Invariant Training 2D-3D Joint Hard Samples for Few-Shot Point Cloud Recognition

• URL: http://arxiv.org/abs/2308.09694v1
• Date: Fri, 18 Aug 2023 17:43:12 GMT
• Title: Invariant Training 2D-3D Joint Hard Samples for Few-Shot Point Cloud Recognition
• Authors: Xuanyu Yi, Jiajun Deng, Qianru Sun, Xian-Sheng Hua, Joo-Hwee Lim, Hanwang Zhang
• Abstract summary: We tackle the data scarcity challenge in few-shot point cloud recognition of 3D objects by using a joint prediction from a conventional 3D model and a well-trained 2D model. We find out the crux is the less effective training for the ''joint hard samples'', which have high confidence prediction on different wrong labels. Our proposed invariant training strategy, called InvJoint, does not only emphasize the training more on the hard samples, but also seeks the invariance between the conflicting 2D and 3D ambiguous predictions.
• Score: 108.07591240357306
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: We tackle the data scarcity challenge in few-shot point cloud recognition of 3D objects by using a joint prediction from a conventional 3D model and a well-trained 2D model. Surprisingly, such an ensemble, though seems trivial, has hardly been shown effective in recent 2D-3D models. We find out the crux is the less effective training for the ''joint hard samples'', which have high confidence prediction on different wrong labels, implying that the 2D and 3D models do not collaborate well. To this end, our proposed invariant training strategy, called InvJoint, does not only emphasize the training more on the hard samples, but also seeks the invariance between the conflicting 2D and 3D ambiguous predictions. InvJoint can learn more collaborative 2D and 3D representations for better ensemble. Extensive experiments on 3D shape classification with widely adopted ModelNet10/40, ScanObjectNN and Toys4K, and shape retrieval with ShapeNet-Core validate the superiority of our InvJoint.

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