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Auteurs principaux: Abdel-Rahman, Mohammad J., Alslman, Yasmeen, Refai, Dania, Saleh, Amro, Loha, Malik A. Abu, Hamed, Mohammad Yahya
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2508.18091
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author Abdel-Rahman, Mohammad J.
Alslman, Yasmeen
Refai, Dania
Saleh, Amro
Loha, Malik A. Abu
Hamed, Mohammad Yahya
author_facet Abdel-Rahman, Mohammad J.
Alslman, Yasmeen
Refai, Dania
Saleh, Amro
Loha, Malik A. Abu
Hamed, Mohammad Yahya
contents This paper investigates the capabilities of large language models (LLMs) in formulating and solving decision-making problems using mathematical programming. We first conduct a systematic review and meta-analysis of recent literature to assess how well LLMs understand, structure, and solve optimization problems across domains. The analysis is guided by critical review questions focusing on learning approaches, dataset designs, evaluation metrics, and prompting strategies. Our systematic evidence is complemented by targeted experiments designed to evaluate the performance of state-of-the-art LLMs in automatically generating optimization models for problems in computer networks. Using a newly constructed dataset, we apply three prompting strategies: Act-as-expert, chain-of-thought, and self-consistency, and evaluate the obtained outputs based on optimality gap, token-level F1 score, and compilation accuracy. Results show promising progress in LLMs' ability to parse natural language and represent symbolic formulations, but also reveal key limitations in accuracy, scalability, and interpretability. These empirical gaps motivate several future research directions, including structured datasets, domain-specific fine-tuning, hybrid neuro-symbolic approaches, modular multi-agent architectures, and dynamic retrieval via chain-of-RAGs. This paper contributes a structured roadmap for advancing LLM capabilities in mathematical programming.
format Preprint
id arxiv_https___arxiv_org_abs_2508_18091
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Teaching LLMs to Think Mathematically: A Critical Study of Decision-Making via Optimization
Abdel-Rahman, Mohammad J.
Alslman, Yasmeen
Refai, Dania
Saleh, Amro
Loha, Malik A. Abu
Hamed, Mohammad Yahya
Artificial Intelligence
Optimization and Control
This paper investigates the capabilities of large language models (LLMs) in formulating and solving decision-making problems using mathematical programming. We first conduct a systematic review and meta-analysis of recent literature to assess how well LLMs understand, structure, and solve optimization problems across domains. The analysis is guided by critical review questions focusing on learning approaches, dataset designs, evaluation metrics, and prompting strategies. Our systematic evidence is complemented by targeted experiments designed to evaluate the performance of state-of-the-art LLMs in automatically generating optimization models for problems in computer networks. Using a newly constructed dataset, we apply three prompting strategies: Act-as-expert, chain-of-thought, and self-consistency, and evaluate the obtained outputs based on optimality gap, token-level F1 score, and compilation accuracy. Results show promising progress in LLMs' ability to parse natural language and represent symbolic formulations, but also reveal key limitations in accuracy, scalability, and interpretability. These empirical gaps motivate several future research directions, including structured datasets, domain-specific fine-tuning, hybrid neuro-symbolic approaches, modular multi-agent architectures, and dynamic retrieval via chain-of-RAGs. This paper contributes a structured roadmap for advancing LLM capabilities in mathematical programming.
title Teaching LLMs to Think Mathematically: A Critical Study of Decision-Making via Optimization
topic Artificial Intelligence
Optimization and Control
url https://arxiv.org/abs/2508.18091