电子系统高功率微波效应研究进展

doi:10.12305/j.issn.1001-506X.2025.08.02

系统工程与电子技术 ›› 2025, Vol. 47 ›› Issue (8): 2429-2443.doi: 10.12305/j.issn.1001-506X.2025.08.02

• 电子技术 • 上一篇

电子系统高功率微波效应研究进展

陈凯柏¹(), 高博¹^,*(), 高敏², 余道杰¹, 周晓东³, 宋燕燕¹, 王越¹

1. 中国人民解放军网络空间部队信息工程大学信息系统工程学院，河南郑州 450001
2. 陆军工程大学石家庄校区导弹工程系，河北石家庄 050003
3. 陆军工程大学石家庄校区弹药工程系，河北石家庄 050003

收稿日期:2024-09-10 出版日期:2025-08-25 发布日期:2025-09-04
通讯作者: 高博 E-mail:ckbguessg@163.com;xd_gaobo@163.com
作者简介:陈凯柏（1996—），男，讲师，博士，主要研究方向为高功率微波效应
高　敏（1964—），男，教授，博士，主要研究方向为弹箭信息化
余道杰（1978—），男，教授，博士，主要研究方向为高功率微波、电磁场
周晓东（1976—），男，副教授，博士，主要研究方向为高功率微波效应
宋燕燕（1984—），女，副教授，硕士，主要研究方向为元器件失效分析
王　越（1997—），女，实验员，硕士，主要研究方向为人工智能技术应用
基金资助:
国家自然科学基金（61871405）资助课题

Research progress on high-power microwave effects in electronic systems

Kaibai CHEN¹(), Bo GAO¹^,*(), Min GAO², Daojie YU¹, Xiaodong ZHOU³, Yanyan SONG¹, Yue WANG¹

1. College of Information Systems Engineering，PLA Information Engineering University，Zhengzhou 450001，China
2. Department of Missile Engineering，Army Engineering University （Shijiazhuang Campus），Shijiazhuang 050003，China
3. Department of Ammunition Engineering，Army Engineering University （Shijiazhuang Campus），Shijiazhuang 050003，China

Received:2024-09-10 Online:2025-08-25 Published:2025-09-04
Contact: Bo GAO E-mail:ckbguessg@163.com;xd_gaobo@163.com

摘要/Abstract

摘要：

开展电子系统高功率微波（high-power microwave, HPM）效应研究对信息化战争意义重大。本文基于HPM技术发展历程，首先介绍了电子系统面临的HPM威胁。其次，阐述了电子系统HPM效应研究的主要问题，分析了解析法、数值法和试验法的研究现状。最后，探讨了效应研究的下一步发展趋势。当前，针对复杂电子系统开展HPM效应研究仍面临算法和模型优化、数据精确测量等现实问题。传统理论分析方法可与人工智能技术有机融合，提高计算精度和效率。在大模型技术的驱动下，HPM效应评估技术将进一步发展，有效提升电子系统HPM防护能力。

关键词: 电子系统, 高功率微波, 效应研究, 人工智能, 效应数据库

Abstract:

Conducting research on high-power microwave （HPM） effects in electronic systems is of great significance for information warfare. Based on the development history of HPM technology, this article first introduces the HPM threats faced by electronic systems. Secondly, the main issues of HPM effect research in electronic systems are elaborated, and the research progress of analytical, numerical, and experimental methods is investigated. Finally, the development trends of effect research are discussed. At present, relevant research on HPM effects in complex electronic systems still faces problems such as algorithm and model optimization, precise data measurement, etc. Traditional theoretical analysis methods can be organically integrated with artificial intelligence technology to improve computational accuracy and efficiency. Driven by the technology of large model, HPM effect evaluation technology will further develop, effectively enhancing the HPM protection capability of electronic systems.

Key words: electronic system, high-power microwave （HPM）, effect research, artificial intelligence, effect database

中图分类号:

O 441

陈凯柏, 高博, 高敏, 余道杰, 周晓东, 宋燕燕, 王越. 电子系统高功率微波效应研究进展[J]. 系统工程与电子技术, 2025, 47(8): 2429-2443.

Kaibai CHEN, Bo GAO, Min GAO, Daojie YU, Xiaodong ZHOU, Yanyan SONG, Yue WANG. Research progress on high-power microwave effects in electronic systems[J]. Systems Engineering and Electronics, 2025, 47(8): 2429-2443.

