微调用于几何物体检索的 3D 基础模型

IF 2.5 4区 计算机科学 Q2 COMPUTER SCIENCE, SOFTWARE ENGINEERING
Jarne Van den Herrewegen , Tom Tourwé , Maks Ovsjanikov , Francis wyffels
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引用次数: 0

摘要

最近,ULIP-2(Xue 等人,2023 年)等基础模型推动了三维深度学习领域的发展。这些模型在训练时使用了大量数据,并在许多下游任务(如三维形状分类和少镜头部件分割)中表现出卓越的表征学习能力。最近的三维基础模型的一个特点是它们通常是多模态的,涉及图像(二维)和标题(文本)分支。这就导致了错综复杂的相互作用,使所有模式都能从中受益。与此同时,人们对这些基础模型所涉及的三维编码器本身的性质还不甚了解。具体来说,对于这些模型所提供的预训练三维特征的效用,或其适应新的下游三维数据的能力,几乎没有分析。在本文中,我们填补了这一空白,并首次展示了如何利用三维基础模型在七个不同的数据集上实现强大的三维到三维检索性能,与最先进的基于视图的架构不相上下。我们使用下游数据对预训练基础模型及其微调版本进行了评估。我们将使用分类标签的监督微调与两种自监督无标签微调方法进行了比较。重要的是,我们引入并描述了一种微调方法,因为我们发现这对于从三维基础模型中稳定地进行迁移学习至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Fine-tuning 3D foundation models for geometric object retrieval

Fine-tuning 3D foundation models for geometric object retrieval

Foundation models, such as ULIP-2 (Xue et al., 2023) recently projected forward the field of 3D deep learning. These models are trained with significantly more data and show superior representation learning capacity in many downstream tasks like 3D shape classification and few-shot part segmentation.

A particular characteristic of the recent 3D foundation models is that they are typically multi-modal, and involve image (2D) as well as caption (text) branches. This leads to an intricate interplay that benefits all modalities. At the same time, the nature of the 3D encoders alone, involved in these foundation models is not well-understood. Specifically, there is little analysis on the utility of both pre-trained 3D features provided by these models, or their capacity to adapt to new downstream 3D data. Furthermore, existing studies typically focus on label-oriented downstream tasks, such as shape classification, and ignore other critical applications, such as 3D content-based object retrieval.

In this paper, we fill this gap and show, for the first time, how 3D foundation models can be leveraged for strong 3D-to-3D retrieval performance on seven different datasets, on par with state-of-the-art view-based architectures. We evaluate both the pre-trained foundation models, as well as their fine-tuned versions using downstream data. We compare supervised fine-tuning using classification labels against two self-supervised label-free fine-tuning methods. Importantly, we introduce and describe a methodology for fine-tuning, as we found this to be crucial to make transfer learning from 3D foundation models work in a stable manner.

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来源期刊
Computers & Graphics-Uk
Computers & Graphics-Uk 工程技术-计算机:软件工程
CiteScore
5.30
自引率
12.00%
发文量
173
审稿时长
38 days
期刊介绍: Computers & Graphics is dedicated to disseminate information on research and applications of computer graphics (CG) techniques. The journal encourages articles on: 1. Research and applications of interactive computer graphics. We are particularly interested in novel interaction techniques and applications of CG to problem domains. 2. State-of-the-art papers on late-breaking, cutting-edge research on CG. 3. Information on innovative uses of graphics principles and technologies. 4. Tutorial papers on both teaching CG principles and innovative uses of CG in education.
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