In a hostile environment, interference identification plays an important role in protecting the authorized communication system and avoiding its performance degradation. In this paper, the interference identification problem for the frequency hopping communication system is discussed. Considering presence of multiple and compound interference in the frequency hopping system, in order to fully extracted effective features of the interferences from the received signals, a composite time-frequency analysis method based on both the linear and bilinear transform is proposed. The time-frequency spectrograms obtained from the time-frequency analysis are constructed as matching pairs and input into the deep neural network for identification. In particular, the Siamese neural network is adopted as the classifier to perform the interference identification. That is, the paired spectrograms are input into the two sub-networks of the Siamese neural network to extract the features of the paired spectrograms. The Siamese neural network is trained and tested by calculating the gap between the generated features, and the interference type identification is realized by the trained Siamese neural network. The simulation results confirm that the proposed algorithm can obtain higher identification accuracy than both traditional single time-frequency representation based approach and the AlexNet transfer learning or convolutional neural network based methods.
翻译:在敌对环境中,干扰识别在保护经授权的通信系统并避免其性能退化方面起着重要作用。在本文件中,讨论了频率选择通信系统的干扰识别问题。考虑到频率选择系统中存在多重和复合干扰,以便从收到的信号中充分提取干扰的有效特征,根据线性和双线性变异,提出了一个基于线性和双线性变异的综合时间频率分析方法。从时间-频率分析中获得的时间-频率光谱作为匹配配对和输入深神经网络以进行识别。特别是,将Siames神经网络用作进行干扰识别的分类器。这就是说,配对光谱是进入西亚线性神经网络的两个子网络以提取配对光谱图特征的输入。通过计算生成的特征之间的差距和通过经过培训的Siamese神经网络实现干扰类型识别的培训和测试。模拟结果证实,拟议的算法可以比传统的单一时间-频率网络代表法或亚历克斯网络的学习方法获得更高的识别准确性。