基于多模电台的SDMANET网络组网方法

doi:10.3969/j.issn.1006-2475.2020.08.013

计算机与现代化 ›› 2020, Vol. 0 ›› Issue (08): 82-88.doi: 10.3969/j.issn.1006-2475.2020.08.013

基于多模电台的SDMANET网络组网方法

(1.北京交通大学计算机与信息技术学院,北京100044；
2.北京交通大学交通数据分析与挖掘北京市重点实验室,北京100044)

收稿日期:2020-01-19 出版日期:2020-08-17 发布日期:2020-08-17
作者简介:戴松(1993-),男,江西九江人,硕士研究生,研究方向:软件定义网络,移动自组织网络,E-mail: daisong1860 @hotmail.com；孙延涛(1975-),男,副教授,博士,研究方向:软件定义网络,数据中心网络,E-mail: ytsun@bjtu.edu.cn；刘强(1980-),男,副教授，博士，研究方向:移动与互联网络,E-mail: liuq@bjtu.edu.cn。
基金资助:
中央高校基本科研业务费专项资金资助项目（K17JB00460）

Networking Method for SDMANET Based on Multi-mode Radio

(1. School of Computer and Information Technology, Beijing Jiaotong University, Beijing 100044, China;
2. Beijing Key Lab of Traffic Data Analysis and Minding, Beijing Jiaotong University, Beijing 100044, China)

Received:2020-01-19 Online:2020-08-17 Published:2020-08-17

摘要/Abstract

摘要： 软件定义网络（SDN）在有线网络和数据中心网络等多种网络场景中正在快速发展，然而在移动自组织网络（MANET）中SDN的使用仍然处于起步阶段。因MANET网络拓扑变化频繁、资源受限以及采用分布式组网方式等特点使得在其中应用SDN变得具有挑战性。为此，本文提出一种基于多模电台的软件定义移动自组织网络（SDMANET）组网方法。该方法使用支配集算法计算骨干节点，仅由骨干节点使用带外信道和SDN控制器通信，并在MAC层基于骨干节点进行TDMA时隙动态分配。实验结果表明，与OLSR协议和直接带外控制的SDN方法相比，本方法具有更低的网络控制开销和信道访问时延，在大规模MANET网络中性能较好。

关键词: 移动组织网络, 软件定义网络, 多模电台, 骨干网, 动态时隙分配

Abstract: Software-defined networking (SDN) is developing rapidly in a variety of network scenarios, including wired networks and data center networks. However, the use of SDN in Mobile Ad Hoc Networks (MANET) is still in its infancy. Due to the frequent topology changes, limited resources, and the use of distributed networking in MANET networks, applying SDN in MANET becomes more challenging. To this end, this paper proposes a Software-defined Mobile Ad Hoc Networks （SDMANET） networking method based on multi-mode radios. This method uses the dominating set algorithm to calculate the backbone nodes. The backbone nodes use out-of-band channels to communicate with the SDN controller, and perform dynamical allocation of TDMA time slots based on the backbone nodes at the MAC layer. Experimental results show that compared with OLSR protocol and direct out-of-band control method, this method has lower network control overhead and channel access delay, and has better performance in large-scale MANET networks.

Key words: mobile Ad Hoc networks (MANET), software-defined network (SDN), multi-mode radio, backbone network, dynamic slot allocation

中图分类号:

TP393.02

戴松, 孙延涛, 刘强, 贾泽群, . 基于多模电台的SDMANET网络组网方法[J]. 计算机与现代化, 2020, 0(08): 82-88.

DAI Song, SUN Yan-tao, LIU Qiang, JIA Ze-qun, . Networking Method for SDMANET Based on Multi-mode Radio[J]. Computer and Modernization, 2020, 0(08): 82-88.

