航天光学遥感器EMC优化设计的研究
|
摘要
本文在航天应用环境下,以航天光学遥感器内部机械电子结构为基础,借鉴EMC领域的理论和方法来构建适合于EMC分析、测量和优化设计的策略,采用模型分析法来研究EMC问题,对电磁干扰源、传播途径以及敏感器件进行了详细分析,解决了航天光学遥感器EMC系统中存在的问题。
首先详细分析了电磁干扰通过导线传导及耦合方式进入系统内部电路的情况,并相应建立了矩阵研究模型,分析了线缆参数对EMC的影响,给出了相应的解决策略。
其次,建立了航天光学遥感器辐射干扰预估分析模型,分别对电缆、信号回路、空间电磁场等进行了模型分析,提出了器件组合分析方法,解决了相关领域的预估计问题。
第三,针对EMC的模型分析,详细阐述了EMC的硬件设计优化方法,分析了屏蔽、滤波以及接地技术,进行了抗扰度实验并采取了相应的波长措施,达到了理想的效果。同时,针对航天领域的EMC测量,建立了专用EMC测量模型,其中包括了合格性测量以及故障分析,并建立了传导敏感度和辐射敏感度测量模型,为航天光学遥感器的EMC测量打下了基础,并提供测量的依据和方法。
最后对航天光学遥感器进行了一系列EMC测试,得到了相应的数据和测试曲线。实验证明,文中所采取的EMC分析及其优化设计方法,取得了预期的效果,实现航天光学遥感器EMC优化设计。
Under the circumstance of aerospace technology applications, this paper, based on the electronic structure of spaceflight optics remote sensors, constructs the strategies that can be applied in EMC analysis, measurement and optimal design through using the EMC theories and methods, adopts mode analysis in studying the EMC issues, analyzes the electromagnetic interference source, transmission routes and sensing device in detail, and solves the problems existing in the EMC system of spaceflight optics remote sensors.
First of all, this paper analyzes the situation of electromagnetic interference entering the system interior circuit by means of conducting wires and coupled ways, sets up the corresponding matrix research model, analyzes the effect of wire and cable parameter on EMC, and provides corresponding solving strategies.
Secondly, this paper establishes the spaceflight optics remote sensors radiated interference pre-estimating analysis model and analyzing the models of cable, signal loop and electromagnetic field, and it puts forward device combination analytical method, which has solved the estimate problems in related fields.
Thirdly, aimed at the model analysis of EMC, this paper expounds the optimization methods of EMC hardware design, analyzes shields, filtering and ground connection technologies, carries on immunity test and adopts corresponding wavelength measures so as to achieve the ideal results. Meanwhile, directing at the EMC measurement in aerospace domain, this paper also establishes EMC-specialized measurement model, including eligibility measurement and fault analysis, and sets up conducted susceptibility and radiation sensitivity measurement model, which has laid foundation for the EMC measurement of spaceflight optics remote sensors as well as provided the measuring basis and methods.
Lastly, this paper carries on a series of EMC test on the spaceflight optics remote sensors, and obtains the corresponding data and curves. And the experimental result proves that the EMC analysis and optimal design method adopted in this paper has obtained the expected effect and achieved the spaceflight optics remote sensors EMC optimal design.
首先详细分析了电磁干扰通过导线传导及耦合方式进入系统内部电路的情况,并相应建立了矩阵研究模型,分析了线缆参数对EMC的影响,给出了相应的解决策略。
其次,建立了航天光学遥感器辐射干扰预估分析模型,分别对电缆、信号回路、空间电磁场等进行了模型分析,提出了器件组合分析方法,解决了相关领域的预估计问题。
第三,针对EMC的模型分析,详细阐述了EMC的硬件设计优化方法,分析了屏蔽、滤波以及接地技术,进行了抗扰度实验并采取了相应的波长措施,达到了理想的效果。同时,针对航天领域的EMC测量,建立了专用EMC测量模型,其中包括了合格性测量以及故障分析,并建立了传导敏感度和辐射敏感度测量模型,为航天光学遥感器的EMC测量打下了基础,并提供测量的依据和方法。
最后对航天光学遥感器进行了一系列EMC测试,得到了相应的数据和测试曲线。实验证明,文中所采取的EMC分析及其优化设计方法,取得了预期的效果,实现航天光学遥感器EMC优化设计。
Under the circumstance of aerospace technology applications, this paper, based on the electronic structure of spaceflight optics remote sensors, constructs the strategies that can be applied in EMC analysis, measurement and optimal design through using the EMC theories and methods, adopts mode analysis in studying the EMC issues, analyzes the electromagnetic interference source, transmission routes and sensing device in detail, and solves the problems existing in the EMC system of spaceflight optics remote sensors.
