基于超球面三元组编码的干扰模式开集识别

高玉龙; 王国强; 王钢

doi:10.11999/JEIT230145

基于超球面三元组编码的干扰模式开集识别

doi: 10.11999/JEIT230145

哈尔滨工业大学电子与信息工程学院哈尔滨 150001

基金项目: 国家自然科学基金(62171163, 62271167)

详细信息

作者简介:
高玉龙：男，教授，博士生导师，研究方向为智能信号处理和智能通信

王国强：男，硕士生，研究方向为干扰信号识别技术

王钢：男，教授，博士生导师，研究方向为数据通信和移动通信

通讯作者:
高玉龙　ylgao@hit.edu.cn

中图分类号: TN972
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- 被引次数: 0
出版历程
- 收稿日期: 2023-03-10
- 修回日期: 2023-11-05
- 网络出版日期: 2023-11-15
- 刊出日期: 2024-03-27

Jamming Pattern Open Set Recognition Based on Hyperspherical Triplet Coding

School of Electronics and Information Engineering, Harbin Institute of Technology, Harbin 150001, China

Funds: The National Natural Science Foundation of China (62171163, 62271167)

摘要

摘要: 干扰模式识别是现代军事通信对抗中必不可少的一环，随着复杂电磁环境当中各种新型恶意干扰样式层出不穷，对于未知型干扰的判决也变得愈发重要。因此，要求干扰模式识别算法保持对于已知型干扰高精度识别的同时，也能够完成对于未知型干扰的判决，以排除未知型恶意干扰的影响。基于此，该文将未知型干扰存在时的干扰模式识别问题建模为开集识别问题，并提出一种基于超球面3元组编码的干扰模式开集识别方法。所提方法基于超球面3元组对输入的时频图像进行降维编码以提高识别精度，然后采用元识别分类器准确地完成干扰模式开集识别任务。通过仿真试验证明该算法在干信比大于–2 dB时能够高效地完成开放空间中的干扰模式识别任务。
- 未知型干扰信号 /
- 开集识别 /
- 3元组损失 /
- 超球面 /
- 元识别
Abstract: Jamming pattern recognition is an indispensable part of modern military communication countermeasure. With the emergence of various new malicious jamming patterns in complex electromagnetic environment, the judgment of unknown jamming has become more and more important. Therefore, the jamming pattern recognition algorithm is required to maintain the high-precision recognition of the known jamming, and can also complete the judgment of the unknown jamming to eliminate the influence of the unknown malicious jamming. Based on this, the jamming pattern recognition problem in the presence of unknown jamming as an open set recognition problem is modeled in this paper, and a jamming pattern open set recognition method based on hyperspherical triple coding is proposed. The proposed method uses hyperspherical triples to reduce the dimension of the input time-frequency image to improve the recognition accuracy, and then uses the meta-recognition classifier to accurately complete the open set recognition of the jamming pattern. The simulation results show that the algorithm can efficiently complete the jamming pattern recognition task in open space when the jamming-to-signal ratio is greater than –2 dB.
- Unknown interference signal /
- Open set recognition /
- Triplet loss /
- Hypersphere /
- Meta recognition

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图 1 3元组损失原理图

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图 2 超球面3元组编码器结构图

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图 3 试验数据组合1训练集编码数据CUSTOM降维效果图

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图 4 试验数据组合1基于元识别分类器干扰模式开集识别混淆矩阵

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图 5 试验数据组合2下不同干扰模式开集识别算法ROC曲线图

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图 6 基于超球面3元组编码的干扰模式开集识别算法准确率曲线图

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算法1　基于超球面3元组编码的干扰模式开集识别算法
准备通过基于3元组损失训练的编码器后的训练集编码数据集合$ {X^{{\text{train}}}}{\text{:\{ }}{Z_1}{\text{,}}{Z_2}{\text{,}} \cdots {\text{,}}{Z_K}{\text{\} }} $和测试集编码数据集合$ {X^{{\text{test}}}} $，其中　$ {Z_{i \in 1, 2,\cdots ,K}}:\{ {z_1},{z_2}, \cdots ,{z_{{n_i}}}\} $表示训练集第$ i $类已知型干扰样本数据集合且样本数为$ {n_i} $，样本数据为$ {z_j} $，设定阈值相关常数$ C $(通过率)。
(1)拟合各已知型干扰Weibull模型；
for $ \left\{{Z}_{i}\right\},\;i=1,2,\cdots ,K $ do
根据$ {\text{MA}}{{\text{V}}_i} = {\text{mean}}({Z_i}) $计算质心坐标$ {\text{MA}}{{\text{V}}_i} $；
for $ {z_j} \in {Z_i} $ do
选择距离类型并计算$ {z_j} $到质心$ {\text{MA}}{{\text{V}}_i} $的距离$ {d_j} $以构成距离合集$ {D_i}:\{ {d_1},{d_2}, \cdots ,{d_{{n_i}}}\} $；
end for
$ {D_i} $中的极大值分布按照Weibull分类来拟合，得到第$ i $类的$ {\text{Weibul}}{{\text{l}}_i} $分布模型。
end for
(2)各已知型干扰Weibull模型信心分数阈值设置；
for $ \left\{i\right\},\;i=1,2,\cdots ,K $ do
for $ {z_j} \in {Z_i} $ do
根据$ {\text{Weibul}}{{\text{l}}_i} $模型计算$ {z_j} $的信心分数$ {c_j} = 1 - {\text{Weibul}}{{\text{l}}_i}({d_j}) $以构成信心分数合集$ {C_i}:\{ {c_1},{c_2}, \cdots ,{c_{{n_i}}}\} $；
end for
将信心分数集合降序排列得$ {C'_i} :\{ {c'_1},{c'_2}, \cdots ,{c'_{{n_i}}}\} $;
将第$ i $类训练集样本数$ {n_i} $与通过率$ p\% $相乘得通过样本数$ {\text{nu}}{{\text{m}}_i} = {n_i} \times p\% $；
第$ i $类信心分数阈值$ {\xi _i} = {c'_{{\text{nu}}{{\text{m}}_i}}} $，即$ {C'_i} $中第$ {\text{nu}}{{\text{m}}_i} $个数值。
end for
(3)测试样本$ {x_t} \in {X^{{\text{test}}}} $开集识别，设置未知型干扰标志$ {\text{flag}} = 0 $；
for $ \left\{i\right\},\; i=1,2,\cdots ,K $ do
计算$ {x_t} $到质心$ {\text{MA}}{{\text{V}}_i} $的距离$ {d_{ti}} $；
计算$ {x_t} $属于第$ i $类的信心分数$ {c_{ti}} = 1 - {\text{Weibul}}{{\text{l}}_i}({d_{ti}}) $；
if $ {c_{ti}} \gt {\xi _i} $ do
判断类别为第$ i $类已知型干扰信号并设置$ {\text{flag}} = 1 $；
Break
end if
end for
if $ {\text{flag}} = 0 $ do
判断类别为未知型干扰信号。
end if

