the detection of attached shadows, with at least 33% BER reduction, while maintaining strong full and cast shadow performance.

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