Related papers: The Point, the Vision and the Text: Does Point Cloud Boost Spatial Reasoning of Large Language Models?

The Point, the Vision and the Text: Does Point Cloud Boost Spatial Reasoning of Large Language Models?

URL: http://arxiv.org/abs/2504.04540v1
Date: Sun, 06 Apr 2025 16:38:48 GMT
Title: The Point, the Vision and the Text: Does Point Cloud Boost Spatial Reasoning of Large Language Models?
Authors: Weichen Zhang, Ruiying Peng, Chen Gao, Jianjie Fang, Xin Zeng, Kaiyuan Li, Ziyou Wang, Jinqiang Cui, Xin Wang, Xinlei Chen, Yong Li,
Abstract summary: 3D Large Language Models (LLMs) leveraging spatial information in point clouds for 3D spatial reasoning attract great attention.<n>Despite some promising results, the role of point clouds in 3D spatial reasoning remains under-explored.<n>We comprehensively evaluate and analyze these models to answer the research question: textitDoes point cloud truly boost the spatial reasoning capacities of 3D LLMs?
Score: 42.3970767778131
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: 3D Large Language Models (LLMs) leveraging spatial information in point clouds for 3D spatial reasoning attract great attention. Despite some promising results, the role of point clouds in 3D spatial reasoning remains under-explored. In this work, we comprehensively evaluate and analyze these models to answer the research question: \textit{Does point cloud truly boost the spatial reasoning capacities of 3D LLMs?} We first evaluate the spatial reasoning capacity of LLMs with different input modalities by replacing the point cloud with the visual and text counterparts. We then propose a novel 3D QA (Question-answering) benchmark, ScanReQA, that comprehensively evaluates models' understanding of binary spatial relationships. Our findings reveal several critical insights: 1) LLMs without point input could even achieve competitive performance even in a zero-shot manner; 2) existing 3D LLMs struggle to comprehend the binary spatial relationships; 3) 3D LLMs exhibit limitations in exploiting the structural coordinates in point clouds for fine-grained spatial reasoning. We think these conclusions can help the next step of 3D LLMs and also offer insights for foundation models in other modalities. We release datasets and reproducible codes in the anonymous project page: https://3d-llm.xyz.

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