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参考文献 94

1	GIRI D V, HOAD R, SABATH F. High power electromagnetic effects on electronic system[M]. London: Artech House, 2020.
2	PARFENOV Y V, CHEPELEV V M, RADASKY W A. About the possibility of mistakes when using unipolar electric field pulses when assessing electronic device immunity to UWB pulses[C]// Proc. of the IEEE International Symposium on Electromagnetic Compatibility and IEEE Asia-Pacific Symposium on Electromagnetic Compatibility, 2018: 928−931.
3	BAUM C E. Reminiscences of high-power electromagnetics[J]. IEEE Trans. on Electromagnetic Compatibility, 2007, 49 (2): 211- 218. doi: 10.1109/TEMC.2007.897147
4	ZHANG J, ZHANG D, FAN Y W, et al. Progress in narrowband high-power microwave sources[J]. Physics of Plasmas, 2020, 27 (1): 010501. doi: 10.1063/1.5126271
5	钱宝良. 国外高功率微波技术的研究现状与发展趋势[J]. 真空电子技术, 2015, (2): 2- 7.
	QIAN B L. The research status and developing tendency of high power microwave technology in foreign countries[J]. Vacuum Electronics, 2015, (2): 2- 7.
6	PRATHER W D, BAUM C E. Ultra-wideband source and antenna research[J]. IEEE Trans. on Plasma Science, 2000, 28 (5): 1624- 1630. doi: 10.1109/27.901245
7	EFREMOV A M, KOSHELEV V I, PLISKO V V, et al. A high-power source of ultrawideband pulses of synthesized radiation[J]. Instruments and Experimental Techniques, 2019, 62 (1): 33- 41. doi: 10.1134/S0020441218060052
8	AGEE F J, BAUM C E, PRATHER W D, et al. Ultra-wideband transmitter research[J]. IEEE Trans. on Plasma Science, 1998, 26 (3): 860- 873. doi: 10.1109/27.700855
9	BAUM C E, BAKER W L, PRATHER W D, et al. JOLT: a highly directive, very intensive, impulse-like radiator[J]. Proceedings of the IEEE, 2004, 92 (7): 1096- 1109. doi: 10.1109/JPROC.2004.829011
10	PRATHER W D, BAUM C E, LEHR J M, et al. Recent developments in ultra-wideband sources and antennas[C]// Proc. of the Conference on Ultra-Wideband, Short-Pulse Electromagnetics, 2003: 369−379.
11	刘金亮, 樊旭亮, 白国强, 等. 紧凑型Marx发生器高功率微波源研究进展[J]. 强激光与粒子束, 2012, 24 (4): 757- 764.
	LIU J L, FAN X L, BAI G Q, et al. Progress of based on compact Marx generators high power microwave source[J]. High Power Laser and Particle Beams, 2012, 24 (4): 757- 764.
12	APPLIED PHYSICAL ELECTRONICS LIMITED COMPANIES. Marx generators-APELC[EB/OL]. [2024-10-23]. https://apelc.com/marx-generators.
13	CLARK R S, RINEHART L F, BUTTRAM M T, et al. An overview of sandia national laboratories’ plasma switched, gigawatt, ultra-wideband impulse transmitter program[C]// Proc. of the Conference on Ultra-Wideband, Short-Pulse Electromagnetics, 1993: 93−98.
14	RUKIN S. Solid-state repetitive generators of short GW-range pulses: a review[J]. Journal of Instrumentation, 2018, 13 (8): P08001.
15	MESYATS G A, KOROVIN S D, ROSTOV V V, et al. The RADAN series of compact pulsed power generators and their applications[J]. Proceedings of the IEEE, 2004, 92 (7): 1166- 1179. doi: 10.1109/JPROC.2004.829005
16	EFREMOV A M, KOSHELEV V I, PLISKO V V, et al. A high-power synthesized ultrawideband radiation source[J]. Review of Scientific Instruments, 2017, 88 (9): 094705. doi: 10.1063/1.5003418
17	PRATHER W D, BAUM C E, TORRES R J, et al. Survey of worldwide high-power wideband capabilities[J]. IEEE Trans. on Electromagnetic Compatibility, 2004, 46 (3): 335- 344. doi: 10.1109/TEMC.2004.831826
18	BALZOVSKY E V, BUYANOV Y I, KOSHELEV V I. Ultrawideband antenna arrays based on planar combined antennas for the frequency range of 3.1-10.6 GHz[J]. Journal of Physics: Conference Series, 2021, 1843 (1): 012003.
19	梁勤金. 固态高功率高重频脉冲源的研究与发展[J]. 电讯技术, 2019, 59 (10): 1227- 1236.
	LIANG Q J. Research and development of solid state high power high repetition frequency pulse source[J]. Telecommunication Engineering, 2019, 59 (10): 1227- 1236.
20	SABATH F, NITSCH D, JUNG M, et al. Design and setup of an UWB simulator for susceptibility investigations[C]// Proc. of the 27th General Assembly URSI, 2002.
21	NIKOO M S, HASHEMI S M A, DILMAGHANIAN M O. DSRD-based high-power repetitive short-pulse generator containing GDT: theory and experiment[J]. IEEE Trans. on Plasma Science, 2017, 45 (8): 2341- 2350. doi: 10.1109/TPS.2017.2717047
