基于改进1DCNN+TCN的雷达辐射源快速识别方法

doi:10.12305/j.issn.1001-506X.2022.02.14

Abstract

Abstract:

In order to solve the problems of low recognition speed and that it is difficult to accurately identify radar emitter in low signal-to-noise ratios (SNRs), a fast radar emitter recognition model based on improved one-dimensional convolution neural network (1DCNN) and temporal convolution network (TCN) is proposed. In this paper, a batch normalization layer is added to the 1DCNN, and the attention mechanism is added before the full connection layer; at the same time, it is improved on the basis of the original TCN, using the Leaky ReLU activation function to replace the ReLU function; and the improved TCN is connected with 1DCNN. Through the analysis of simulation results, the model can not only identify emitter signals quickly, but also have a high accuracy rate of identification, which can effectively balance the recognition speed and model recognition accuracy.

Key words: rapid identification of emitter signals, time series, temporal convolution network (TCN), one dimensional convolution network (1DCNN), parametric linear correction element, attention mechanism

CLC Number:

TN971.1

Tao JIN, Xiaofeng WANG, Runlan TIAN, Xindong ZHANG. Rapid recognition method of radar emitter based on improved 1DCNN+TCN[J]. Systems Engineering and Electronics, 2022, 44(2): 463-469.

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References 31

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信号	主要参数	取值
BPSK	巴克码位数	{7, 11, 13}
多相码	码位数	{36, 64}
FMCW	采样频率/kHz 调制周期/ms 调制带宽/kHz	{15, 17} {50, 25, 35} {0.25, 0.35, 0.5}
Costas	频率序列/kHz	{[4 7 1 6 5 2 3], [2 6 3 8 7 5 1]}

网络模型	训练时间/s	准确率	损失
TCN	139	0.955 0	0.146 9
TCN+注意力	241	0.967 3	0.124 5

网络模型	训练时间/s	准确率	损失
TCN	139	0.955 0	0.146 9
TCN+注意力	241	0.967 3	0.124 5
CTA	147	0.967 6	0.111 3

对比项	ReLU	ELUS	Leaky ReLU
损失	0.121 4	0.117 1	0.111 3
准确率	0.964 9	0.965 6	0.967 6

网络模型	训练时间/s	训练轮数	准确率	损失
VGG19	1 363	6	0.948 7	0.152 5
ResNet18	1 490	7	0.948 0	0.153 8
AlexNet	474	5	0.917 1	0.261 3
CTA	147	11	0.967 6	0.111 3
TCN	139	8	0.955 0	0.146 9

Rapid recognition method of radar emitter based on improved 1DCNN+TCN

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