Shared-aperture Jammer Assisted Covert Communication Using Time Modulated Array
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摘要: 该文首次研究了基于时间调制阵列(TMA)的共孔径干扰辅助短包隐蔽通信。首先提出并设计了共口径干扰的TMA架构,提出一种优化方法,能够在最大化目标方向信号增益的同时对非目标方向形成干扰。基于上述模型,推导出隐蔽性约束和隐蔽吞吐量的闭合表达式。在此基础上,该文进一步对发送功率和数据包长进行联合优化,以最大化隐蔽吞吐量。仿真结果表明,存在一个使隐蔽吞吐量最大化的最优包长,所提方案相比基准方案实现了更好的隐蔽通信性能。Abstract: The short packet covert communication using a shared-aperture jammer assisted Time-Modulated Array (TMA) is investigated for the first time in this paper. Firstly, a TMA architecture for shared-aperture jammer is proposed and an optimization method is introduced that maximizes the gain of the target direction while forming interference in non-target directions. Based on this model, closed-form expressions for the covertness constraint and covert throughput are derived. Furthermore, the transmission power and blocklength are optimized to maximize the covert throughput. Simulation results show that there exists an optimum blocklength that maximizes the covert throughput, and the proposed scheme outperforms the benchmark scheme in terms of covert communication performance.
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1 基于CS算法的TMA方向图优化程序
初始化:使用随机实数来生成s个巢穴的初始种群$ {x_i} $(i = 1, 2, ···,
S),其中$ {x_i} $表示切换序列。适应度计算:将每个宿主巢穴代入适合度函数$ {f_i} $,计算适合度值。 当t<K时:通过Lévy飞行随机选择一个巢穴,并评估其适应度值; 随机选择一个巢; 如果$ {f_i} > {f_j} $,则用新解代替j; 一部分($ P \in \left[ {0,1} \right] $)较差的巢被放弃,并建立新的巢; 保留最佳解决方案; 对解决方案进行排序,找出当前最佳解决方案; 得到最优的开关序列。 结束 
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表 1 仿真参数设置
天线数 迭代次数 谐波级数 巢数 信号旁瓣 干扰旁瓣 Bob方向 Willie方向 信道编码速率 M=12 K=1 000 h=1 S=25 –40 dB –25 dB –20° –5° R=0.1 BPCU dab daw dbw 总发射功率 噪声功率 路径衰减 最大包长 最小包长 40 m 10 m 10 m P=–20 dBm σ2=–80 dBm α=3 Nmax=800 Nmin=100
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