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表 1 干扰信号参数设置

干扰样式	干扰参数				JSR
干扰样式	干扰个数	干扰带宽因子	中心频率	初始相位	JSR
单音干扰(CW)	无	无	10～20 MHz	0～2π	–2:2:10 dB
多音干扰(MTJ)	3～6	无	10～20 MHz
宽带干扰(PBNJ)	干扰带宽因子
宽带干扰(PBNJ)	0.2～0.8
线性扫频干扰(LFM)	带宽因子	扫频周期	依赖于带宽因子的大小，保证信号带宽完整地位于感知带宽内。
线性扫频干扰(LFM)	0.2～0.8	0.05～0.25 ms	依赖于带宽因子的大小，保证信号带宽完整地位于感知带宽内。
正弦调频干扰(SFM)	带宽因子	扫频周期
正弦调频干扰(SFM)	0.2～0.8	0.05～0.25 ms
周期脉冲噪声干扰(PPNJ)	脉冲周期	脉冲周期内占空比	脉冲干扰触发时间
周期脉冲噪声干扰(PPNJ)	0.05～0.25 ms	0.1～0.5	0～0.5 ms
跳频干扰(FHJ)	驻留时间	跳变频率集	信号带宽
跳频干扰(FHJ)	0.1 ms	10.5:1:19.5 MHz	1 MHz
噪声调频干扰(NFM)	调频因子		中心频率
噪声调频干扰(NFM)	0.7～1.5		10～20 MHz
QPSK数字调频干扰	信息速率	信号带宽	中心频率
QPSK数字调频干扰	1 Mbit/s	1 MHz	10～20 MHz
样本数	每种干扰样式在每个JSR下分别生成500个样本，并且每个样本的干扰参数取值均服从给定参数范围内的均匀分布，其中训练集样本数:测试集样本数=4:1。

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表 2 干扰模式开集识别试验数据组合

试验数据组合序号	已知型干扰							未知型干扰
组合1	CW	MTJ	LFM	PBNJ	PPNJ	FHJ	SFM	NFM	QPSK
组合2	CW	MTJ	LFM	PBNJ	PPNJ	FHJ	NFM	SFM	QSPK
组合3	CW	MTJ	LFM	PBNJ	PPNJ	FHJ	QPSK	SFM	NFM
组合4	CW	MTJ	LFM	PBNJ	PPNJ	SFM	NFM	FHJ	QPSK
组合5	CW	MTJ	LFM	PBNJ	PPNJ	SFM	QPSK	FHJ	NFM
组合6	CW	MTJ	LFM	PBNJ	PPNJ	NFM	QPSK	FHJ	SFM

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表 3 不同分类方法的干扰模式开集识别整体性能对比(%)

分类方法	TNR	TPR(Recall)	Precision	F1-score
SVDD	89.4762	99.0748	97.0876	98.0628
OCSVM	88.4762	98.9932	96.8261	97.8820
余弦距离	80.1191	99.8708	94.6819	97.1910
元识别方法($ p\% = 99.9\% $)	92.1072	99.6123	97.8179	98.6988

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表 4 不同干扰模式开集识别算法整体性能对比(%)

参数	TNR	TPR(Recall)	Precision	F1-score
本文方法($ p\% = 99.9\% $)	92.1072	99.6123	97.8179	98.6988
本文方法($ p\% = 99.0\% $)	95.2738	98.5408	98.6626	98.5982
文献[15]方法	59.5714	99.9184	90.1224	94.6436
openmax方法	84.0238	99.7619	95.7828	97.6917

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表 5 已知型干扰与未知型干扰混合情况下该文方法的判决准确率(%)

本文方法	组合1	组合2	组合3	组合4	组合5	组合6	平均值
$ p\% = 99.9\% $	65.7143	66.5306	66.3265	69.7449	66.3265	58.9796	65.6037
$ p\% = 99.0\% $	79.9490	77.0918	77.6020	80.5102	75.9184	71.9388	77.1684

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