First of all, this paper analyzes the situation of electromagnetic interference entering the system interior circuit by means of conducting wires and coupled ways, sets up the corresponding matrix research model, analyzes the effect of wire and cable parameter on EMC, and provides corresponding solving strategies.
Secondly, this paper establishes the spaceflight optics remote sensors radiated interference pre-estimating analysis model and analyzing the models of cable, signal loop and electromagnetic field, and it puts forward device combination analytical method, which has solved the estimate problems in related fields.
Thirdly, aimed at the model analysis of EMC, this paper expounds the optimization methods of EMC hardware design, analyzes shields, filtering and ground connection technologies, carries on immunity test and adopts corresponding wavelength measures so as to achieve the ideal results. Meanwhile, directing at the EMC measurement in aerospace domain, this paper also establishes EMC-specialized measurement model, including eligibility measurement and fault analysis, and sets up conducted susceptibility and radiation sensitivity measurement model, which has laid foundation for the EMC measurement of spaceflight optics remote sensors as well as provided the measuring basis and methods.
Lastly, this paper carries on a series of EMC test on the spaceflight optics remote sensors, and obtains the corresponding data and curves. And the experimental result proves that the EMC analysis and optimal design method adopted in this paper has obtained the expected effect and achieved the spaceflight optics remote sensors EMC optimal design.
引文
[1]高枚纲.EMC总论[M].北京:北京邮电大学出版社,2001.5.
[2]沙斐.机电一体化系统的EMC技术[M].北京:中国电力出版社,1999.7.
[3]杨克俊.EMC原理与设计技术[M].北京:人民邮电出版社,2004.8.
[4]区建昌.电子设备的EMC设计[M].北京:电子工业出版社,2003.9.
[5]周旭.电子设备防干扰技术原理与技术[M].北京:国防工业出版社,2005(6):33.
[6]陈昌金.军用伺服驱动器的电磁兼容分析与研究[D].硕士论文.电子科技大学.2008.10
[7]邱扬.田锦.EMC设计技术[M].西安:西安电子科技大学,2001.8.
[8]杨克俊.EMC原理与设计技术[M].北京:人民邮电出版社,2004.6.
[9]孟进,马伟明,张磊,潘启军,赵治华.变换器传导电磁千扰集中等效模型参数估计方法[J].电工技术学报,2005.20(6).
[10]和军平,姜建国,陈斌.电力电子装置传导电磁干扰特性测量的新方法[Z].电力电子技术,2001.5.
[11]陈斌,姜建国,孙旭东.PWM逆变器感应电机驱动系统中接地电流EMI问题的分析[Z].中国电机工程学报,2003.23(2).
[12]和军平,陈为,姜建国.开关电源共模传导干扰模型的研究[J].中国电机工程学报.2005.25(8):50-55.
[13]Dr. Todd H. Hubing. Survey of Numerical Electromagnetic Modeling Techniques. [R].UMR EMC Lab:Universiy of Missouri-Rolla Electromagnetic Compatibiliy Laboratory Technical Reports.1991.
[14]Bruce Arcbambeault. Modeling and Simulation Validation for EMC Applications. IEEE International Symposium on Electromagnetic Compatibiliy. 1999 (1):492-496.
[15]Bruce Arcbambeault. Concerns and Approaches for Accurate EMC Simulation Validation.2003 IEEE International Symposium on Electromagnetic Compatibiliy.
[16]R. Neurnayer. Continuous Simulation of System-Level Automotive EMC Problems. IEEE Symposium on Electromagnetic Compatibiliy 2003(1):409-413.
[17]张玉莲.电子设备电磁兼容仿真建模研究.硕士论文.西安电子科技大学,2007.1
[18]刘国强.Ansoft工程电磁场有限元分析[M].北京:电子工业出版社,2006.2.
[19]金建铭,电磁场有限元方法[M].西安:西安电子科技大学出版社,1998.3.
[20]盛新庆.计算电磁学要论[M].北京:科学出版社,2005.6.
[21]王长清,祝西里.电磁场计算中的时域有限差分法[M].北京:北京大学出版社,1990.9.
[22]朱加铭,欧贵宝,何蕴增.有限元与边界元法[M].哈尔滨:哈尔滨工程大学出版社,2002.1.
[23]尹海平.传导性电磁兼容关键技术研究[D].硕士论文.南京师范大学,2008.6
[24]赵阳,李世锦等.传导性EMI噪声的模态分离与噪声抑制问题探讨[J].南京师范大学学报(工程技术版),2004,vol.4,No.4,1-4.