22	HUISKAMP T, BECKERS F, HEESCH E J M, et al. First implementation of a sub-nanosecond rise time, variable pulse duration, variable amplitude, repetitive, high-voltage pulse source[J]. IEEE Trans. on Plasma Science, 2014, 42 (3): 859- 867. doi: 10.1109/TPS.2014.2300895
23	牛卉, 伍洋, 李明. 国外高功率微波武器发展情况研究[J]. 飞航导弹, 2021, 8, 12- 16，23.
	NIU H, WU Y, LI M. Research on the development of high-power microwave weapons abroad[J]. Aerodynamic Missile Journal, 2021, 8, 12- 16，23.
24	王永芳, 许健明, 徐晓艳. 基于专利分析国外高功率微波武器发展情况[J]. 国防科技, 2022, 43 (6): 14- 19.
	WANG Y F, XU J M, XU X Y. An analysis of the development of foreign high power microwave weapons based on patents[J]. National Defense Technology, 2022, 43 (6): 14- 19.
25	张帅, 张艺博, 涂敏. 浅析美国高功率微波效应研究动态[J]. 强激光与粒子束, 2024, 36 (1): 5- 8.
	ZHANG S, ZHANG Y B, TU M. Brief analysis of research trends of high power microwave effect in the United States[J]. High Power Laser and Particle Beams, 2024, 36 (1): 5- 8.
26	贺军涛, 姚金妹, 王蕾. 美欧高功率微波技术研究现状及发展趋势[J]. 信息对抗技术, 2023, 2 (4): 123- 137.
	HE J T, YAO J M, WANG L. Research status and prospect of high power microwave technology in the United States and Europe[J]. Information Countermeasure Technology, 2023, 2 (4): 123- 137.
27	赵鸿燕, 周丽. 国外高功率微波武器发展研究[J]. 航空兵器, 2023, 30 (4): 42- 48.
	ZHAO H Y, ZHOU L. Research on the development of high-power microwave weapon abroad[J]. Aero Weaponry, 2023, 30 (4): 42- 48.
28	李庆颍. 机载设备电磁脉冲防护方法研究[D]. 沈阳: 沈阳航空航天大学, 2018.
	LI Q Y. Research on the method of electromagnetic pulses protection for airborne equipment[D]. Shenyang: Shenyang Aerospace University, 2018.
29	MIN S H, JUNG H, KWON O, et al. Analysis of electromagnetic pulse effects under high-power microwave sources[J]. IEEE Access, 2021, 9, 136775- 136791. doi: 10.1109/ACCESS.2021.3117395
30	SEWELL P, TURNER J D, ROBINSON M P, et al. Comparison of analytic, numerical and approximate models for shielding effectiveness with measurement[J]. IEE Proceedings-Science, Measurement and Technology, 1998, 145 (2): 61- 66. doi: 10.1049/ip-smt:19981832
31	SOLIN J R. Formula for the field excited in a rectangular cavity with an electrically large aperture[J]. IEEE Trans. on Electromagnetic Compatibility, 2012, 54 (1): 188- 192. doi: 10.1109/TEMC.2011.2179941
32	MENDEZ H A. Shielding theory of enclosures with apertures[J]. IEEE Trans. on Electromagnetic Compatibility, 1978, 20 (2): 296- 305.
33	BRIDGES J E. An update on the circuit approach to calculate shielding effectiveness[J]. IEEE Trans. on Electromagnetic Compatibility, 1988, 30 (3): 211- 221. doi: 10.1109/15.3299
34	BETHE H A. Theory of diffraction by small holes[J]. Physical Review, 1944, 66 (7-8): 163- 182. doi: 10.1103/PhysRev.66.163
35	SOLIN J R. Shielding effectiveness of satellite faraday cages with EMI taped seams and closeouts[J]. IEEE Electromagnetic Compatibility Magazine, 2018, 7 (2): 40- 46.
36	张亚普, 达新宇, 祝杨坤, 等. 电大开孔箱体屏蔽效能分析解析模型[J]. 物理学报, 2014, 63 (23): 164- 173.
	ZHANG Y P, DA X Y, ZHU Y K, et al. Formulation for shielding effectiveness analysis of a rectangular enclosure with an electrically large aperture[J]. Acta Physica Sinica, 2014, 63 (23): 164- 173.
37	公延飞, 郝建红, 蒋璐行, 等. 基于Bethe小孔耦合理论和镜像原理的双腔体电磁泄漏的解析模型[J]. 电工技术学报, 2018, 33 (9): 2139- 2147.
	GONG Y F, HAO J H, JIANG L X, et al. An analytical model for electromagnetic leakage from double cascaded enclosures based on Bethe’s small aperture coupling theory and mirror procedure[J]. Transactions of China Electrotechnical Society, 2018, 33 (9): 2139- 2147.
38	JIANG L H, HAO J H, GONG Y F. Analytical method for electromagnetic coupling to a penetrated transmission line in cascaded multiple enclosures with hybrid apertures[J]. Journal of Electromagnetic Waves and Applications, 2019, 33 (7): 1131- 1144.
39	ROBINSON M P, BENSON T M, CHRISTOPOULOS C, et al. Analytical formulation for the shielding effectiveness of enclosures with apertures[J]. IEEE Trans. on Electromagnetic Compatibility, 1998, 40 (3): 240- 248. doi: 10.1109/15.709422
