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Autori principali: Li, Haolin, Zhou, Yuhang, Zhao, Ziheng, Du, Siyuan, Yao, Jiangchao, Xie, Weidi, Zhang, Ya, Wang, Yanfeng
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2409.19540
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author Li, Haolin
Zhou, Yuhang
Zhao, Ziheng
Du, Siyuan
Yao, Jiangchao
Xie, Weidi
Zhang, Ya
Wang, Yanfeng
author_facet Li, Haolin
Zhou, Yuhang
Zhao, Ziheng
Du, Siyuan
Yao, Jiangchao
Xie, Weidi
Zhang, Ya
Wang, Yanfeng
contents The widespread adoption of large-scale pre-training techniques has significantly advanced the development of medical foundation models, enabling them to serve as versatile tools across a broad range of medical tasks. However, despite their strong generalization capabilities, medical foundation models pre-trained on large-scale datasets tend to suffer from domain gaps between heterogeneous data, leading to suboptimal performance on specific tasks compared to specialist models, as evidenced by previous studies. In this paper, we explore a new perspective called "Knowledge Decomposition" to improve the performance on specific medical tasks, which deconstructs the foundation model into multiple lightweight expert models, each dedicated to a particular anatomical region, with the aim of enhancing specialization and simultaneously reducing resource consumption. To accomplish the above objective, we propose a novel framework named Low-Rank Knowledge Decomposition (LoRKD), which explicitly separates gradients from different tasks by incorporating low-rank expert modules and efficient knowledge separation convolution. The low-rank expert modules resolve gradient conflicts between heterogeneous data from different anatomical regions, providing strong specialization at lower costs. The efficient knowledge separation convolution significantly improves algorithm efficiency by achieving knowledge separation within a single forward propagation. Extensive experimental results on segmentation and classification tasks demonstrate that our decomposed models not only achieve state-of-the-art performance but also exhibit superior transferability on downstream tasks, even surpassing the original foundation models in task-specific evaluations. The code is available at here.
format Preprint
id arxiv_https___arxiv_org_abs_2409_19540
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle LoRKD: Low-Rank Knowledge Decomposition for Medical Foundation Models
Li, Haolin
Zhou, Yuhang
Zhao, Ziheng
Du, Siyuan
Yao, Jiangchao
Xie, Weidi
Zhang, Ya
Wang, Yanfeng
Computer Vision and Pattern Recognition
The widespread adoption of large-scale pre-training techniques has significantly advanced the development of medical foundation models, enabling them to serve as versatile tools across a broad range of medical tasks. However, despite their strong generalization capabilities, medical foundation models pre-trained on large-scale datasets tend to suffer from domain gaps between heterogeneous data, leading to suboptimal performance on specific tasks compared to specialist models, as evidenced by previous studies. In this paper, we explore a new perspective called "Knowledge Decomposition" to improve the performance on specific medical tasks, which deconstructs the foundation model into multiple lightweight expert models, each dedicated to a particular anatomical region, with the aim of enhancing specialization and simultaneously reducing resource consumption. To accomplish the above objective, we propose a novel framework named Low-Rank Knowledge Decomposition (LoRKD), which explicitly separates gradients from different tasks by incorporating low-rank expert modules and efficient knowledge separation convolution. The low-rank expert modules resolve gradient conflicts between heterogeneous data from different anatomical regions, providing strong specialization at lower costs. The efficient knowledge separation convolution significantly improves algorithm efficiency by achieving knowledge separation within a single forward propagation. Extensive experimental results on segmentation and classification tasks demonstrate that our decomposed models not only achieve state-of-the-art performance but also exhibit superior transferability on downstream tasks, even surpassing the original foundation models in task-specific evaluations. The code is available at here.
title LoRKD: Low-Rank Knowledge Decomposition for Medical Foundation Models
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2409.19540