参考文献

［1］ ROY R R. Handbook of Mobile Ad Hoc Networks for Mobility Models［M］. Springer Science & Business Media, 2010.
［2］ POULARAKIS K， IOSIFIDIS G， TASSIULAS L. SDN enabled tactical Ad Hoc networks: Extending programmable control to the edge［J］. IEEE Communications Magazine, 2018,56(7):132-138.
［3］ LIORET J, SHU L, LACUESTA R, et al. User-oriented and service-oriented spontaneous Ad Hoc and sensor wireless network［J］. Ad Hoc and Sensor Wireless Networks, 2012,14(1):1-8.
［4］ BELLAVISTA P, CORRADI A, GIANNELLI C. Middleware-layer quality-aware collaborative recasting of live multimedia in multi-hop spontaneous networks［J］. Journal of Network and Systems Management, 2015,23(3):620-649.
［5］ GIANNELLI C, BELLAVISTA P, SCOTECE D. Softwaredefined networking for quality-aware management of multi-hop spontaneous networks［C］// International Conference on Computing, Networking and Communications. 2018:561-566.
［6］ BELLAVISTA P, DOLCI A, GIANNELLI C. MANET-oriented SDN: Motivations, challenges, and a solution prototype［C］// The 19th International Symposium on “A World of Wireless, Mobile and Multimedia Networks”. 2018:14-22.
［7］ POULARAKIS K, QIN Q F, MARCUS K M, et al. Hybrid SDN control in mobile Ad Hoc networks［C］// International Conference on Smart Computing (SMA-RTCOMP). 2019:110-114.
［8］ HAQUE I, ABU-GHAZALEH N. Wireless software defined networking: A survey and taxonomy［J］. IEEE Communications Surveys & Tutorials, 2016,18(4):2713-2737.
［9］ ABOLHASAN M, LIPMAN J, NI W, et al. Software-defined wireless networking: Centralized, distributed, or hybrid［J］. IEEE Network, 2015,29(4):32-38.
［10］DUSIA A, MISHRA V, SETHI A. Control communication in SDN-based dynamic multi-hop wireless infrastructure-less networks［C］// International Conference on Advanced Networks and Telecommunications Systems. 2018:1-6.
［11］DUSIA A, RAMANATHAN R, SETHI A. CORR: Centralized opportunistic reactive routing for mobile multi-hop wireless networks［C］// The 28th International Conference on Computer Communication and Networks. 2019:1-6.
［12］WANG J F, MIAO Y M, ZHOU P, et al. A software defined network routing in wireless multi-hop network［J］. Journal of Network and Computer Applications， 2016,85(C):76-83．
［13］YU H C, QUER G, RAO R R. Wireless SDN mobile Ad Hoc network: From theory to practice［C］// IEEE International Conference on Communications. 2017:1-7.
［14］DETTI A, PISA C, SALSANO S, et al. Wireless mesh software defined networks (wmSDN)［C］// 2013 IEEE 9th International Conference on Wireless and Mobile Computing, Networking and Communications. 2013:89-95.
［15］CLAUSEN T, JACQUET P.RFC 3626: Optimized Link State Routing Protocol (OLSR)［S］. United States: RFC Editor, 2003.
［16］ DEGANTE A, ASLAN M, MATRAWY A. Smart wireless sensor network management based on software-defined networking［C］// 2014 27th Biennial Symposium on Communications. 2014:71-75.
［17］LI H, DONG M X, OTA K. Control plane optimization in software-defined vehicular Ad Hoc networks［J］. IEEE Transactions on Vehicular Technology, 2016,65(10):7895-7904.
［18］ZHU M, CAO J N, PANG D M, et al. SDN-based routing for efficient message propagation in VANET［C］// International Conference on Wireless Algorithms, Systems, and Applications. 2015:788-797.
［19］HE Z J, CAO J N, LIU X F. SDVN: Enabling rapid network innovation for heterogeneous vehicular communication［J］. IEEE Network, 2016,30(4):10-15.
［20］MCKEOWN N, TOM A, BALAKRISHNAN H, et al. OpenFlow: Enabling innovation in campus networks［J］. ACM SIGCOMM Computer Communication Review, 2008,38(2):69-74.
［21］STOJMENOVIC I, SEDDIGH M, ZUNIC J. Dominating sets and neighbor elimination-based broadcasting algorithms in wireless networks［J］. IEEE Transactions on Parallel and Distributed Systems, 2002,13(1):14-25.
［22］BHATTACHARJEE S, TRIPATHI J, MISTRY O, et al. Distributed algorithm for power aware connected dominating set for efficient routing in mobile Ad Hoc networks［C］// International Symposium on Ad Hoc and Ubiquitous Computing. 2006:13-23.
［23］ASADOLLAHI S, GOSWAMI B, SAMEER M. Ryu controllers scalability experiment on software defined networks［C］// 2018 IEEE International Conference on Current Trends in Advanced Computing. 2018:1-5.