40	SHIM J, KAM D G, KWON J H, et al. Circuital modeling and measurement of shielding effectiveness against oblique incident plane wave on apertures in multiple sides of rectangular enclosure[J]. IEEE Trans. on Electromagnetic Compatibility, 2010, 52 (3): 566- 577. doi: 10.1109/TEMC.2009.2039483
41	AZARO R, CAORSI S, DONELLI M, et al. A circuital approach to evaluating the electromagnetic field on rectangular apertures backed by rectangular cavities[J]. IEEE Trans. on Microwave Theory and Techniques, 2002, 50 (10): 2259- 2266. doi: 10.1109/TMTT.2002.803434
42	POAD F A, JENU M Z M, CHRISTOPOULOS C, et al. Analytical and experimental study of the shielding effectiveness of a metallic enclosure with off-centered apertures[C]// Proc. of the 17th International Zurich Symposium on Electromagnetic Compatibility, 2006: 618−621.
43	SU D L, LIU H, YANG S, et al. An analytical method for calculating the shielding effectiveness of an enclosure with an oblique rectangular aperture[J]. Chinese Journal of Electronics, 2019, 28 (4): 850- 855. doi: 10.1049/cje.2019.02.006
44	NIE B L, LIU Q S, DU P A. An improved thickness correction method of analytical formulations for shielding effectiveness prediction[J]. IEEE Trans. on Electromagnetic Compatibility, 2016, 58 (3): 907- 910. doi: 10.1109/TEMC.2016.2533661
45	HU P Y, SUN X Y, CHEN J. Hybrid model for estimating the shielding effectiveness of metallic enclosures with arbitrary apertures[J]. IET Science, Measurement & Technology, 2020, 14(4): 462−470.
46	NIE B L, DU P A, XIAO P. An improved circuital method for the prediction of shielding effectiveness of an enclosure with apertures excited by a plane wave[J]. IEEE Trans. on Electromagnetic Compatibility, 2017, 60 (5): 1376- 1383.
47	CHEN K B, GAO M, LIU S H, et al. A circuit model for predicting the shielding effectiveness of cylindrical enclosure[J]. Measurement Science and Technology, 2022, 33 (11): 115006. doi: 10.1088/1361-6501/ac8366
48	RABAT A, BONNET P, DRISSI K E K, et al. An analytical evaluation of the shielding effectiveness of enclosures containing complex apertures[J]. IEEE Access, 2021, 9, 147191- 147200. doi: 10.1109/ACCESS.2021.3123441
49	林竞羽, 周东方, 毛天鹏, 等. 电磁拓扑分析中的BLT方程及其应用[J]. 信息工程大学学报, 2004, (2): 118- 121.
	LIN J Y, ZHOU D F, MAO T P , et al. BLT equation in electromagnetic topology analysis and its application[J]. Journal of Information Engineering University, 2004, (2): 118- 121.
50	TESCHE F M, BUTLER C M. On the addition of EM field propagation and coupling effects in the BLT equation[J]. Interaction Notes, 2003, 588, 1- 43.
51	BAUM C E. Including apertures and cavities in the BLT formalism[J]. Electromagnetics, 2005, 25 (7/8): 623- 635. doi: 10.1080/02726340500214852
52	ZHANG X, ZHOU Z P, WANG, Z L, et al. An approach to approximate evaluation of shielding effectiveness of double-cavity structure with an aperture array using BLT equation[C]// Proc. of the Frontier Academic Forum of Electrical Engineering, 2022: 967−976.
53	CHEN K B, GAO M, ZHOU X D. A model for the prediction of the shielding effectiveness of cylindrical enclosure[J]. AIP Advances, 2022, 12 (8): 085309. doi: 10.1063/5.0091183
54	BRUNS H D, SCHUSTER C, SINGER H. Numerical electromagnetic field analysis for EMC problems[J]. IEEE Trans. on Electromagnetic Compatibility, 2007, 49 (2): 253- 262. doi: 10.1109/TEMC.2007.897152
55	任卓翔, 闫帅, 陈志福, 等. 电工装备低频电磁仿真中若干关键问题研究现状及趋势[J]. 高电压技术, 2024, 50 (3): 905- 923.
	REN Z X, YAN S, CHEN Z F, et al. State of the art and trend of several key issues in low frequency electromagnetic simulation of electrical equipment[J]. High Voltage Engineering, 2024, 50 (3): 905- 923.
56	VENKATA S C P, JAYASREE P. Innovative measurement and noise reduction of voltage coupling in shielded cables for enhanced signal integrity[J]. AIP Advances, 2023, 13, 085030. doi: 10.1063/5.0167508
57	LARIBI H, DEHKHODA P, TAVAKOLI A, et al. Susceptibility analysis of a low noise amplifier against an electromagnetic pulse[J]. IET Science, Measurement & Technology, 2020, 14(10): 1044−1048.
58	CHEN K B, LIU S H, GAO M. Simulation and analysis of an FMCW radar against the UWB EMP coupling responses on the wires[J]. Sensors, 2022, 22 (12): 4641. doi: 10.3390/s22124641
