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Main Authors: Huang, Wei, Ge, Yi, Yang, Shuai, Xiao, Yicheng, Mao, Huizi, Lin, Yujun, Ye, Hanrong, Liu, Sifei, Cheung, Ka Chun, Yin, Hongxu, Lu, Yao, Qi, Xiaojuan, Han, Song, Chen, Yukang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.11696
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author Huang, Wei
Ge, Yi
Yang, Shuai
Xiao, Yicheng
Mao, Huizi
Lin, Yujun
Ye, Hanrong
Liu, Sifei
Cheung, Ka Chun
Yin, Hongxu
Lu, Yao
Qi, Xiaojuan
Han, Song
Chen, Yukang
author_facet Huang, Wei
Ge, Yi
Yang, Shuai
Xiao, Yicheng
Mao, Huizi
Lin, Yujun
Ye, Hanrong
Liu, Sifei
Cheung, Ka Chun
Yin, Hongxu
Lu, Yao
Qi, Xiaojuan
Han, Song
Chen, Yukang
contents We propose QeRL, a Quantization-enhanced Reinforcement Learning framework for large language models (LLMs). While RL is essential for LLMs' reasoning capabilities, it is resource-intensive, requiring substantial GPU memory and long rollout durations. QeRL addresses these issues by combining NVFP4 quantization with Low-Rank Adaptation (LoRA), accelerating rollout phase of RL while reducing memory overhead. Beyond efficiency, our findings show that quantization noise increases policy entropy, enhancing exploration, and enabling the discovery of better strategies during RL. To further optimize exploration, QeRL introduces an Adaptive Quantization Noise (AQN) mechanism, which dynamically adjusts noise during training. Experiments demonstrate that QeRL delivers over 1.5 times speedup in the rollout phase. Moreover, this is the first framework to enable RL training of a 32B LLM on a single H100 80GB GPU, while delivering overall speedups for RL training. It also achieves faster reward growth and higher final accuracy than 16-bit LoRA and QLoRA, while matching the performance of full-parameter fine-tuning on mathematical benchmarks such as GSM8K (90.8%) and MATH 500 (77.4%) in the 7B model. These results establish QeRL as an efficient and effective framework for RL training in LLMs.
format Preprint
id arxiv_https___arxiv_org_abs_2510_11696
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle QeRL: Beyond Efficiency -- Quantization-enhanced Reinforcement Learning for LLMs
Huang, Wei
Ge, Yi
Yang, Shuai
Xiao, Yicheng
Mao, Huizi
Lin, Yujun
Ye, Hanrong
Liu, Sifei
Cheung, Ka Chun
Yin, Hongxu
Lu, Yao
Qi, Xiaojuan
Han, Song
Chen, Yukang
Machine Learning
Computation and Language
Computer Vision and Pattern Recognition
We propose QeRL, a Quantization-enhanced Reinforcement Learning framework for large language models (LLMs). While RL is essential for LLMs' reasoning capabilities, it is resource-intensive, requiring substantial GPU memory and long rollout durations. QeRL addresses these issues by combining NVFP4 quantization with Low-Rank Adaptation (LoRA), accelerating rollout phase of RL while reducing memory overhead. Beyond efficiency, our findings show that quantization noise increases policy entropy, enhancing exploration, and enabling the discovery of better strategies during RL. To further optimize exploration, QeRL introduces an Adaptive Quantization Noise (AQN) mechanism, which dynamically adjusts noise during training. Experiments demonstrate that QeRL delivers over 1.5 times speedup in the rollout phase. Moreover, this is the first framework to enable RL training of a 32B LLM on a single H100 80GB GPU, while delivering overall speedups for RL training. It also achieves faster reward growth and higher final accuracy than 16-bit LoRA and QLoRA, while matching the performance of full-parameter fine-tuning on mathematical benchmarks such as GSM8K (90.8%) and MATH 500 (77.4%) in the 7B model. These results establish QeRL as an efficient and effective framework for RL training in LLMs.
title QeRL: Beyond Efficiency -- Quantization-enhanced Reinforcement Learning for LLMs
topic Machine Learning
Computation and Language
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2510.11696