基于持久同调的图卷积网络细粒度三维形状分割

Chi-Chong Wong, C. Vong
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引用次数: 9

摘要

细粒度的三维分割是三维对象理解中的一项重要任务,特别是在三维对象的智能制造或零件分析等应用中。然而,这一问题所涉及的许多挑战尚未得到解决,例如:1)为3D物体解释位于不同区域的复杂结构;Ii)捕获具有足够拓扑正确性的细粒度结构。目前的深度学习和图形机器学习方法无法解决这些挑战,因此在细粒度3D分析中提供较差的性能。在这项工作中,拓扑数据分析方法与几何深度学习模型相结合,用于3D物体的细粒度分割任务。我们提出了一种新的神经网络模型,称为基于持久同调的图卷积网络(PHGCN),该模型i)将持久同调集成到图卷积网络中,以捕获多尺度结构信息,可以准确地表示三维物体的复杂结构;ii)应用了一种新的持久化图损失(persistent Diagram Loss,简称为__pd),它为细粒度结构的分割提供了足够的拓扑正确性。在细粒度三维分割上的大量实验验证了所提出的PHGCN模型的有效性,并显示出比当前最先进的方法有显著改进。
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Persistent Homology based Graph Convolution Network for Fine-grained 3D Shape Segmentation
Fine-grained 3D segmentation is an important task in 3D object understanding, especially in applications such as intelligent manufacturing or parts analysis for 3D objects. However, many challenges involved in such problem are yet to be solved, such as i) interpreting the complex structures located in different regions for 3D objects; ii) capturing fine-grained structures with sufficient topology correctness. Current deep learning and graph machine learning methods fail to tackle such challenges and thus provide inferior performance in fine-grained 3D analysis. In this work, methods in topological data analysis are incorporated with geometric deep learning model for the task of fine-grained segmentation for 3D objects. We propose a novel neural network model called Persistent Homology based Graph Convolution Network (PHGCN), which i) integrates persistent homology into graph convolution network to capture multi-scale structural information that can accurately represent complex structures for 3D objects; ii) applies a novel Persistence Diagram Loss (ℒPD) that provides sufficient topology correctness for segmentation over the fine-grained structures. Extensive experiments on fine-grained 3D segmentation validate the effectiveness of the proposed PHGCN model and show significant improvements over current state-of-the-art methods.
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