支持差异化可协商的数据通信机制

寇文龙; 李凤华; 董秀则; 曹晓刚; 耿魁; 李青

doi:10.11959/j.issn.1000-436x.2021183

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支持差异化可协商的数据通信机制

学术论文 | 更新时间：2024-06-05

- 支持差异化可协商的数据通信机制
- Differentiated and negotiable mechanism for data communication
- 通信学报 2021年42卷第10期页码：55-66
- 作者机构：
  
  1. 西安电子科技大学网络与信息安全学院，陕西西安 710071
  2. 中国科学院信息工程研究所，北京100093
  3. 中国科学院大学网络空间安全学院，北京 100049
  4. 北京电子科技学院电子通信工程系，北京 100070
  5. 中国电信股份有限公司研究院，北京 100033
- 作者简介：
  
  [ "寇文龙（1990- ），男，河南许昌人，西安电子科技大学博士生，主要研究方向为信息安全" ]
  [ "李凤华（1966- ），男，湖北浠水人，博士，中国科学院信息工程研究所研究员、博士生导师，主要研究方向为网络与系统安全、信息保护、隐私计算" ]
  [ "董秀则（1976- ），男，山东莒县人，北京电子科技学院副教授，主要研究方向为信息安全、密码工程" ]
  [ "曹晓刚（1996- ），男，河北邢台人，中国科学院信息工程研究所博士生，主要研究方向为信息安全" ]
  [ "耿魁（1989- ），男，湖北红安人，博士，中国科学院信息工程研究所高级工程师、硕士生导师，主要研究方向为网络安全、信息保护" ]
  [ "李青（1973- ），男，陕西宝鸡人，中国电信股份有限公司研究院高级工程师，主要研究方向为电信增值业务平台及产品开发、网络演进、云计算/大数据等运营技术" ]
- 基金信息：
  
  国家重点研发计划基金资助项目;The National Key Research and Development Program of China(2017YFB0801802)
- DOI：10.11959/j.issn.1000-436x.2021183
  中图分类号： TN92
- 网络出版日期：2021-10，
  
  纸质出版日期：2021-10-25
- 稿件说明：
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寇文龙, 李凤华, 董秀则, 等. 支持差异化可协商的数据通信机制[J]. 通信学报, 2021,42(10):55-66.

Wenlong KOU, Fenghua LI, Xiuze DONG, et al. Differentiated and negotiable mechanism for data communication[J]. Journal on communications, 2021, 42(10): 55-66.
寇文龙, 李凤华, 董秀则, 等. 支持差异化可协商的数据通信机制[J]. 通信学报, 2021,42(10):55-66. DOI： 10.11959/j.issn.1000-436x.2021183.

Wenlong KOU, Fenghua LI, Xiuze DONG, et al. Differentiated and negotiable mechanism for data communication[J]. Journal on communications, 2021, 42(10): 55-66. DOI： 10.11959/j.issn.1000-436x.2021183.

摘要

针对云环境和物联网中存在海量、差异化的计算单元和终端设备，硬件资源和运算能力的差异对高可靠高性能的数据通信提出了新的挑战这一问题，提出了支持差异化可协商的数据通信机制。提出参数协商方法，发送端根据接收端能力不同进行参数协商，实现差异化、可协商的数据通信；设计重传反馈机制，发送端通过接收端反馈的数据接收情况动态调整发送速率和重传数据，提高通信效率和可靠性。实验结果表明，所提机制能够根据接收端能力差异，进行动态自适应、高效、并行通信。

Abstract

In view of the massive and differentiated computing units and terminal devices in the cloud environment and the Internet of things

the differences in hardware resources and computing capabilities posed new challenges to high reliability and high performance data communication

a data communication mechanism supporting differentiation and negotiation was proposed.A parameters negotiation method was proposed

and parameters were negotiated by the sender according to the difference of the receiver capability to achieve differentiated and negotiable data communication.A retransmission feedback mechanism was designed

and the transmission rate was dynamically adjusted and the data was retransmitted based on the data reception feedback of the receiver by the sender to improve communication efficiency and reliability.The experimental results show that the proposed mechanism can perform dynamic adaptive

efficient and parallel communication according to the difference of the receiver capability.

关键词

Keywords

references

ZHOU Y Q , LIU L , WANG L , et al . Service-aware 6G:an intelligent and open network based on the convergence of communication,computing and caching [J ] . Digital Communications and Networks , 2020 , 6 ( 3 ): 253 - 260 .

AL-SARAWI S , ANBAR M , ALIEYAN K , et al . Internet of things (IoT) communication protocols [C ] // Proceedings of 2017 8th International Conference on Information Technology (ICIT) . Piscataway:IEEE Press , 2017 : 685 - 690 .

CHAI L , REINE R . Performance of UDP-lite for IoT network [J ] . IOP Conference Series:Materials Science and Engineering , 2019 , 495 : 012038

DIZDAREVIC J , CARPIO F , JUKAN A , et al . A survey of communication protocols for Internet of things and related challenges of fog and cloud computing integration [J ] . ACM Computing Surveys , 2019 , 51 ( 6 ): 1 - 29 .