[1]	肖军弼, 邱艺. 基于状态感知数据平面的SDN故障检测与恢复方案[J]. 计算机与现代化, 2024, 0(12): 116-123.
[2]	陈晨, 庄毅, 高增. QoE驱动的SDN网络高可用传输框架[J]. 计算机与现代化, 2023, 0(11): 62-68.
[3]	王重阳, 庄毅. 基于SDN和改进CSA算法的多作业集群的负载均衡算法[J]. 计算机与现代化, 2023, 0(11): 28-35.
[4]	姜厚海, 庄毅, 曹子宁. 一种基于流聚合与拥塞避免的SDN快速故障恢复方案[J]. 计算机与现代化, 2023, 0(10): 77-83.
[5]	姜厚海, 庄毅, 曹子宁. 一种基于改进BDD的SDN可靠性评估算法[J]. 计算机与现代化, 2023, 0(09): 64-69.
[6]	雷依翰, 曹利峰, 韩孟达, 韩雪. 软件定义天地一体化网络安全切换架构与方法[J]. 计算机与现代化, 2023, 0(08): 119-126.
[7]	高枫, 庄毅, 刘骁. 一种基于路径跟踪反馈的SDN网络可信传输方案[J]. 计算机与现代化, 2022, 0(12): 102-110.
[8]	包春晖, 庄毅, 郭黎烨. 面向服务传输的SDN移动网络脆弱性评估模型[J]. 计算机与现代化, 2022, 0(11): 43-51.
[9]	凌致远, 陈晓, 宋磊, . 基于匹配动作表模型的可编程数据平面流表归并[J]. 计算机与现代化, 2022, 0(07): 74-78.
[10]	王文蔚, 肖军弼, 程鹏, 张悦. 基于SDN的DDoS攻击防御系统[J]. 计算机与现代化, 2021, 0(02): 117-121.
[11]	肖军弼, 程鹏, 谭立状, 孟祥泽. 基于SDN的数据中心动态优先级多路径调度算法[J]. 计算机与现代化, 2020, 0(07): 21-26.
[12]	耿岚岚1，孙延涛2，戴松1. 一种面向软件定义移动自组网的拓扑发现方法[J]. 计算机与现代化, 2019, 0(09): 53-.
[13]	詹晗. 基于OpenStack的分布式SDN控制器Dragonflow研究[J]. 计算机与现代化, 2017, 0(7): 91-94.
[14]	印苏凯1,刘光杰1,刘伟伟1,翟江涛2,戴跃伟1,2. 软件定义网络中的多流时间式隐信道设计[J]. 计算机与现代化, 2017, 0(4): 94-98,104.
[15]	庄怀东，杜庆伟. 一种基于SDN的数据中心网络动态流量调度方法[J]. 计算机与现代化, 2016, 251(07): 80-86.

基于多模电台的SDMANET网络组网方法

Networking Method for SDMANET Based on Multi-mode Radio

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价