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Autori principali: Huang, Chao, Zhang, Zeliang, Liu, Jiang, Sun, Ximeng, Wu, Jialian, Yu, Xiaodong, Wang, Ze, Xu, Chenliang, Barsoum, Emad, Liu, Zicheng
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2510.15050
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author Huang, Chao
Zhang, Zeliang
Liu, Jiang
Sun, Ximeng
Wu, Jialian
Yu, Xiaodong
Wang, Ze
Xu, Chenliang
Barsoum, Emad
Liu, Zicheng
author_facet Huang, Chao
Zhang, Zeliang
Liu, Jiang
Sun, Ximeng
Wu, Jialian
Yu, Xiaodong
Wang, Ze
Xu, Chenliang
Barsoum, Emad
Liu, Zicheng
contents Multimodal large language models (MLLMs) have made rapid progress, yet their reasoning ability often lags behind strong text-only LLMs. Bridging this gap typically requires large-scale multimodal reasoning data or reinforcement learning, incurring substantial cost. An appealing alternative is parameter-space model merging between reasoning-enhanced LLMs and MLLMs, but we show that naive merging is fragile: its effectiveness varies widely across model families and can significantly degrade performance (e.g., for Qwen-based MLLMs). We propose Directional Reasoning Injection for Fine-Tuning (DRIFT), a lightweight method that transfers reasoning knowledge in the gradient space while preserving multimodal alignment. DRIFT precomputes a reasoning prior from the parameter differences between text-only reasoning experts and multimodal models, and uses it to bias gradients during supervised fine-tuning. This design retains the simplicity of standard SFT pipelines while enabling efficient and stable reasoning transfer. Experiments on multimodal reasoning benchmarks, including MathVista and MathVerse, show that DRIFT consistently outperforms naive merging and standard SFT, and matches or surpasses training-intensive methods with substantially lower data and compute.
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publishDate 2025
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spellingShingle DRIFT: Transferring Reasoning Priors for Efficient MLLM Fine-Tuning
Huang, Chao
Zhang, Zeliang
Liu, Jiang
Sun, Ximeng
Wu, Jialian
Yu, Xiaodong
Wang, Ze
Xu, Chenliang
Barsoum, Emad
Liu, Zicheng
Computer Vision and Pattern Recognition
Multimodal large language models (MLLMs) have made rapid progress, yet their reasoning ability often lags behind strong text-only LLMs. Bridging this gap typically requires large-scale multimodal reasoning data or reinforcement learning, incurring substantial cost. An appealing alternative is parameter-space model merging between reasoning-enhanced LLMs and MLLMs, but we show that naive merging is fragile: its effectiveness varies widely across model families and can significantly degrade performance (e.g., for Qwen-based MLLMs). We propose Directional Reasoning Injection for Fine-Tuning (DRIFT), a lightweight method that transfers reasoning knowledge in the gradient space while preserving multimodal alignment. DRIFT precomputes a reasoning prior from the parameter differences between text-only reasoning experts and multimodal models, and uses it to bias gradients during supervised fine-tuning. This design retains the simplicity of standard SFT pipelines while enabling efficient and stable reasoning transfer. Experiments on multimodal reasoning benchmarks, including MathVista and MathVerse, show that DRIFT consistently outperforms naive merging and standard SFT, and matches or surpasses training-intensive methods with substantially lower data and compute.
title DRIFT: Transferring Reasoning Priors for Efficient MLLM Fine-Tuning
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2510.15050