电子引信无线装定技术应用研究

doi:10.16180/j.cnki.issn1007-7820.2023.06.009

Abstract

Abstract:

Modern war requires weapons to have a higher degree of environmental adaptability and more accurate guidance ability. As the core control component of guided weapons, the rapid response ability of electronic fuze and accurate control ability are not only closely related to the performance of weapons but also an important factor affecting the striking ability of weapons. Wireless setting technology is one of the core technologies of precision-guided weapons. Compared with the traditional wired setting technology, wireless setting technology has the characteristics of non-contact, fast setting speed, and strong adaptability. Quickly and stably transmitting the control information to the electronic fuse through wireless setting technology is one of the key technologies for the development of intelligent ammunition in the future. Principles of different wireless setting technologies, the causes of wireless setting technology are analyzed, and the necessity of wireless setting technology research is obtained. This study summarizes the key technologies and characteristics of three main wireless installation methods, electromagnetic induction installation, RF installation, and magnetic coupling resonance installation, and looks forward to the future development trend of wireless installation technology.

Key words: wireless setting, electronic fuse, time fuse, electromagnetic induction, radio frequency, magnetic coupling resonance, burst point control, communication technology

CLC Number:

TN919

ZHANG Mingyue,FANG Liqing,GUO Deqing,SHI Yonglei,LIU Bingnan. Application Research on Wireless Setting Technology of Electronic Fuze[J].Electronic Science and Technology, 2023, 36(6): 57-63.

Figures/Tables 7

Figure 1.

Figure 2.

Figure 3.

Table 1.

Figure 4.

Figure 5.

Figure 6.