59	王蕾, 柴常春, 赵天龙, 等. p-GaN HEMT强电磁脉冲损伤效应与防护设计研究[J]. 西安电子科技大学学报, 2023, 50 (6): 34- 43.
	WANG L, CHAI C C, ZHAO T L, et al. Damage effect and protection design of the p-GaN HEMT induced by the high power electromagnetic pulse[J]. Journal of Xidian University, 2023, 50 (6): 34- 43.
60	张兵, 方子璇, 彭帅, 等. 高功率微波频率对PIN限幅器的影响分析[J]. 电子科技大学学报, 2024, 53 (3): 321- 326.
	ZHANG B, FANG Z X, PENG S, et al. Effect analysis of high power microwave frequency on PIN limiter[J]. Journal of University of Electronic Science and Technology of China, 2024, 53 (3): 321- 326.
61	ZHANG H X, ZHAN Q, HUANG L, et, al. A scalable HPC-based domain decomposition method for multiphysics modeling of RF devices[J]. IEEE Trans. on Components, Packaging and Manufacturing Technology, 2021, 11 (12): 2158- 2170. doi: 10.1109/TCPMT.2021.3121540
62	SABATH F. IEMI风险评估——用结构化方法改进关键基础设施对电磁攻击的恢复能力[J]. 安全与电磁兼容, 2016, 2, 9- 10，22.
	SABATH F. IEMI risk assessment-a structured way to improve the resilience of critical infrastructures to electromagnetic attacks[J]. Safety & EMC, 2016, 2, 9- 10，22.
63	MIL-STD-188-125-2. High altitude electromagnetic pulse (HEMP) protection for ground-based C4I facilities performing critical time-urgent missions, part 2: transportable systems[S]. Washington, D. C.: United States Department of Defense, 1999.
64	CROVETTI P S. Reproduction of the effects of an arbitrary radiated field by ground current injection[J]. IEEE Trans. on Microwave Theory and Techniques, 2012, 60 (4): 1136- 1145. doi: 10.1109/TMTT.2012.2183382
65	魏光辉, 卢新福, 潘晓东. 强场电磁辐射效应测试方法研究进展与发展趋势[J]. 高电压技术, 2016, 42 (5): 1347- 1355.
	WEI G H, LU X F, PAN X D. Recent progress and development in test methods for high intensity electromagnetic field radiation effect[J]. High Voltage Engineering, 2016, 42 (5): 1347- 1355.
66	WUNSCH D C, BELL R R. Determination of threshold failure levels of semiconductor diodes and transistors due to pulse voltages[J]. IEEE Trans. on Nuclear Science, 1968, 15 (6): 244- 259. doi: 10.1109/TNS.1968.4325054
67	TASCA D M. Pulse power failure modes in semiconductors[J]. IEEE Trans. on Nuclear Science, 1970, 17 (6): 364- 372. doi: 10.1109/TNS.1970.4325819
68	WHALEN J J, CALCATERA M C, THORN M L. Microwave nanosecond pulse burnout properties of GaAs MESFET’s[J]. IEEE Trans. on Microwave Theory and Techniques, 1979, 27 (12): 1026- 1031. doi: 10.1109/TMTT.1979.1129785
69	ILIADIS A A, KIM K. Theoretical foundation for upsets in CMOS circuits due to high-power electromagnetic interference[J]. IEEE Trans. on Device and Materials Reliability, 2010, 10 (3): 347- 352. doi: 10.1109/TDMR.2010.2050692
70	NITSCH D, CAMP M, SABATH F, et al. Susceptibility of some electronic equipment to HPEM threats[J]. IEEE Trans. on Electromagnetic Compatibility, 2004, 46 (3): 380- 389. doi: 10.1109/TEMC.2004.831842
71	DENG X C, HUANG W, LI X, et al. Investigation of failure mechanisms of 1200V rated trench SiC MOSFETs under repetitive avalanche stress[J]. IEEE Trans. on Power Electronics, 2022, 37 (9): 10562- 10571. doi: 10.1109/TPEL.2022.3163930
72	LI Q W, SUN J, LI F X, et al. C band microwave damage characteristics of pseudomorphic high electron mobility transistor[J]. Chinese Physics B, 2021, 30 (9): 605- 611.
73	CAMP M, GARBE H, NITSCH D. UWB and EMP susceptibility of modern electronics[C]// Proc. of the IEEE International Symposium on Electromagnetic Compatibility, 2001, 2: 1015−1020.
74	MORO N, DEHBAOUI A, HEYDEMANN K, et al. Electromagnetic fault injection: towards a fault model on a 32-bit microcontroller[C]// Proc. of the Workshop on Fault Diagnosis and Tolerance in Cryptography, 2013: 77−88.
75	MORO N, HEYDEMANN K, ENCRENAZ E, et al. Formal verification of a software countermeasure against instruction skip attacks[J]. Journal of Cryptographic Engineering, 2014, 4 (3): 145- 156. doi: 10.1007/s13389-014-0077-7
76	LTCI O T, LTCI L S, LTCI J L D. Characterization of electromagnetic fault injection on a 32-bit microcontroller instruction buffer[C]// Proc. of the Asian Hardware Oriented Security and Trust Symposium, 2020.
