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Main Authors: Yao, Yumeng, Dong, Jingzhi, Gu, Haowen, Chen, Tao, Wu, Zonghan, Huang, Xiaoshui, Yao, Yazhou
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.17566
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author Yao, Yumeng
Dong, Jingzhi
Gu, Haowen
Chen, Tao
Wu, Zonghan
Huang, Xiaoshui
Yao, Yazhou
author_facet Yao, Yumeng
Dong, Jingzhi
Gu, Haowen
Chen, Tao
Wu, Zonghan
Huang, Xiaoshui
Yao, Yazhou
contents With the rapid progress of multimodal foundation models and predictive pre-training, an important open question is how to equip 3D point clouds with a pre-training paradigm that is better aligned with next-token and next-embedding learning. Existing point-cloud self-supervised methods are largely built on masked reconstruction or explicit geometric generation, and thus remain tied to input recovery rather than predictive dependency modeling. In this paper, we introduce PointNTP, which reformulates point cloud pre-training as a fully causal, decoder-free latent Next-Token Prediction problem. Specifically, each point cloud is first partitioned into local patches and serialized into a structured 3D token sequence according to patch-center geometry. The resulting sequence is then modeled by a causal Transformer under prefix-only conditioning, and trained with a shift-based prediction objective stabilized by stop-gradient targets. This design enables the model to learn structural dependencies directly in latent space, without reconstruction decoders or explicit geometric recovery. Extensive experiments demonstrate that the proposed PointNTP is highly competitive across multiple downstream tasks: it achieves 93.8%(+0.5%), 92.6%(+0.3%), and 89.3%(+1.1%) on OBJ_BG, OBJ_ONLY, and PB_T50_RS of ScanObjectNN, respectively; obtains 85.0%(+0.1%) in Cls.mIoU on ShapeNetPart; and reaches 71.1% mAcc on S3DIS Area 5. Overall, decoder-free causal latent prediction provides a simple, scalable, and potentially modality-agnostic paradigm for point-cloud self-supervised learning, offering a new 3D perspective on foundation-style predictive learning for 3D data.
format Preprint
id arxiv_https___arxiv_org_abs_2605_17566
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Rethinking Point Clouds as Sequences: A Causal Next-Token Predictive Learning Framework
Yao, Yumeng
Dong, Jingzhi
Gu, Haowen
Chen, Tao
Wu, Zonghan
Huang, Xiaoshui
Yao, Yazhou
Computer Vision and Pattern Recognition
With the rapid progress of multimodal foundation models and predictive pre-training, an important open question is how to equip 3D point clouds with a pre-training paradigm that is better aligned with next-token and next-embedding learning. Existing point-cloud self-supervised methods are largely built on masked reconstruction or explicit geometric generation, and thus remain tied to input recovery rather than predictive dependency modeling. In this paper, we introduce PointNTP, which reformulates point cloud pre-training as a fully causal, decoder-free latent Next-Token Prediction problem. Specifically, each point cloud is first partitioned into local patches and serialized into a structured 3D token sequence according to patch-center geometry. The resulting sequence is then modeled by a causal Transformer under prefix-only conditioning, and trained with a shift-based prediction objective stabilized by stop-gradient targets. This design enables the model to learn structural dependencies directly in latent space, without reconstruction decoders or explicit geometric recovery. Extensive experiments demonstrate that the proposed PointNTP is highly competitive across multiple downstream tasks: it achieves 93.8%(+0.5%), 92.6%(+0.3%), and 89.3%(+1.1%) on OBJ_BG, OBJ_ONLY, and PB_T50_RS of ScanObjectNN, respectively; obtains 85.0%(+0.1%) in Cls.mIoU on ShapeNetPart; and reaches 71.1% mAcc on S3DIS Area 5. Overall, decoder-free causal latent prediction provides a simple, scalable, and potentially modality-agnostic paradigm for point-cloud self-supervised learning, offering a new 3D perspective on foundation-style predictive learning for 3D data.
title Rethinking Point Clouds as Sequences: A Causal Next-Token Predictive Learning Framework
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2605.17566