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Hauptverfasser: Lu, Yao, Ma, Tengfei, Wang, Zeyu, Chen, Zhuangzhi, Xu, Dongwei, Lin, Yun, Xuan, Qi, Gui, Guan
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2505.21571
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author Lu, Yao
Ma, Tengfei
Wang, Zeyu
Chen, Zhuangzhi
Xu, Dongwei
Lin, Yun
Xuan, Qi
Gui, Guan
author_facet Lu, Yao
Ma, Tengfei
Wang, Zeyu
Chen, Zhuangzhi
Xu, Dongwei
Lin, Yun
Xuan, Qi
Gui, Guan
contents With the rapid development of wireless communications and the growing complexity of digital modulation schemes, traditional manual modulation recognition methods struggle to extract reliable signal features and meet real-time requirements in modern scenarios. Recently, deep learning based Automatic Modulation Recognition (AMR) approaches have greatly improved classification accuracy. However, their large model sizes and high computational demands hinder deployment on resource-constrained devices. Model pruning provides a general approach to reduce model complexity, but existing weight, channel, and layer pruning techniques each present a trade-off between compression rate, hardware acceleration, and accuracy preservation. To this end, in this paper, we introduce FCOS, a novel Fine-to-COarse two-Stage pruning framework that combines channel-level pruning with layer-level collapse diagnosis to achieve extreme compression, high performance and efficient inference. In the first stage of FCOS, hierarchical clustering and parameter fusion are applied to channel weights to achieve channel-level pruning. Then a Layer Collapse Diagnosis (LaCD) module uses linear probing to identify layer collapse and removes the collapsed layers due to high channel compression ratio. Experiments on multiple AMR benchmarks demonstrate that FCOS outperforms existing channel and layer pruning methods. Specifically, FCOS achieves 95.51% FLOPs reduction and 95.31% parameter reduction while still maintaining performance close to the original ResNet56, with only a 0.46% drop in accuracy on Sig2019-12. Code is available at https://github.com/yaolu-zjut/FCOS.
format Preprint
id arxiv_https___arxiv_org_abs_2505_21571
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle FCOS: A Two-Stage Recoverable Model Pruning Framework for Automatic Modulation Recognition
Lu, Yao
Ma, Tengfei
Wang, Zeyu
Chen, Zhuangzhi
Xu, Dongwei
Lin, Yun
Xuan, Qi
Gui, Guan
Machine Learning
Artificial Intelligence
With the rapid development of wireless communications and the growing complexity of digital modulation schemes, traditional manual modulation recognition methods struggle to extract reliable signal features and meet real-time requirements in modern scenarios. Recently, deep learning based Automatic Modulation Recognition (AMR) approaches have greatly improved classification accuracy. However, their large model sizes and high computational demands hinder deployment on resource-constrained devices. Model pruning provides a general approach to reduce model complexity, but existing weight, channel, and layer pruning techniques each present a trade-off between compression rate, hardware acceleration, and accuracy preservation. To this end, in this paper, we introduce FCOS, a novel Fine-to-COarse two-Stage pruning framework that combines channel-level pruning with layer-level collapse diagnosis to achieve extreme compression, high performance and efficient inference. In the first stage of FCOS, hierarchical clustering and parameter fusion are applied to channel weights to achieve channel-level pruning. Then a Layer Collapse Diagnosis (LaCD) module uses linear probing to identify layer collapse and removes the collapsed layers due to high channel compression ratio. Experiments on multiple AMR benchmarks demonstrate that FCOS outperforms existing channel and layer pruning methods. Specifically, FCOS achieves 95.51% FLOPs reduction and 95.31% parameter reduction while still maintaining performance close to the original ResNet56, with only a 0.46% drop in accuracy on Sig2019-12. Code is available at https://github.com/yaolu-zjut/FCOS.
title FCOS: A Two-Stage Recoverable Model Pruning Framework for Automatic Modulation Recognition
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2505.21571