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基于深度学习的通信系统中安全能效的控制

邹翔宇 黄崇文 徐勇军 杨照辉 曹越

邹翔宇, 黄崇文, 徐勇军, 杨照辉, 曹越. 基于深度学习的通信系统中安全能效的控制[J]. 电子与信息学报, 2022, 44(7): 2245-2252. doi: 10.11999/JEIT211611
引用本文: 邹翔宇, 黄崇文, 徐勇军, 杨照辉, 曹越. 基于深度学习的通信系统中安全能效的控制[J]. 电子与信息学报, 2022, 44(7): 2245-2252. doi: 10.11999/JEIT211611
ZOU Xiangyu, HUANG Chongwen, XU Yongjun, YANG Zhaohui, CAO Yue. Secure Energy Efficiency in Communication Systems Based on Deep Learning[J]. Journal of Electronics & Information Technology, 2022, 44(7): 2245-2252. doi: 10.11999/JEIT211611
Citation: ZOU Xiangyu, HUANG Chongwen, XU Yongjun, YANG Zhaohui, CAO Yue. Secure Energy Efficiency in Communication Systems Based on Deep Learning[J]. Journal of Electronics & Information Technology, 2022, 44(7): 2245-2252. doi: 10.11999/JEIT211611

基于深度学习的通信系统中安全能效的控制

doi: 10.11999/JEIT211611
详细信息
    作者简介:

    邹翔宇:男,1995年生,博士生,研究方向为智能反射面、机器学习

    黄崇文:男,1988年生,教授,研究方向为智能反射面、机器学习

    徐勇军:男,1986年生,副教授,研究方向为智能反射面、机器学习

    杨照辉:男,1992年生,博士后,研究方向为智能反射面、联邦学习

    曹越:男,1984年生,教授,研究方向为智能电动车机器学习

    通讯作者:

    黄崇文 chongwenhuang@zju.edu.cn

  • 中图分类号: TN919.4

Secure Energy Efficiency in Communication Systems Based on Deep Learning

  • 摘要: 该文研究了基于可重构智能超表面(RIS)赋能的无线通信系统的安全传输问题。在研究的模型中,一个用户通过智能超表面连接到接入点,而窃听者窃听了从用户发送到基站的信号。因此,有必要设计一个合适的智能超表面反射向量来解决窃听问题。这个问题被表述为一个优化问题,其目标是通过共同优化智能超表面反射向量和智能超表面元件的数量来最大化安全能效,该安全能效定义为安全速率与系统总能耗的比值。这是一个非凸优化问题,传统方法是难以解决的。为了解决这个问题,提出了一种利用新兴的深度学习(DL)技术的新算法,以找到近似最优的智能超表面反射向量并确定近似最优的genie-aided反射元素数量。仿真结果表明,该方法达到了近似最优算法的最佳安全能效的96%。
  • 图  1  系统模型图

    图  2  多层感知器(MLP)网络

    图  3  室外射线跟踪场景“O1”

    图  4  基于不同RIS单元个数的DL算法与理想的算法的安全能量效率对比

    表  1  基于深度神经网络的DeepRIS(算法1)

     阶段(1):训练阶段
     for $s = 1$ to $S$ do //$s$个信道相干块,$s = 1,2, \cdots ,S$
     RIS系统获得信道状态描述符${\mathbf{h}}(s)$
     for $n = 1$ to $ \left| \mathcal{P} \right| $ do
     RIS基于$ {{\mathbf{\theta }}_n} $和RIS激活单元个数$ M $计算出对应的安全能量效率
     ${\eta _n}(s)$
     end for
     RIS构造安全能量效率向量$ {\mathbf{\eta }}(s) = \left[ {{\eta _1}(s),{\eta _2}(s), \cdots ,{\eta _{\left| \mathcal{P} \right|}}(s)} \right] $
     将所获得的数据添加到训练数据集$\mathcal{D} \leftarrow \left\langle {{\mathbf{h}}(s),{\mathbf{\eta }}(s)} \right\rangle $
     RIS使用最佳反射向量$ {{\mathbf{\theta }}_{{n^*}}} $($ {n^*} = \arg \mathop {\max }\limits_n {\eta _n}(s) $)传输数据
     end for
     使用训练数据集$\mathcal{D}$训练深度神经网络
     阶段(2):预测阶段
     while true do //针对每个信道相干块
     RIS系统获得信道状态描述符${\mathbf{h}}$
     RIS利用深度神经网络模型预测反射向量
     $ {{\mathbf{\theta }}_{{n^{{\text{D}}L}}}} $($ {n^{{\text{DL}}}} = \arg \mathop {\max }\limits_n {\hat \eta _n}(s) $)和激活的反射单元个数
     $ {M_{{\text{DL}}}} $($ {M_{{\text{DL}}}} = \arg \mathop {\max }\limits_M \hat \eta _{\max }^M(s) $)
     RIS使用最佳反射向量$ {{\mathbf{\theta }}_{{n^{{\text{D}}L}}}} $传输数据
     end while
    下载: 导出CSV

    表  2  系统及深度MIMO数据集参数

    Deep MIMO数据集参数数值
    基站编号(作为RIS)3
    作为发射器的用户从R1000到R1200的网格范围内
    作为AP的用户R850行,第90列
    作为Eve的用户R850行,第100列
    发射器(用户)/接收器(AP/Eve)天线数均为1
    BS天线(RIS单元)数8×8($ M = 64 $),10×10($ M = 100 $),
    12×12($ M = 144 $),14×14($ M = 196 $),
    16×16($ M = 256 $),18×18($ M = 324 $),
    20×20($ M = 400 $),22×22($ M = 484 $),
    24×24($ M = 576 $)
    系统带宽100 MHz
    OFDM子载波数256
    OFDM使用子载波数4
    OFDM采样系数1
    路径数1
    天线间距0.5
    天线单元增益3 dBi
    发射机天线发射功率35 dBm
    用户设备的噪声系数5 dB
    每个RIS单元的功率0.005W
    下载: 导出CSV
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出版历程
  • 收稿日期:  2021-12-30
  • 修回日期:  2022-06-05
  • 网络出版日期:  2022-06-07
  • 刊出日期:  2022-07-25

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