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Main Authors: Zhong, Qimin, Liao, Hao, Wang, Siwei, Zhou, Mingyang, Wu, Xiaoqun, Mao, Rui, Chen, Wei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.23186
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author Zhong, Qimin
Liao, Hao
Wang, Siwei
Zhou, Mingyang
Wu, Xiaoqun
Mao, Rui
Chen, Wei
author_facet Zhong, Qimin
Liao, Hao
Wang, Siwei
Zhou, Mingyang
Wu, Xiaoqun
Mao, Rui
Chen, Wei
contents Large Language Models (LLMs) have achieved impressive performance across diverse tasks but continue to struggle with learning transitive relations, a cornerstone for complex planning. To address this issue, we investigate the Multi-Token Prediction (MTP) paradigm and its impact to transitive relation learning. We theoretically analyze the MTP paradigm using a Transformer architecture composed of a shared output head and a transfer layer. Our analysis reveals that the transfer layer gradually learns the multi-step adjacency information, which in turn enables the backbone model to capture unobserved transitive reachability relations beyond those directly present in the training data, albeit with some inevitable noise in adjacency estimation. Building on this foundation, we propose two strategies to enhance the transfer layer and overall learning quality: Next-Token Injection (NTI) and a Transformer-based transfer layer. Our experiments on both synthetic graphs and the Blocksworld planning benchmark validate our theoretical findings and demonstrate that the improvements significantly enhance the model's path-planning capability. These findings deepen our understanding of how Transformers with MTP learn in complex planning tasks, and provide practical strategies to overcome the transitivity bottleneck, paving the way toward structurally aware and general-purpose planning models.
format Preprint
id arxiv_https___arxiv_org_abs_2509_23186
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Understanding and Enhancing the Planning Capability of Language Models via Multi-Token Prediction
Zhong, Qimin
Liao, Hao
Wang, Siwei
Zhou, Mingyang
Wu, Xiaoqun
Mao, Rui
Chen, Wei
Artificial Intelligence
Machine Learning
Large Language Models (LLMs) have achieved impressive performance across diverse tasks but continue to struggle with learning transitive relations, a cornerstone for complex planning. To address this issue, we investigate the Multi-Token Prediction (MTP) paradigm and its impact to transitive relation learning. We theoretically analyze the MTP paradigm using a Transformer architecture composed of a shared output head and a transfer layer. Our analysis reveals that the transfer layer gradually learns the multi-step adjacency information, which in turn enables the backbone model to capture unobserved transitive reachability relations beyond those directly present in the training data, albeit with some inevitable noise in adjacency estimation. Building on this foundation, we propose two strategies to enhance the transfer layer and overall learning quality: Next-Token Injection (NTI) and a Transformer-based transfer layer. Our experiments on both synthetic graphs and the Blocksworld planning benchmark validate our theoretical findings and demonstrate that the improvements significantly enhance the model's path-planning capability. These findings deepen our understanding of how Transformers with MTP learn in complex planning tasks, and provide practical strategies to overcome the transitivity bottleneck, paving the way toward structurally aware and general-purpose planning models.
title Understanding and Enhancing the Planning Capability of Language Models via Multi-Token Prediction
topic Artificial Intelligence
Machine Learning
url https://arxiv.org/abs/2509.23186