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Autori principali: Zhu, Erle, Liu, Yadi, Zhang, Zhe, Li, Xujun, Zhou, Jin, Yu, Xinjie, Huang, Minlie, Wang, Hongning
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2501.10768
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author Zhu, Erle
Liu, Yadi
Zhang, Zhe
Li, Xujun
Zhou, Jin
Yu, Xinjie
Huang, Minlie
Wang, Hongning
author_facet Zhu, Erle
Liu, Yadi
Zhang, Zhe
Li, Xujun
Zhou, Jin
Yu, Xinjie
Huang, Minlie
Wang, Hongning
contents Pre-trained on extensive text and image corpora, current Multi-Modal Large Language Models (MLLM) have shown strong capabilities in general visual reasoning tasks. However, their performance is still lacking in physical domains that require understanding diagrams with complex physical structures and quantitative analysis based on multi-modal information. To address this, we develop a new framework, named Multi-Modal Scientific Reasoning with Physics Perception and Simulation (MAPS) based on an MLLM. MAPS decomposes expert-level multi-modal reasoning task into physical diagram understanding via a Physical Perception Model (PPM) and reasoning with physical knowledge via a simulator. The PPM module is obtained by fine-tuning a visual language model using carefully designed synthetic data with paired physical diagrams and corresponding simulation language descriptions. At the inference stage, MAPS integrates the simulation language description of the input diagram provided by PPM and results obtained through a Chain-of-Simulation process with MLLM to derive the underlying rationale and the final answer. Validated using our collected college-level circuit analysis problems, MAPS significantly improves reasoning accuracy of MLLM and outperforms all existing models. The results confirm MAPS offers a promising direction for enhancing multi-modal scientific reasoning ability of MLLMs. We will release our code, model and dataset used for our experiments upon publishing of this paper.
format Preprint
id arxiv_https___arxiv_org_abs_2501_10768
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MAPS: Advancing Multi-Modal Reasoning in Expert-Level Physical Science
Zhu, Erle
Liu, Yadi
Zhang, Zhe
Li, Xujun
Zhou, Jin
Yu, Xinjie
Huang, Minlie
Wang, Hongning
Artificial Intelligence
Pre-trained on extensive text and image corpora, current Multi-Modal Large Language Models (MLLM) have shown strong capabilities in general visual reasoning tasks. However, their performance is still lacking in physical domains that require understanding diagrams with complex physical structures and quantitative analysis based on multi-modal information. To address this, we develop a new framework, named Multi-Modal Scientific Reasoning with Physics Perception and Simulation (MAPS) based on an MLLM. MAPS decomposes expert-level multi-modal reasoning task into physical diagram understanding via a Physical Perception Model (PPM) and reasoning with physical knowledge via a simulator. The PPM module is obtained by fine-tuning a visual language model using carefully designed synthetic data with paired physical diagrams and corresponding simulation language descriptions. At the inference stage, MAPS integrates the simulation language description of the input diagram provided by PPM and results obtained through a Chain-of-Simulation process with MLLM to derive the underlying rationale and the final answer. Validated using our collected college-level circuit analysis problems, MAPS significantly improves reasoning accuracy of MLLM and outperforms all existing models. The results confirm MAPS offers a promising direction for enhancing multi-modal scientific reasoning ability of MLLMs. We will release our code, model and dataset used for our experiments upon publishing of this paper.
title MAPS: Advancing Multi-Modal Reasoning in Expert-Level Physical Science
topic Artificial Intelligence
url https://arxiv.org/abs/2501.10768