ZHOU Y Q , TIAN L , LIU L , et al . Fog computing enabled future mobile communication networks:a convergence of communication and computing [J ] . IEEE Communications Magazine , 2019 , 57 ( 5 ): 20 - 27 .

SASAKI Y , YOKOTANI T . Performance evaluation of MQTT as a communication protocol for IoT and prototyping [J ] . Advances in Technology Innovation , 2019 , 4 ( 1 ): 21 - 29 .

王伟杭 , 任勇毛 , 唐明洁 , 等 . 终端性能自适应传输协议 [J ] . 软件学报 , 2010 , 21 ( 7 ): 1635 - 1645 .

WANG W H , REN Y M , TANG M J , et al . End-system performance aware transport protocols [J ] . Journal of Software , 2010 , 21 ( 7 ): 1635 - 1645 .

FAIRHURST G , TRAMMELL B , KUEHLEWIND M . Services provided by IETF transport protocols and congestion control mechanisms [R ] . RFC Editor , 2017 .

AL-DHIEF F T , SABRI N , LATIFF N M A , et al . Performance comparison between TCP and UDP protocols in different simulation scenarios [J ] . International Journal of Engineering ＆ Technology , 2018 , 7 ( 4 ): 172 - 176 .

WHEEB A H . Performance evaluation of UDP,DCCP,SCTP and TFRC for different traffic flow in wired networks [J ] . International Journal of Electrical and Computer Engineering , 2017 , 7 ( 6 ): 3552 .

HE E , LEIGH J , YU O , et al . Reliable blast UDP:predictable high performance bulk data transfer [C ] // Proceedings of IEEE International Conference on Cluster Computing . Piscataway:IEEE Press , 2002 : 317 - 324 .

KACHAN D , SIEMENS E . Comparison of contemporary protocols for high-speed data transport via 10 Gbps WAN connections [C ] // Proceedings of the 2nd International Conference on Applied Innovations in IT . Berlin:Springer , 2014 : 21 - 27 .

MEISS M R . Tsunami:a high-speed rate-controlled protocol for file transfer [R ] . Indiana University , 2004 .

SYZOV D , KACHAN D , SIEMENS E . High-speed UDP data transmission with multithreading and automatic resource allocation [C ] // Proceedings of the 4th International Conference on Applied Innovations in IT . Berlin:Springer , 2016 : 51 - 55 .

LUO Q , WANG J F . FRUDP:a reliable data transport protocol for aeronautical ad hoc networks [J ] . IEEE Journal on Selected Areas in Communications , 2018 , 36 ( 2 ): 257 - 267 .

ZHENG Z G , SANGAIAH A K , WANG T . Adaptive communication protocols in flying ad hoc network [J ] . IEEE Communications Magazine , 2018 , 56 ( 1 ): 136 - 142 .

NASSER B , RABANI A , FREILING D , et al . An adaptive telerobotics control for advanced manufacturing [C ] // Proceedings of 2018 NASA/ESA Conference on Adaptive Hardware and Systems . Piscataway:IEEE Press , 2018 : 82 - 89 .

陈波 , 陶威 , 王运明 . 基于ARUDP的指挥控制网络数据传输协议 [J ] . 火力与指挥控制 , 2016 , 41 ( 4 ): 157 - 160 .

CHEN B , TAO W , WANG Y M . Command and control network data transmission protocol based on ARUDP [J ] . Fire Control ＆ Command Control , 2016 , 41 ( 4 ): 157 - 160 .

CHRISTENSEN M J , RICHTER T . Achieving reliable UDP transmission at 10 GB/s using BSD socket for data acquisition systems [J ] . Journal of Instrumentation , 2020 , 15 ( 9 ): T09005 .

ZHANG X , GU N J , SU J J . DCUDP:scalable data transfer for high-speed long-distance networks [J ] . Concurrency and Computation:Practice and Experience , 2017 , 29 ( 4 ): e3846 .

张旭 . 面向网络服务的传输协议设计与任务调度优化 [D ] . 合肥:中国科学技术大学 , 2017 .

ZHANG X . Transfer protocol design and task scheduling optimization on network service system [D ] . Hefei:University of Science and Technology of China , 2017 .

GU Y H , GROSSMAN R L . UDT:UDP-based data transfer for high-speed wide area networks [J ] . Computer Networks , 2007 , 51 ( 7 ): 1777 - 1799 .

ECKART B , HE X B , WU Q S . Performance adaptive UDP for high-speed bulk data transfer over dedicated links [C ] // Proceedings of 2008 IEEE International Symposium on Parallel and Distributed Processing . Piscataway:IEEE Press , 2008 : 1 - 10 .

SIDLER D , ALONSO G , BLOTT M , et al . Scalable 10Gbps TCP/IP stack architecture for reconfigurable hardware [C ] // Proceedings of 2015 IEEE 23rd Annual International Symposium on Field-Programmable Custom Computing Machines . Piscataway:IEEE Press , 2015 : 36 - 43 .

SIDLER D , ISTVÁN Z ,, ALONSO G . Low-latency TCP/IP stack for data center applications [C ] // Proceedings of 2016 26th International Conference on Field Programmable Logic and Applications . Piscataway:IEEE Press , 2016 : 1 - 4 .

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