References 22

[1]	张涛, 国伟, 苏子舟, 等. 基于磁场方向变化的同步感应线圈发射器效率提升分析[J]. 电工技术学报, 2021, 36(3):517-524.
	Zhang Tao, Guo Wei, Su Zizhou, et al. Analysis of improving efficiency on synchronous induction coilgun based on the directional change of magnetic field[J]. Transactions of China Electrotechnical Society, 2021, 36(3):517-524.
[2]	胡德福. 金属管内磁共振耦合无线装定技术研究[D]. 南京: 南京理工大学, 2019:26-45.
	Hu Defu. Research on wireless installation technology of magnetic resonance coupling in metal tube[D]. Nanjing: Nanjing University of Technology, 2019:26-45.
[3]	裘添烨. 基于有线无线复合的装定技术研究[D]. 南京: 南京理工大学, 2018:45-55.
	Qiu Tianye. Research on installation technology based on wired and wireless composite[D]. Nanjing: Nanjing University of Technology, 2018:45-55.
[4]	罗浩. 感应装定系统中FPGA的应用与研究[D]. 太原: 中北大学, 2020:34-40.
	Luo Hao. Application and research of FPGA in induction setting system[D]. Taiyuan: Zhongbei University, 2020:34-40.
[5]	吴向臣, 吴茂林, 刘玉. 基于近场通信技术的引信感应装定方法[J]. 探测与控制学报, 2016, 38(3):29-31.
	Wu Xiangchen, Wu Maolin, Liu Yu. Research on NFC technology application in fuze induction setting[J]. Journal of Detection and Control, 2016, 38(3):29-31.
[6]	李含健, 薛连莉, 周栋, 等. 2019年精确制导武器战斗部和引信技术发展综述[J]. 飞航导弹, 2020(1):41-45.
	Li Hanjian, Xue Lianli, Zhou Dong, et al. Summary of the development of warhead and fuze technology of precision guided weapons in 2019[J]. Aeronautical Missile Journal, 2020(1):41-45.
[7]	刘肖肖, 李鹏, 陈以安. 基于电磁感应技术的弹道修正装定系统仿真分析[J]. 电子测量技术, 2020, 43(17):7-11.
	Liu Xiaoxiao, Li Peng, Chen Yian. Simulation analysis of ballistic correction setting system based on electromagnetic induction technology[J]. Electronic Measurement Technology, 2020, 43(17):7-11.
[8]	Mao B Q, Lan T, Deng W. Simulation of magnetic field penetration of cylindrical cavity with wound solenoid[C]. Xiamen: Proceedings of the International Conference on Modeling, Simulation and Optimization Technologies and Applications, 2016:174-176.
[9]	刘党丽. 基于射频识别的感应装定技术[D]. 太原: 中北大学, 2021:18-65.
	Liu Dangli. Induction setting technology based on RFID[D]. Taiyuan: Zhongbei University, 2021:18-65.
[10]	李龙坤. 引信信息射频装定技术[D]. 太原: 中北大学, 2014:21-45.
	Li Longkun. Fuze information RF setting technology[D]. Taiyuan: Zhongbei University, 2014:21-45.
[11]	郎需强, 陈曦, 王伟, 等. 基于独特码的无源射频装定系统研究[J]. 兵工学报, 2016, 37(S2):29-35.
	Lang Xuqiang, Chen Xi, Wang Wei, et al. Research on passive RF setting system based on unique code[J]. Acta Armamentarii, 2016, 37(S2):29-35.
[12]	余燕文. 基于RFID的非接触式引信感应装定系统[J]. 水雷战与舰船防护, 2015, 23(4):62-65.
	Yu Yanwen. Design of contactless fuse's inductive setting system based on RFID[J]. Mine Warfare and Ship Self-Defence, 2015, 23(4):62-65.
[13]	Malioutov D, Cetin M, Willsky A S. A sparse signal reconstruction perspective for source localization with sensor arrays[J]. IEEE Transactions on Signal Process, 2005, 53(8):3010-3022. doi: 10.1109/TSP.2005.850882
[14]	Realan M A, Strohmer T. General deviants: An analysis of perturbations in compressed sensing[J]. IEEE Journal of Selected Topics in Signal Process, 2010, 4(2):342-349. doi: 10.1109/JSTSP.2009.2039170
[15]	Sun L Z, Ma D G, Tang H J. A review of recent trends in wireless power transfer technology and its applications in electric vehicle wireless charging[J]. Renewable and Sustainable Energy Reviews, 2018, 91(4):490-503. doi: 10.1016/j.rser.2018.04.016
[16]	雷雯, 栗敬雨. 基于四路ADC芯片交替采样的宽带信号采集系统设计[J]. 电子科技, 2021, 34(9):30-35.
	Lei Wen, Li Jingyu. Design of a sampling system based on four-channel ADC chip time-interleaved sampling[J]. Electronic Science and Technology, 2021, 34(9):30-35.
[17]	李炜昕, 张合, 丁立波, 等. 磁耦合共振引信装定信息的双向传输技术[J]. 火力与指挥控制, 2014, 39(7):89-92.
	Li Weixin, Zhang He, Ding Libo, et al. Bidirectional transmission technology of magnetic coupling resonance fuze setting information[J]. Fire and Command and Control, 2014, 39(7):89-92.
[18]	廖志娟, 孙跃, 叶兆虹, 等. 无线电能传输系统共振机理及共振点分布特性研究[J]. 电工技术学报, 2020, 35(2):215-224.
	Liao Zhijuan, Sun Yue, Ye Zhaohong, et al. Research on resonance mechanism and resonant point distribution characteristic of magnetic coupling wireless power transfer systems[J]. Journal of Electrotechnics, 2020, 35(2):215-224.
[19]	蔡进, 吴旭升, 孙盼, 等. 磁耦合无线电能传输技术研究进展及其大功率实现方法[J]. 海军工程大学学报, 2021, 33(5):19-27.
	Cai Jin, Wu Xusheng, Sun Pan, et al. Research progress of magnetic coupling wireless power transmission technology and its high power realization method[J]. Journal of Naval University of Engineering, 2021, 33(5):19-27.
[20]	何强, 杨青慧, 张怀武. 一种射频放大器上电时序及偏置点控制方法[J]. 电子科技, 2021, 34(2):1-6.
	He Qiang, Yang Qinghui, Zhang Huaiwu. A control method of power up bias sequence of rdio frequency amplifier[J]. Electronic Science and Technology, 2021, 34(2):1-6.
[21]	Naka Y, Yamamoto K, Nakata T, et al. Improvement in efficiency of underwater wireless power transfer with electric coupling[J]. IEICE Transactions on Electronics, 2017, 100(10):850-857.
[22]	高胜峰, 朱海, 王超, 等. 基于有限元法的潜艇磁场模型适用条件分析[J]. 舰船科学技术, 2016, 38(1):34-38.
	Gao Shengfeng, Zhu Hai, Wang Chao, et al. Analysis on the applicability of submarine magnetic model based on finite-element method[J]. Ship Science and Technology, 2016, 38(1):34-38.

