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One Shot Learning for Edge Detection on Point Clouds.

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    This study introduces a novel one-shot learning method for edge extraction on 3D point clouds. OSFENet effectively learns scanner-specific data distributions, outperforming general models on diverse datasets.

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    Area of Science:

    • Computer Vision
    • Machine Learning
    • 3D Data Processing

    Background:

    • 3D scanners have unique data characteristics and sampling error distributions.
    • Training neural networks on diverse scanner data yields suboptimal edge extraction performance.
    • Scanner-specific data distributions necessitate specialized network training approaches.

    Purpose of the Study:

    • To develop a novel one-shot learning method for accurate edge extraction on 3D point clouds.
    • To address the challenge of varying data distributions from different 3D scanners.
    • To improve the performance of point cloud analysis by learning target-specific data distributions.

    Main Methods:

    • Proposed OSFENet (One-Shot Feature Extraction Network), a lightweight network for edge extraction.
    • Designed a filtered-KNN-based surface patch representation for one-shot learning.
    • Introduced an RBF_DoS module integrating Radial Basis Function-based Descriptor of the Surface patch.

    Main Results:

    • OSFENet achieved superior results compared to 7 baselines on the ABC dataset.
    • Demonstrated effectiveness across diverse real-scanned datasets, including indoor (S3DIS) and outdoor (Semantic3D, UrbanBIS) scenes.
    • Validated the practical utility of the proposed one-shot learning approach for edge extraction.

    Conclusions:

    • The proposed one-shot learning method effectively learns scanner-specific data distributions for improved edge extraction.
    • OSFENet offers a robust and efficient solution for point cloud edge extraction in varied real-world scenarios.
    • The approach significantly advances the field of 3D point cloud analysis by enabling high-performance, scanner-adaptive feature extraction.