[25]Kye Yak See, Junhong Deng. Measurement of noise source imPedanee of SMPS using a two current probes approach, IEEE transactions on Power Electronies.2004. VOI.19, No.3,862-868.
[26]Franco Fiori, Vincenzo. P, Modified gummel-poon model for susceptibility prediction[J]. IEEE transactions on electromagnetic compatibility,2000. 42(2):206-213.
[27]张文彬,通信产品电子线路EMC的分析与预测[D],哈尔宾工业大学,信息科学与技术学院,2001.7.
[28]谭波.汽车电子控制系统的电磁兼容性研究[D].硕士论文.重庆大学,2009.5.
[29]靳江红,EMC的计算机预测[J],中国职业安全卫生管理体系认证,2001,(4):42-43;
[30]Seibert G, Metzner D, Klotz F. Behavioral modelling of ICs for investigations of conducted emissions in automotive systems[C] 17th International Zurich Symposium on Electromagnetic Compatibility,2006.27(2):356-358.
[31]Hara O M, Colebrooke J. Automotive EMC test harnesses:standard lengths and their effect on conducted emissions IEEE International Symposium on Electromagnetic Compatibility[C],2003.11 (5):233-236.
[32]Makaran J E, Lovetri J. Prediction of conducted RFI emissions in BLDC motors for automotive applications[C]. IEEE International Symposium on Electromagnetic Compatibility,2001.1 (8):21-25.
[33]Loeckx J, Gielen G. Efficient identification of major contributions to EMI-induced rectification effects in analog automotive circuits[C].17th International Zurich Symposium on Electromagnetic Compatibility,2006.27 (2):148-151.
[34]王健,高勇.汽车电子转向器电磁传导敏感度测试技术研究[J],西安理工大学学报,2007.23(2):168-171.
[35]马喜来.汽车电磁兼容性预估计的研究[D].博士论文.吉林大学,2008.4
[36]Piazza Di, Ragusa A.A model of electromagnetic radiated emissions for dual automotive electrical systems[C]. IEEE International Symposium on industrial Elec 2004.1(5):317-322.
[37]Sun Shishuang, Drewniak J, Pommerenke D. Common-mode radiation resultin handassembled cable bundles on automotive platforms[C]. IEEE International SymposElectromagnetic Compatibility,2006.2 (8):298-303.
[38]汪泉弟,刘春艳,俞集辉.汽车火花点火系统电磁干扰的抑制方法[J].重庆大学学报(自然科学版),2007.30(7):46-49.
[39]Ankarson, P., Carlsson, J. FDTD simulation of the electrical environment for vehicles by using CAD data[C]. Electromagnetic Compatibility,2002 3rd International Symposium on 21-24 May 2002:272-275.
[40]Anzaldi, G., Riu, P. J., Fernandez, M., Silva, F. Validation procedure for final users applied to automotive environments[C]. Validation of Computational Electromagnetic,IEE Seminar on 30 March 2004:43-47.
[41]Reineix, A., Jecko, F., Jecko, B. Time Domain Modeling Techniques improvement for new EMC problems[C]. Electromagnetic Compatibility,1997. IEEE 1997 International Symposium on 18-22 Aug.1997:231-235.
[42]Chingchi Chen. Predicting Vehicle-Level Radiated EMI Emissions Using Module-Level Conducted EMIs and Harness Radiation Efficiencies [C]. Electromagnetic Compatibility,2001.EMC.2001 IEEE International Symposium on Volume 2,13-17 Aug.2001,1146-1151 vol.2.
[43]Geping Liu, Chingchi Chen, Yuhua Tu, Drewniak, J. L. Anticipating full vehicle radiated EMI from module-level testing in automobiles[C]. Electromagnetic Compatibility,2002 IEEE International Symposium on Volume 2,19-23 Aug.2002:982-986.
[44]Shiraki, Y., Sugahara, K., Tanabe, S., Nakamoto, K., Watanabe, T. Electromagnetic field distribution inside an automobile vehicle[C]. Electromagnetic Compatibility,2003 IEEE International Symposium on Volume 2,18-22 Aug.2003:730-734.
[45]Anzaldi, G., Riu, P. J., Silva, F., Santos, R. Finite difference time domain low cost modeling for automotive environments. Electromagnetic Compatibility[C].EMC2004.2004 International Symposium on Volume 3.9-13 Aug.2004:775-780.
[46]徐立.汽车电磁干扰及其影响[J].汽车电子应用,2006.2:46-49.
[47]陈天殷.汽车电器电磁兼容性及电磁干扰的抑制[J].汽车电器,2007.1:56-59.
