近距无线通信组网拓扑技术

doi:10.16180/j.cnki.issn1007-7820.2024.04.013

Abstract

Abstract:

In response to the new operational requirements of precision-guided weapons, this study focuses on wireless electrical design as the core technological direction and implements product modular design to address the challenges of flexible networking, resilience against destruction, and dynamic topology. The research adopts an Ad Hoc networking architecture, generalized coding, and passive multiple access techniques to achieve fast, flexible, and stable information exchange. By employing a hybrid routing design, the study divides the metal chamber network into subnets and applies proactive and reactive routing within the subnets, while introducing the concept of landmarks to mitigate the impact of multi-system communication. The specific approach involves predefining the timing and priority of all events, establishing a simplified event type library, and enabling node-to-node backup storage. Additionally, the use of boundary broadcasting protocols facilitates the rapid arrival of destination nodes at gateway nodes. The research findings confirm that the proposed solution meets the requirements of modular design for weapon functionality. Through wireless networking and routing protocol design, the capabilities of flexible networking, resilience against destruction, dynamic topology, and multi-system communication are successfully achieved.

Key words: close range wireless communication, wireless electrical, modularization, Ad Hoc network form, generalized encoding, passive multiple access, hybrid routing, multi standard communication

CLC Number:

YANG Jiayi, YAN Jun. Research on Network Topology Technology of Close Range Wireless Communication[J].Electronic Science and Technology, 2024, 37(4): 97-102.

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References 18

[1]	Necsulescu P, Schilling K. Automation of a multiple robot self-organizing multi-hop mobile ad-hoc networkusing signal strength[C]. Boston: Instrumentation and Measurement Technology Conference,IEEE, 2015:505-510.
[2]	张翠平, 卢宁宁, 张海鹏. 飞行器内部信息交互无缆化需求分析和体系构想[J]. 无线电工程, 2017, 47(8):9-13.
	Zhang Cuiping, Lu Ningning, Zhang Haipeng. Analysis and design on wireless internal information exchange in flight vehicle[J]. Radio Engineering, 2017, 47(8):9-13.
[3]	顾佳蓉. 面向密闭空间的多参数无线传感器网络[D]. 南京: 南京理工大学, 2015:15-40.
	Gu Jiarong. Multi parameter wireless sensor network for confined space[D]. Nanjing: Nanjing University of Science and Technology, 2015:15-40.
[4]	刘波, 费聚锋, 张恒, 等. 卫星舱内无线组网传输系统的设计与实现[J]. 科学技术与工程, 2017, 17(36):242-247.
	Liu Bo, Fei Jufeng, Zhang Heng, et al. Design and implementation of cabin wireless Ad Hoc communication system for satellite[J]. Science Technology and Engineering, 2017, 17(36):242-247.
[5]	韩秀红. 无源中继站在数字微波中的应用研究[J]. 中国新通信, 2019, 21(11):86-87.
	Han Xiuhong. Research on the application of passive relay stations in digital microwave[J]. China New Telecommunications, 2019, 21(11):86-87.
[6]	Mohapatra S, Kanungo P. Performance analysis of AODV,DSR,OLSR and DSDV routing protocols using NS2 simulator[J]. Procedia Engineering, 2012, 30(7):69-76. doi: 10.1016/j.proeng.2012.01.835
[7]	滑娟. 移动Ad Hoc网络路由协议研究和改进[J]. 电子技术与软件工程, 2013(13):36-36.
	Hua Juan. Research and improvement of mobile Ad Hoc network routing protocol[J]. Electronic Technology & Software Engineering, 2013(13):36-36.
[8]	陈汉元. Ad Hoc网络TORA路由协议的研究与改进[D]. 武汉: 湖北大学, 2013:12-37.
	Chen Hanyuan. Investigation on TORA routing protocol in Ad Hoc networks and its improvement[D]. Wuhan: Hubei University, 2013:12-37.
[9]	李凯, 左文成, 赵子文, 等. 星载5G小型化天线的设计与分析[J]. 电子科技, 2022, 35(11):7-12.
	Li Kai, Zuo Wencheng, Zhao Ziwen, et al. Design and analysis of spaceborne 5G miniaturized antenna[J]. Electronic Science and Technology, 2022, 35(11):7-12.
[10]	左文成, 赵子文, 徐至江, 等. 基于5G通信的空间站舱内电磁环境分析[J]. 电子科技, 2022, 35(10):1-7.
	Zuo Wencheng, Zhao Ziwen, Xu Zhijiang, et al. Analysis and research of electromagnetic environment in spacestation cabin based on 5G communication[J]. Electronic Science and Technology, 2022, 35(10):1-7.
[11]	缪鹏飞, 司圣平, 费飓峰. 卫星舱内无线传输技术的应用探索[J]. 上海航天(中英文), 2020, 37(5):86-91.
	Miao Pengfei, Si Shengping, Fei Jufeng. Application of wireless transmission technology in satellite cabin[J]. Aerospace Shanghai(Chinese & English), 2020, 37(5):86-91.
[12]	胡晓春, 白小平, 李纳. 一种高密度4G/5G无线组网容量模型研究及应用[J]. 移动通信, 2022, 46(9):51-57.
	Hu Xiaochun, Bai Xiaoping, Li Na. Research and application of a high-density 4G/5G wireless networking capacity model[J]. Mobile Communications, 2022, 46(9):51-57.
[13]	陈永朝, 邱世阳, 沈楚钦. 4G/5G干扰协同优化策略研究[J]. 湖南邮电职业技术学院学报, 2022, 21(2):9-11.
	Chen Yongchao, Qiu Shiyang, Shen Chuqin. Research on 4G/5G interference cooperative optimization strategy[J]. Journal of Hunan Post and Telecommunication College, 2022, 21(2):9-11.
[14]	方华建, 吕光宏. 基于无线Mesh网络的干扰感知型路由判据[J]. 电子科技, 2012, 25(10):97-100.
	Fang Huajian, Lv Guanghong. Interference-aware routing metrics based on the wireless Mesh network[J]. Electronic Science and Technology, 2012, 25(10):97-100.
[15]	梁东云. 一种GSM与WCDMA网的协同优化方法研究[J]. 电子测试, 2017, 23(1):64-65.
	Liang Dongyun. Research on a collaborative optimization method for GSM and WCDMA networks[J]. Electronic Test, 2017, 23(1):64-65.
[16]	蔡勇超, 赵振兴. 电力物联网安全无线组网方案研究及应用[J]. 电力信息与通信技术, 2021, 19(11):63-68.
	Cai Yongchao, Zhao Zhenxing. Research and application of the safe wireless networking scheme of power internet of things[J]. Electric Power Information and Communication Technology, 2021, 19(11):63-68.
[17]	闵全, 张格鹏, 考持盛. 无线组网通信技术研究[J]. 数字通信世界, 2021, 197(5):56-57,87.
	Min Quan, Zhang Gepeng, Kao Chisheng. Research on wireless network communication technology[J]. Digital Communication World, 2021, 197(5):56-57,87.
[18]	陈文杰, 宋宇鲲, 张多利. 基于改进QR算法的矩阵分解器设计[J]. 电子科技, 2022, 35(11):21-28.
	Chen Wenjie, Song Yukun, Zhang Duoli. Design of matrix decomposer based on improved QR algorithm[J]. Electronic Science and Technology, 2022, 35(11):21-28.

Research on Network Topology Technology of Close Range Wireless Communication

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