77	HOAD R, CARTER N J, HERKE D, et al. Trends in EM susceptibility of IT equipment[J]. IEEE Trans. on Electromagnetic Compatibility, 2004, 46 (3): 390- 395. doi: 10.1109/TEMC.2004.831815
78	SABATH F. HPEM susceptibility test on IT-Networks and their components[C]// Proc. of the 29th General Assembly of the URSI, 2008.
79	ZHENG J Y, WEI G H, QI C. Research on blocking interference for digital radio station under UWB EMP[J]. AIP Advances, 2021, 11 (5): 055306. doi: 10.1063/5.0048853
80	熊久良. 典型米波无线电引信电磁脉冲辐照效应[J]. 高电压技术, 2017, 43 (10): 3371- 3380.
	XIONG J L. Irradiation effect of emp on typical metric wave radio fuze[J]. High Voltage Engineering, 2017, 43 (10): 3371- 3380.
81	BACKSTROM M, LOVSTRAND K G. Susceptibility of electronic systems to high-power microwaves: summary of test experience[J]. IEEE Trans. on Electromagnetic Compatibility, 2004, 46 (3): 396- 403. doi: 10.1109/TEMC.2004.831814
82	CAMP M, SCHMITZ J, JUNG M. Vulnerability and coupling behaviour of a TETRA communication system to electromagnetic fields[C]// Proc. of the IEEE International Symposium on Electromagnetic Compatibility, 2015: 344−349.
83	MAO Q D, XIANG Z W, HUANG L Y, et al. High-power microwave pulse-induced failure on unmanned aerial vehicle system[J]. IEEE Trans. on Plasma Science, 2023, 51 (7): 1885- 1893. doi: 10.1109/TPS.2023.3236300
84	安亚帅. 高功率电磁脉冲对无人机惯性系统的毁伤效应研究[D]. 南京: 南京理工大学, 2023.
	AN Y S. Research on the destructive effect of high-power electromagnetic pulse on unmanned aerial vehicle inertial system[D]. Nanjing: Nanjing University of Science & Technology, 2023.
85	YANG C X, CUI D H, CHEN Z H, et al. High-power microwave damage assessment method for UAV[J]. Journal of Physics: Conference Series, 2022, 2478 (8): 082011.
86	张庆龙, 王玉明, 程二威, 等. 导航接收机跟踪环路电磁干扰的预测方法研究[J]. 电子与信息学报, 2021, 43 (12): 3656- 3661. doi: 10.11999/JEIT200895
	ZHANG Q L, WANG Y M, CHENG E W, et al. Investigation on prediction method of electromagnetic interference in the tracking loop of navigation receiver[J]. Journal of Electronics & Information Technology, 2021, 43 (12): 3656- 3661. doi: 10.11999/JEIT200895
87	余道杰, 雷顺天, 贺凯, 等. 无人机定位系统电源分配网络电磁干扰行为级分析与预测[J]. 强激光与粒子束, 2023, 35 (5): 42- 48.
	YU D J, LEI S T, HE K, et al. Analysis and prediction of electromagnetic interference behavior level in power distribution network of UAV positioning system[J]. High Power Laser and Particle Beams, 2023, 35 (5): 42- 48.
88	周长林, 王振义, 刘统, 等. 基于BP神经网络的低压差线性稳压器电磁干扰损伤模型[J]. 高电压技术, 2016, 42 (3): 973- 979.
	ZHOU C L, WANG Z Y, LIU T, et al. Low dropout linear regulator electromagnetic interference damage model based on BP neural network[J]. High Voltage Engineering, 2016, 42 (3): 973- 979.
89	WU J F, BOYER A, LI J, et al. Modeling and simulation of LDO voltage regulator susceptibility to conducted EMI[J]. IEEE Trans. on Electromagnetic Compatibility, 2014, 56 (3): 726- 735. doi: 10.1109/TEMC.2013.2294951
90	王寅达, 李谭毅, 王一尧, 等. 高功率微波作用下微系统中电磁-热耦合效应仿真新方法及验证[C]//全国天线年会, 2021: 1927−1930.
	WANG Y D, LI T Y, WANG Y Y, et al. Novel simulation method and its verification of electro-thermal coupling effect in microsystem under high power microwave injection[C]// Proc. of the National Antenna Annual Conference, 2021: 1927−1930.
91	ZHANG H X, ZHAN Q, HUANG L, et al. Multiphysics computing of challenging antenna arrays under a supercomputer framework[J]. IEEE Journal on Multiscale and Multiphysics Computational Techniques, 2023, 8, 165- 177. doi: 10.1109/JMMCT.2023.3254661
92	张天成. 时域不连续伽辽金的多尺度/非线性电磁问题高效分析方法研究[D]. 南京: 南京理工大学, 2022.
	ZHANG T C. Efficient discontinuous Galerkin time-domain method for multiscale/nonlinear electromagnetic problems[D]. Nanjing: Nanjing University of Science & Technology, 2022.
93	BRAUER F, SABATH F, HASEBORG J L. Susceptibility of IT network systems to interferences by HPEM[C]// Proc. of the IEEE International Symposium on Electromagnetic Compatibility, 2009: 237−242.
94	郝建红, 潘慧东, 范杰清. 基于时间门方法的随机耦合模型在复杂腔体电磁预测中的应用[J]. 电波科学学报, 2021, 36 (1): 61- 67.
	HAO J H, PAN H D, FAN J Q. Application of random coupling model based on time gating method in electromagnetic prediction of complex cavity[J]. Chinese Journal of Radio Science, 2021, 36 (1): 61- 67.