[48]余勇,李建秋,周明等,车用柴油机ECU的电磁兼容性分析与设计[J].汽车工程,2001.6,23(6):395-400.
[49]张臻,先进汽车电子控制单元ECU的改进与发展[J].机械与电子,2006.7:36-38.
[50]李鸿强,刘志春等,汽车电子控制单元ECU的设计[J].汽车电子,2006.22(11):271-274.
[51]赖后翔.高频开关电源DC-DC模块的研究[D].硕士论文,湖南大学,2003.4.
[52]王鸿麟,景占荣.通信基础电源(第二版)[M].西安:西安电子科技大学出版社,2002.2.
[53]王虎刚.平均电流模式高效降压型DC-DC集成电路设计[D].硕士论文,西安电子科技大学,2005.1.
[54]华伟.通信开关电源的五种PWM反馈控制模式研究[J].通信电源技术,2005.2.
[55]胡为东.多电源系统的高速PCB设计[D].硕士论文.西安电子科技大学,2005.1.
[561何彬.电力系统二次设备的电磁兼容问题[J].中国电力,1998.31(4):46-50.
[57]崔翔.电力系统电磁兼容研究进展[J].电力系统自动化,2003.27(4):1-5.
[58]卢铁兵,崔翔.变电站空载母线波过程的数值分析[J].中国电机工程学报,2000.20(6):39-42.
[59]李清泉,李彦明,牛亚民.变电站开关操作引起的瞬变电磁场及其防护[J].高电压技术,2001.27(4):35-37.
[60]刘帆,陈柏超,卞利钢.变电站二次电缆屏蔽层接地方式探讨[J].电网技术,2003.27(2):63-67.
[70]莫付江,阮江军,陈允平.浪涌抑制与电磁兼容[J].电网技术,2004.28(5):69-72.
[71]汪东艳,张林昌.电力电子装置电磁兼容性的研究进展[J].电工技术学报,2000.15(1):47-51.
[72]和军平,姜建国,陈斌.电力电子装置传导电磁干扰特性测量的新方法[J].电力电子技术,2001.35(5):32-35.
[73]吴维宁,张文亮,吴峡.电力系统中电子设备抗干扰技术研究与应用[J].电力自动化设备,2001.21(6):20-22.
[74]吕庆敏.浅谈电力电子技术领域中若干的研究热点[J].电力电子技术,2001.35(1):61-62.
[75]孟进,马伟明,张磊等.基于IGBT开关暂态过程建模的功率变流器电磁干扰频谱估计[J].中国电机工程学报,2005.25(20):16-20.
[76]孟进,马伟明,张磊,等.开关电源变换器传导干扰分析及建模方法[J].中国电机工程学报,2005.25(5):49-54.
[77]裴雪军,康勇,熊健,等.PWM逆变器共模传导电磁干扰[J].中国电机工程学报,2004.24(8):83-88.
[78]和军平,陈为,姜建国.开关电源共模传导干扰模型的研究[J].中国电机工程学报,2005.25(s):50-55.
[79]李庆民,徐国政,siew W.基于静态同步补偿器的变电站中电磁辐射测试分析[J].中国电机工程学报,2003.23(11):33-35.
[80]李庆民,徐国政,siew W.基于SVC的变电站中电磁辐射测试分析[J].清华大学学报,2004.43(3):1-4.
[81]马伟明,涂吕期.AC/DC变流装置产生的电磁干扰分析[J].海军工程大学学,2000.24(3):1-4.
[82]汪东艳,张林昌.电力电子装置电磁兼容性的研究进展[J].电工技术学报,2000.15(1):47-51.
[83]温郑锉,陈玉燕.适用于PsPice的晶闸管开关模型[J].电力电子技术,1995(2):37-42.
[84]温家良,刘正之,傅鹏.一种简化晶闸管宏模型及其在暂态分析中的应用[J].电力电子技术,2002.36(2):66-68.
[85]赵中原,邱毓昌,于永明,等.用晶闸管宏模型分析换流阀内电压分布特性[J].电网技术,2003.27(9):33-36.
[86]邹刚,陈祥训,郑健超.一种微观一宏观相结合的晶闸管PSPICE模型[J].中国电机工程学报,1999.19(7):6-10.
[87]马莉.用pspleE仿真oTo的瞬态特性[J].电力电子技术,1996.30(4):90-93.
[88]张纯江,王长永,乌肠伟扬.用PSPICE多瞬态分析法建立GTO仿真模型[J].电力电子技术,1999.33(2):65-67.
