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车辆网络多平台卸载智能资源分配算法

王汝言 梁颖杰 崔亚平

王汝言, 梁颖杰, 崔亚平. 车辆网络多平台卸载智能资源分配算法[J]. 电子与信息学报, 2020, 42(1): 263-270. doi: 10.11999/JEIT190074
引用本文: 王汝言, 梁颖杰, 崔亚平. 车辆网络多平台卸载智能资源分配算法[J]. 电子与信息学报, 2020, 42(1): 263-270. doi: 10.11999/JEIT190074
Ruyan WANG, Yingjie LIANG, Yaping CUI. Intelligent Resource Allocation Algorithm for Multi-platform Offloading in Vehicular Networks[J]. Journal of Electronics & Information Technology, 2020, 42(1): 263-270. doi: 10.11999/JEIT190074
Citation: Ruyan WANG, Yingjie LIANG, Yaping CUI. Intelligent Resource Allocation Algorithm for Multi-platform Offloading in Vehicular Networks[J]. Journal of Electronics & Information Technology, 2020, 42(1): 263-270. doi: 10.11999/JEIT190074

车辆网络多平台卸载智能资源分配算法

doi: 10.11999/JEIT190074
基金项目: 国家自然科学基金(61801065, 61771082, 61871062),重庆市高校创新团队建设计划(CXTDX201601020)
详细信息
    作者简介:

    王汝言:男,1969年生,教授,主要研究方向为泛在网络、多媒体信息处理等

    梁颖杰:女,1994年生,硕士生,研究方向为车联网、移动边缘计算

    崔亚平:男,1986年生,讲师,研究方向为毫米波通信、多天线技术、车联网等

    通讯作者:

    梁颖杰 liangyj10111@163.com

  • 中图分类号: TN919.2

Intelligent Resource Allocation Algorithm for Multi-platform Offloading in Vehicular Networks

Funds: The National Natural Science Foundation of China (61801065, 61771082, 61871062), The Program for Innovation Team Building at Institutions of Higher Education in Chongqing (CXTDX201601020)
  • 摘要:

    为了降低计算任务的时延和系统的成本,移动边缘计算(MEC)被用于车辆网络,以进一步改善车辆服务。该文在考虑计算资源的情况下对车辆网络时延问题进行研究,提出一种多平台卸载智能资源分配算法,对计算资源进行分配,以提高下一代车辆网络的性能。该算法首先使用K临近(KNN)算法对计算任务的卸载平台(云计算、移动边缘计算、本地计算)进行选择,然后在考虑非本地计算资源分配和系统复杂性的情况下,使用强化学习方法,以有效解决使用移动边缘计算的车辆网络中的资源分配问题。仿真结果表明,与任务全部卸载到本地或MEC服务器等基准算法相比,提出的多平台卸载智能资源分配算法实现了时延成本的显著降低,平均可节省系统总成本达80%。

  • 图  1  网络模型

    图  2  总成本与距离关系图

    图  3  总成本与车辆数关系图

    图  4  总成本与车辆数及本地计算能力关系图

    图  5  总成本与任务数据大小关系图

     算法1 多平台卸载智能资源分配算法
     阶段1:初始化
        (1) 任务${R_i}$的最大延迟${\tau _{{R_i}}}$,任务大小${B_{{R_i}}}$;
        (2) 任务的当前位置$P = 1$;
        (3) ${{Q}}$矩阵,参数$\gamma $,奖赏矩阵${{R}}$;
        (4) 本地(l)、移动边缘计算(m)、云计算(c),各平台平 均延迟${\tau _1},{\tau _2},{\tau _3}$,允许最大任务大小${B_1},{B_2},{B_3}$。
     阶段2:选择任务卸载位置
       计算(${\tau _{{R_i}}},{B_{{R_i}}}$)和(${\tau _1},{B_1}$)的欧式距离$D$
       $D = \sqrt {{{({\tau _{{R_i}}} - {\tau _1})}^2} + {{({B_{{R_i}}} - {B_1})}^2}} ,P = 1$
       for j=2, 3 do
        计算(${\tau _{{R_i}}},{B_{{R_i}}}$)和(${\tau _j},{B_j}$)的欧式距离${d_j}$
        if ${d_j} < D$ then
         $D = {d_j},P = j$
        end if
       end for
       if P=1
        任务卸载到本地
        if P=2 or 3
        进行阶段3。
     阶段3:资源分配
      if P=3 then
       在云计算服务器中计算任务${R_i}$
     end if
     if P=2 then
       for 每次迭代 do
        随机选择一个状态${s_t}$
      for 每一步 do
        从状态${s_t}$的可能动作中随机选择动作$a$
        执行动作$a$,计算奖励$r$,进入下一状态$s'$
        计算
        $q(s,a) \leftarrow r(s,a) + \gamma \cdot \max [q(s',a')]$
        更新状态$s \leftarrow s'$
        until ${{Q}}$矩阵稳定
       end for
      end for
     end if
    下载: 导出CSV
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出版历程
  • 收稿日期:  2019-01-25
  • 修回日期:  2019-07-16
  • 网络出版日期:  2019-09-20
  • 刊出日期:  2020-01-21

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