研究国家	研究机构	脉冲源型号	峰值功率/GW	$ {{r}}{E_{{\mathrm{P}}} } $/kV	中心频率/GHz	脉冲前沿/ns	脉冲宽度/ns	重频/Hz
美国^[6−13]	空军研究实验室	H₃	43	360	1~2	0.13	0.3	2×10³
		H₄	100	—	1~2	0.13	0.5	—
		H₅	15	430	—	0.238	2.5	2×10³
		IRA	—	1280	0.032~3	0.085	0.13	200
		IRA II	—	690	0.070~4	0.085	0.13	400
		JOLT	—	5400	0.050~2	0.085	0.1	600
	中国湖基地	THOR	200	680	0.2~1	0.2	0.4	—
	应用物理电子公司	MG171C500PF	0.4	—	—	0.2	2~3	100
		MG403C2700PF	10	—	—	<5	—	10
		MG831C150NF	230	—	—	1.2~100	—	1
	圣地亚哥国家试验室	SINPER	1	400	0.1~3	0.15	2	1.2×10³
俄罗斯^[14−18]	叶卡捷琳堡电物理研究所	S-500	>15	750	2~4	0.1	0.12	1×10³
	叶卡捷琳堡电物理研究所	RADAN-303B	0.2	—	—	0.25	4	100
	托木斯克强流电子学研究所	SINUS	3.2	4300	—	—	1	100
		—	0.6	690	—	—	0.5	100
		—	—	450	—	0.08	0.23	100
		—	—	440	—	—	1	100
		—	—	500	0.2~0.8	—	2~3	100
		—	—	220	0.1~1	—	2~3	100
		—	—	600	0.39~2	—	0.5	100
		—	—	200	0.15~2.7	—	1	100
		—	—	—	3.1~10.6	0.05	0.2	—
德国^[19−20]	贝尔巴克公司	FPG30P	—	—	—	1	1~500	100
	贝尔巴克公司	FPG5	—	—	—	0.3	1~2	5×10⁵
	代傲防务集团	DS350	2	300	—	—	—	100
	武装技术研究所	—	0.8	<1000	—	0.25	0.5	1×10³
伊朗^[21]	谢里夫理工大学	—	0.006	—	—	—	1.1	4.5×10⁵
荷兰^[22]	埃因霍芬理工大学	—	—	—	—	0.2	1~10	1×10³

