基于改进Res2Net与自适应多尺度窗口池化的调制识别方法

王丹; 李万杰; 江丰杨

doi:10.12263/DZXB.20251229

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基于改进Res2Net与自适应多尺度窗口池化的调制识别方法

学术论文 | 更新时间：2026-05-28

- 基于改进Res2Net与自适应多尺度窗口池化的调制识别方法
- Modulation Recognition Method Based on Improved Res2Net and Adaptive Multi-Scale Window Pooling
- 电子学报 2026年54卷第2期页码：562-577
- 作者机构：
  
  重庆邮电大学通信与信息工程学院，重庆 400065
- 作者简介：
  
  [ "王丹女，1981年9月出生于重庆市。博士，现为正高级工程师、重庆邮电大学硕士生导师。主要研究方向为移动通信物理层算法、物联网、信号处理。E-mail: wangdan@cqupt.edu.cn" ]
  [ "李万杰男，2001年10月出生于重庆市。现为重庆邮电大学硕士研究生。主要研究方向为调制识别、信号处理。E-mail: 1531603255@qq.com" ]
  [ "江丰杨男，2002年2月出生于浙江省杭州市。现为重庆邮电大学硕士研究生。主要研究方向为调制识别、信号处理。E-mail: fengyang_jiang@163.com" ]
- 基金信息：
  
  重庆市自然科学基金创新发展联合基金（中国星网）资助项目(CSTB2023NSCQ-LZX0114)
- DOI：10.12263/DZXB.20251229
  中图分类号： TN911.3;
- 收稿：2026-01-12，
  
  录用：2026-01-31，
  
  纸质出版：2026-02-25
- 稿件说明：
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王丹, 李万杰, 江丰杨. 基于改进Res2Net与自适应多尺度窗口池化的调制识别方法[J]. 电子学报, 2026, 54(02): 562-577.

WANG Dan, LI Wanjie, JIANG Fengyang. Modulation Recognition Method Based on Improved Res2Net and Adaptive Multi-Scale Window Pooling[J]. Acta Electronica Sinica, 2026, 54(02): 562-577.
王丹, 李万杰, 江丰杨. 基于改进Res2Net与自适应多尺度窗口池化的调制识别方法[J]. 电子学报, 2026, 54(02): 562-577. DOI：10.12263/DZXB.20251229

WANG Dan, LI Wanjie, JIANG Fengyang. Modulation Recognition Method Based on Improved Res2Net and Adaptive Multi-Scale Window Pooling[J]. Acta Electronica Sinica, 2026, 54(02): 562-577. DOI：10.12263/DZXB.20251229

摘要

随着现代通信技术的快速发展，自动调制识别（Automatic Modulation Recognition，AMR）在频谱资源管理方面的重要性日益凸显，基于深度学习的AMR方法凭借其优异的性能成为当前研究热点。针对现有方法在复杂信道条件下多尺度特征融合能力不足、特征token化方式有效性与复杂度难以平衡的问题，提出一种基于改进Res2Net与自适应多尺度窗口池化的调制识别方法Res2-AMWP。特征提取阶段利用改进的Res2Net对特征按通道分组并逐级融合，同时引入挤压与激励（Squeeze-and-Excitation，SE）注意力机制对通道进行自适应重标定。特征融合阶段提出自适应多尺度窗口池化（Adaptive Multi-scale Window Pooling，AMWP）模块将多尺度特征转化为更具判别性的token表征，并利用双向长短期记忆网络（Bidirectional Long Short-Term Memory，BiLSTM）捕获token间的上下文依赖。注意力分类头采用注意力池化机制进一步突出关键的token表征，由全连接层得到最终的识别结果。在公开数据集RadioML2016.10a、RadioML2016.10b、RML22上的实验结果表明，Res2-AMWP的整体识别准确率分别达到63.51%、65.36%、70.30%，相较于多种对比方法分别提高了1.01%~7.33%、0.32%~6.5%、0.75%~8.40%，且模型的复杂度保持在较低水平，实现了精度与复杂度的较好平衡。

Abstract

With the rapid development of modern communication technology

automatic modulation recognition (AMR) has become increasingly important in spectrum resource management

and deep learning-based AMR methods have become a current research hotspot due to their superior performance. To address the problems of insufficient multi-scale feature fusion capability and the difficulty in balancing the effectiveness and complexity of feature tokenization under complex channel conditions in existing methods

this thesis proposed a modulation recognition method termed Res2-AMWP based on an improved Res2Net and adaptive multi-scale window pooling. In the feature extraction stage

the improved Res2Net was adopted to group features by channel and fuse them progressively

while the squeeze-and-excitation (SE) attention mechanism was introduced to perform adaptive channel re-calibration. In the feature fusion stage

an adaptive multi-scale window pooling (AMWP) module was proposed to transform multi-scale features into more discriminative token representations

and a bidirectional long short-term memory network (BiLSTM) was employed to capture contextual dependencies among tokens. The attention-based classification head further highlighted key token representations through an attention pooling mechanism

and the final recognition results were obtained by fully connected layers. Experimental results on the public datasets RadioML2016.10a

RadioML2016.10b

and RML22 demonstrated that Res2-AMWP achieved overall recognition accuracies of 63.51%

65.36%

and 70.30%

respectively

outperforming multiple baseline methods by 1.01%~7.33%

0.32%~6.5%

and 0.75%~8.40% on the three datasets. Moreover

the model complexity remained at a relatively low level

achieving a good balance between accuracy and complexity.

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references

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