{"title":"AI-Enabled Compressive Spectrum Classification for Wideband Radios","authors":"Tassadaq Nawaz, Ramasamy Srinivasaga Naidu","doi":"10.3390/technologies11060182","DOIUrl":null,"url":null,"abstract":"Cognitive radio is a promising technology that emerged as a potential solution to the spectrum shortage problem by enabling opportunistic spectrum access. In many cases, cognitive radios are required to sense a wide range of frequencies to locate the spectrum white spaces; hence, wideband spectrum comes into play, which is also an essential step in future wireless systems to boost the throughput. Cognitive radios are intelligent devices and therefore can be opted for the development of modern jamming and anti-jamming solutions. To this end, our article introduces a novel AI-enabled energy-efficient and robust technique for wideband radio spectrum characterization. Our work considers a wideband radio spectrum made up of numerous narrowband signals, which could be normal communications or signals disrupted by a stealthy jammer. First, the receiver recovers the wideband from significantly low sub-Nyquist rate samples by exploiting compressive sensing technique to decrease the overhead caused by the high complexity analog-to-digital conversion process. Once the wideband is recovered, each available narrowband signal is given to a cyclostationary feature detector that computes the corresponding spectral correlation function and extracts the feature vectors in the form of cycle and frequency profiles. Then profiles are concatenated and given as input features set to an artificial neural network which in turn classifies each NB signal as legitimate communication with a specific modulation or disrupted by a stealthy jammer. The results show a classification accuracy of about 0.99 is achieved. Moreover, the algorithm highlights significantly high performances in comparison to recently reported spectrum classification techniques. The proposed technique can be used to design anti-jamming systems for military communication systems.","PeriodicalId":22341,"journal":{"name":"Technologies","volume":"23 2","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2023-12-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Technologies","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3390/technologies11060182","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Cognitive radio is a promising technology that emerged as a potential solution to the spectrum shortage problem by enabling opportunistic spectrum access. In many cases, cognitive radios are required to sense a wide range of frequencies to locate the spectrum white spaces; hence, wideband spectrum comes into play, which is also an essential step in future wireless systems to boost the throughput. Cognitive radios are intelligent devices and therefore can be opted for the development of modern jamming and anti-jamming solutions. To this end, our article introduces a novel AI-enabled energy-efficient and robust technique for wideband radio spectrum characterization. Our work considers a wideband radio spectrum made up of numerous narrowband signals, which could be normal communications or signals disrupted by a stealthy jammer. First, the receiver recovers the wideband from significantly low sub-Nyquist rate samples by exploiting compressive sensing technique to decrease the overhead caused by the high complexity analog-to-digital conversion process. Once the wideband is recovered, each available narrowband signal is given to a cyclostationary feature detector that computes the corresponding spectral correlation function and extracts the feature vectors in the form of cycle and frequency profiles. Then profiles are concatenated and given as input features set to an artificial neural network which in turn classifies each NB signal as legitimate communication with a specific modulation or disrupted by a stealthy jammer. The results show a classification accuracy of about 0.99 is achieved. Moreover, the algorithm highlights significantly high performances in comparison to recently reported spectrum classification techniques. The proposed technique can be used to design anti-jamming systems for military communication systems.
认知无线电是一种前景广阔的技术,它通过实现机会性频谱接入,成为解决频谱短缺问题的潜在方案。在许多情况下,认知无线电需要感知大范围的频率来定位频谱白区;因此,宽带频谱开始发挥作用,这也是未来无线系统提高吞吐量的必要步骤。认知无线电是一种智能设备,因此可用于开发现代干扰和反干扰解决方案。为此,我们的文章介绍了一种新颖的人工智能节能稳健技术,用于宽带无线电频谱表征。我们的工作考虑了由无数窄带信号组成的宽带无线电频谱,这些信号可能是正常通信,也可能是被隐形干扰器破坏的信号。首先,接收器利用压缩传感技术,从明显低于奈奎斯特速率的采样中恢复宽带,以减少高复杂度模数转换过程造成的开销。一旦恢复了宽带,每个可用的窄带信号都会交给一个周期静态特征检测器,该检测器会计算相应的频谱相关函数,并以周期和频率剖面的形式提取特征向量。然后将剖面图串联起来,作为人工神经网络的输入特征集,再由人工神经网络将每个 NB 信号分类为采用特定调制方式的合法通信或被隐形干扰器破坏的通信。结果显示,分类准确率约为 0.99。此外,与最近报道的频谱分类技术相比,该算法的性能显著提高。所提出的技术可用于设计军事通信系统的抗干扰系统。