算法	算法特点
TLM	依据惠更斯电磁波传播原理，结合Maxwell方程和边界条件求解模型的时域或频域响应，分析模型磁场分布
FIT	通过正交网格完成离散Maxwell方程组的空间离散化，用中心差分代替时间导数，通过显式方程求解电磁场问题，无需进行矩阵求逆运算
FDTD	根据差分形式的Maxwell方程组和模型初始条件、吸收边界条件，在时间轴上对计算元胞内的电磁场数据连续抽样，求解模型的电磁场时空分布
FEM	以变分原理为基础，将模型分割为计算子域，在子域内使用插值函数表示未知量，通过迭代法或直接法求解子域节点边值问题
MOM	将积分方程转换成算子方程，将待求解函数表示为基函数，将基函数代入算子方程并使用权函数获取矩量，得到代数方程组，该方法只需设置吸收边界条件

效应等级	效应现象	现象描述
未知效应	未知	对设备影响或未观察到，无法确定
无效应	无影响	无效应现象
干扰效应	噪声	信号线和电源线的噪声水平升高，导致显示器闪烁或数据速率降低
	位翻转	数据流的位置交替
	失效	电磁干扰导致系统/组件故障
	故障	软件故障或崩溃
损伤效应	闩锁	半导体元件闩锁
	闪络	芯片内闪络/元件内闪络
	片上焊丝熔化	芯片上的导线熔化
	键合线破坏/导线熔化	半导体器件中的键合线熔化

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电子系统高功率微波效应研究进展

Research progress on high-power microwave effects in electronic systems

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