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Autori principali: Wu, Jinyang, Zhai, Guocheng, Jin, Ruihan, Shen, Yuhao, Lu, Zhengxi, Zhang, Fan, Luo, Haoran, Lian, Zheng, Wen, Zhengqi, Tao, Jianhua
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2605.22177
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author Wu, Jinyang
Zhai, Guocheng
Jin, Ruihan
Shen, Yuhao
Lu, Zhengxi
Zhang, Fan
Luo, Haoran
Lian, Zheng
Wen, Zhengqi
Tao, Jianhua
author_facet Wu, Jinyang
Zhai, Guocheng
Jin, Ruihan
Shen, Yuhao
Lu, Zhengxi
Zhang, Fan
Luo, Haoran
Lian, Zheng
Wen, Zhengqi
Tao, Jianhua
contents The proliferation of large language models (LLMs) and modular skills has endowed autonomous agents with increasingly powerful capabilities. Existing frameworks typically rely on monolithic LLMs and fixed logic to interface with these skills. This gives rise to a critical bottleneck: different LLMs offer distinct advantages across diverse domains, yet current frameworks fail to exploit the complementary strengths of models and skills, thereby limiting their performance on downstream tasks. In this paper, we present Maestro (Multimodal Agent for Expert-Skill Targeted Reinforced Orchestration), a Reinforcement Learning (RL)-driven orchestration framework that reframes heterogeneous multimodal tasks as a sequential decision-making process over a hierarchical model-skill registry. Rather than consolidating all knowledge into a single model, Maestro trains a lightweight policy to dynamically compose ensembles of frozen expert models and a two-tier skill library, deciding at each step whether to invoke an external expert, which model-skill pair to select, and when to terminate. The policy is optimized via outcome-based RL, requiring no step-level supervision. We evaluate Maestro across ten representative multimodal benchmarks spanning mathematical reasoning, chart understanding, high-resolution perception, and domain-specific analysis. With only a 4B orchestrator, Maestro achieves an average accuracy of 70.1%, surpassing both GPT-5 (69.3%) and Gemini-2.5-Pro (68.7%). Crucially, the learned coordination policy generalizes to unseen models and skills without retraining: augmenting the registry with out-of-domain experts yields a 59.5% average on four challenging benchmarks, outperforming all closed-source baselines. Maestro further maintains high computational efficiency with low latency. The source code is available at https://github.com/jinyangwu/Maestro.
format Preprint
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Maestro: Reinforcement Learning to Orchestrate Hierarchical Model-Skill Ensembles
Wu, Jinyang
Zhai, Guocheng
Jin, Ruihan
Shen, Yuhao
Lu, Zhengxi
Zhang, Fan
Luo, Haoran
Lian, Zheng
Wen, Zhengqi
Tao, Jianhua
Machine Learning
Computation and Language
The proliferation of large language models (LLMs) and modular skills has endowed autonomous agents with increasingly powerful capabilities. Existing frameworks typically rely on monolithic LLMs and fixed logic to interface with these skills. This gives rise to a critical bottleneck: different LLMs offer distinct advantages across diverse domains, yet current frameworks fail to exploit the complementary strengths of models and skills, thereby limiting their performance on downstream tasks. In this paper, we present Maestro (Multimodal Agent for Expert-Skill Targeted Reinforced Orchestration), a Reinforcement Learning (RL)-driven orchestration framework that reframes heterogeneous multimodal tasks as a sequential decision-making process over a hierarchical model-skill registry. Rather than consolidating all knowledge into a single model, Maestro trains a lightweight policy to dynamically compose ensembles of frozen expert models and a two-tier skill library, deciding at each step whether to invoke an external expert, which model-skill pair to select, and when to terminate. The policy is optimized via outcome-based RL, requiring no step-level supervision. We evaluate Maestro across ten representative multimodal benchmarks spanning mathematical reasoning, chart understanding, high-resolution perception, and domain-specific analysis. With only a 4B orchestrator, Maestro achieves an average accuracy of 70.1%, surpassing both GPT-5 (69.3%) and Gemini-2.5-Pro (68.7%). Crucially, the learned coordination policy generalizes to unseen models and skills without retraining: augmenting the registry with out-of-domain experts yields a 59.5% average on four challenging benchmarks, outperforming all closed-source baselines. Maestro further maintains high computational efficiency with low latency. The source code is available at https://github.com/jinyangwu/Maestro.
title Maestro: Reinforcement Learning to Orchestrate Hierarchical Model-Skill Ensembles
topic Machine Learning
Computation and Language
url https://arxiv.org/abs/2605.22177