Saved in:
Bibliographic Details
Main Authors: Liu, Minglu, Hu, Cunchen, Xu, Liangliang, Tang, Fengming, Wang, Ruijia, Yu, Fu
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.06836
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911577977913344
author Liu, Minglu
Hu, Cunchen
Xu, Liangliang
Tang, Fengming
Wang, Ruijia
Yu, Fu
author_facet Liu, Minglu
Hu, Cunchen
Xu, Liangliang
Tang, Fengming
Wang, Ruijia
Yu, Fu
contents Quantization is an effective way to reduce the memory cost of large-scale model training. However, most existing methods adopt fixed-precision policies, which ignore the fact that optimizer-state distributions vary significantly across layers and training steps. Such uniform designs often introduce noticeable accuracy degradation. To move beyond fixed quantization, we propose STQuant, a distributed training framework that reduces the memory footprint of optimizer states via dynamic precision allocation across layers, state variables, and training steps, while maintaining model quality. Naively applying dynamic quantization during training is challenging for two reasons. First, optimizer states are numerically sensitive, and quantization noise can destabilize quality. Second, jointly considering multiple states and layers induces a large combinatorial search space. STQuant addresses these challenges with two key techniques: 1) a provably near-optimal factor selection strategy that accurately identifies the most influential factors for precision adaptation. 2) a dynamic transition decision algorithm that reduces the search cost from exponential to linear complexity. Experiments on GPT-2 and ViT show that STQuant reduces optimizer-state memory by 84.4%, achieving an average bit-width of as low as 5.1 bits, compared with existing solutions. Moreover, STQuant incurs only O(N/K) computational overhead and requires O(1) extra space.
format Preprint
id arxiv_https___arxiv_org_abs_2604_06836
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle STQuant: Spatio-Temporal Adaptive Framework for Optimizer Quantization in Large Multimodal Model Training
Liu, Minglu
Hu, Cunchen
Xu, Liangliang
Tang, Fengming
Wang, Ruijia
Yu, Fu
Machine Learning
Quantization is an effective way to reduce the memory cost of large-scale model training. However, most existing methods adopt fixed-precision policies, which ignore the fact that optimizer-state distributions vary significantly across layers and training steps. Such uniform designs often introduce noticeable accuracy degradation. To move beyond fixed quantization, we propose STQuant, a distributed training framework that reduces the memory footprint of optimizer states via dynamic precision allocation across layers, state variables, and training steps, while maintaining model quality. Naively applying dynamic quantization during training is challenging for two reasons. First, optimizer states are numerically sensitive, and quantization noise can destabilize quality. Second, jointly considering multiple states and layers induces a large combinatorial search space. STQuant addresses these challenges with two key techniques: 1) a provably near-optimal factor selection strategy that accurately identifies the most influential factors for precision adaptation. 2) a dynamic transition decision algorithm that reduces the search cost from exponential to linear complexity. Experiments on GPT-2 and ViT show that STQuant reduces optimizer-state memory by 84.4%, achieving an average bit-width of as low as 5.1 bits, compared with existing solutions. Moreover, STQuant incurs only O(N/K) computational overhead and requires O(1) extra space.
title STQuant: Spatio-Temporal Adaptive Framework for Optimizer Quantization in Large Multimodal Model Training
topic Machine Learning
url https://arxiv.org/abs/2604.06836