芯片型号	频段 /MHz	最大发射功率/dBm	传输速率 /kbit·s^-1
NRF24L01P	2 400~2 525	20.0	2 000.0
CC2530	2 400~2 450	4.5	3.3
CC1101	387~464	10.0	500.0

Application Research on Wireless Setting Technology of Electronic Fuze

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 7

References 22

Related Articles 15

Metrics

Comments

Recommended 10

[1]	WAN Zhuang,XIE Jian,ZHAO Xun,QIN Jie. Research Progress of Vehicle Positioning and Communication Network Protocol [J]. Electronic Science and Technology, 2021, 34(11): 42-45.
[2]	SUN Haijing,CHEN Qiang,YANG Jiao,ZHOU Ling. Design of Chipless RFID Tag Based on Hybrid Coding [J]. Electronic Science and Technology, 2020, 33(6): 8-12.
[3]	YAN Yang,SHI Yu. Design and Implementation of a Passive High Linear Mixing Component [J]. Electronic Science and Technology, 2020, 33(3): 1-5.
[4]	WANG Zhengwei,GUO Hongli,YANG Xuezhou. Radio Frequency Fingerprinting Identification Based on Carrier Frequency Stability [J]. Electronic Science and Technology, 2019, 32(9): 46-50.
[5]	WEN Jie,WU Zhilin,SHI Yu,LIU Lan,HU Yue,LIU Lele. Design of a Programmable High Anti-interference AGC [J]. Electronic Science and Technology, 2019, 32(1): 76-79.
[6]	LI Gang1, HU Xu2 . Mechanism Analysis of the Electric Resonance in the Wireless Power Transmission [J]. , 2016, 29(9): 142-.
[7]	YANG Hongjun. Application of Moved Ticket Checking System in the Passenger Station [J]. , 2014, 27(11): 92-.
[8]	LIU Xuan, LIU Yi, XIANG Wen-Hao. Selection-based Cooperative Beamforming Algorithm for Relay Networks [J]. , 2014, 27(1): 30-.
[9]	CAI Si-Yu, SHANG Wei-Ping. Novel Automatic Interpretation System Based on Power Line Carrier Communication for Museums [J]. , 2013, 26(4): 41-.
[10]	WANG Li-Peng, REN Shun-Hang, LV Peng-Peng, SHANG Qiu-Feng. System Communications Technologies Based on Information Collection [J]. , 2013, 26(11): 170-.
[11]	ZHAO Zhi-Yu. Application of Electric Power Communication Tower Resources Management Based on Internet of Things [J]. , 2013, 26(11): 160-.
[12]	GONG Bingqing,WANG Yuanyuan. Design of a Low Power Radio-triggered Wake-up Circuit [J]. , 2013, 26(10): 151-.
[13]	PENG Leilei. Research on DRFM Technique in Electronic Jamming [J]. , 2013, 26(1): 104-.
[14]	LIN Ying,DENG Ke. Design and Realization of the Large Bandwidth DRFM Based on DDC and DUC Technology [J]. , 2013, 26(1): 98-.
[15]	WANG Yu-Qing, LI Kai-Yu, SUN Chun-Peng. an Improved Dynamic Frame Slotted ALOHA Algorithm [J]. , 12, 25(7): 76-.