Tiange Xiang scite author profile

General point clouds have been increasingly investigated for different tasks, and recently Transformerbased networks are proposed for point cloud analysis. However, there are barely related works for medical point clouds, which are important for disease detection and treatment. In this work, we propose an attention-based model specifically for medical point clouds, namely 3D medical point Transformer (3DMedPT), to examine the complex biological structures. By augmenting contextual information and summarizing local responses at query, our attention module can capture both local context and global content feature interactions. However, the insufficient training samples of medical data may lead to poor feature learning, so we apply position embeddings to learn accurate local geometry and Multi-Graph Reasoning (MGR) to examine global knowledge propagation over channel graphs to enrich feature representations. Experiments conducted on IntrA dataset proves the superiority of 3DMedPT, where we achieve the best classification and segmentation results. Furthermore, the promising generalization ability of our method is validated on general 3D point cloud benchmarks: ModelNet40 and ShapeNetPart. Code 1 is released.

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Walk in the Cloud: Learning Curves for Point Clouds Shape Analysis

Xiang

Zhang

Song

et al. 2021

Preprint

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Discrete point cloud objects lack sufficient shape descriptors of 3D geometries. In this paper, we present a novel method for aggregating hypothetical curves in point clouds. Sequences of connected points (curves) are initially grouped by taking guided walks in the point clouds, and then subsequently aggregated back to augment their pointwise features. We provide an effective implementation of the proposed aggregation strategy including a novel curve grouping operator followed by a curve aggregation operator. Our method was benchmarked on several point cloud analysis tasks where we achieved the state-of-the-art classification accuracy of 94.2% on the ModelNet40 classification task, instance IoU of 86.8% on the ShapeNetPart segmentation task and cosine error of 0.11 on the ModelNet40 normal estimation task.

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Integration of Multimodal Data for Breast Cancer Classification Using a Hybrid Deep Learning Method

Yan

Ren

Rao

et al. 2019

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Tiange Xiang

Walk in the Cloud: Learning Curves for Point Clouds Shape Analysis

BiO-Net: Learning Recurrent Bi-directional Connections for Encoder-Decoder Architecture

3D Medical Point Transformer: Introducing Convolution to Attention Networks for Medical Point Cloud Analysis

Walk in the Cloud: Learning Curves for Point Clouds Shape Analysis

Integration of Multimodal Data for Breast Cancer Classification Using a Hybrid Deep Learning Method

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