[89]何相宁.用PSPICE多瞬态分析法建立新型电力电子器件的模型特性[J].电力电子技术,1995.29(3):62-66.
[90]周勇,吕中宾.IGCT及其逆变电路PSPICE仿真[J].电力自动化设备,2005.25(6):77-79.
[91]KuhnH,黄慧.IGCT无吸收和串联工作电路仿真的新型有效的物理模型[J].变流技术与电力牵引,2003.10(5):2-25.
[92]蔡丽娟,邹祖冰.新型功率器件MCT关断模型[J].华南理工大学学报,2004.32(I):29-32.
[93]孙元章,刘前进.FACTS控制技术综述——模型目标与策略[J].电力系统自动化,1999.23(6):1-7.
[94]姜齐荣,王强,韩英铎.ASVG的建模与控制[J].清华大学学报,1997.37(7):21-25.
[95]黄振宇,倪以信,陈寿孙.UPFC动态模型在电力系统动态分析中的实现[J].电力系统自动化,1999.23(6):26-30.
[96]戚庆茹,焦连伟,严正.统一潮流控制器的动态向量建模与仿真[J].电力系统自动化,2003.27(15):10-4.
[97]王庆红,胡国根.统一潮流控制器的Matlab仿真建模及分析[J].电网技术,2000.24(9):22-25.
[98]张东霞,童陆园,尹忠东.描述可控串补装置暂态特性的数学模型[J].中国电机学报,1999.19(5):30-34.
[99]赵学强,陈陈.晶闸管控制的串联电容补偿模型的综合研究[J].电力系统自动化,1999,23(6):31-35.
[100]李晓露,段献忠.用基频动态等值模型研究TCSC暂态[J].清华大学学报(自然科学版),1999.39(3):24-32.
[101]张爱国.SVC装置的Simulink实现和仿真[J].陕西电力,2007.35(5):55-58.
[102]杨吟梅.变电站内电磁兼容问题(二)——变电站内主要干扰源及其特性[J].电网技术,1997.21(3):72-75.
[103]杨吟梅.变电站内电磁兼容问题(四)——抑制电磁干扰的措施[J].电网技术,1997.21(5):67-74.
[104]张重远,梁贵书,崔翔.气体绝缘变电站内电压互感器高频传输函数模型的建立[J]. 电工技术杂志,2002.21(12):26-28.
[105]汪剑鸣,许镇琳.利用混沌提高dc/dc变换器的EMC能[J].电子科技大学学报,2006.33(5):586-589.
[106]郝绣,翁存海.电力电子设备的电磁干扰对策[J].船电技术,2000.20(3):52-57.
[107]张志华.EMI专用元件的选择和使用[J].安全与电磁兼容,1994.6(I):26-31.
[108]姜晓鸿.系统内电磁兼容性(EMC)问题的建模及其优化设计[J].系统工程与电子技术,1996.18(6):22-27.
[109]吴维宁,张文亮,吴峡.电力系统中电子设备抗干扰技术研究与应用[J].电力自动化设备,2001.21(6):20-22.
[110]颜慧,钱卫东.开关电源电磁干扰的产生和抑制措施[J].广东水利电力职业技术学院学报,2005.3(3):47-49.
[111]叶志琼.电子设备的电磁兼容技术[J].通信电源技术,2005.22(1):37-40.
[112]刘宝殿,卢民牛,王南.无线电话射频感应传导干扰抗扰度测试[S].安全与电磁兼容,2003.(4):23-29.
[113]雷新.电源EMI滤波器的设计特性及其选取原则[J].电磁兼容设计与检测,2002.(4):5054.
[114]Sun, Li:Nie, Jianhong:WU, Fengjiang. StodyoneonduetedEMIsuPPressionmethod adjustablesPeedSystem[C], International Power Eleetronies Congress-CIEP, 9thIEEEInte PowerEleetroniesCongress-TehniealProeeeding. CIEP2004:230-235.
[115]林民杰.浅谈软开关电源[J].现代电影技术,2007.(6):31-33.
[116]陈小龙一种软开关电源的设计和研究[J].开关电源技术,2006.(3):5-7.
[117]王会立.开关电源的电磁兼容设计[J].电源技术应用,2003.6(4):152-155
[2]沙斐.机电一体化系统的EMC技术[M].北京:中国电力出版社,1999.7.
[3]杨克俊.EMC原理与设计技术[M].北京:人民邮电出版社,2004.8.
[4]区建昌.电子设备的EMC设计[M].北京:电子工业出版社,2003.9.
[5]周旭.电子设备防干扰技术原理与技术[M].北京:国防工业出版社,2005(6):33.
[6]陈昌金.军用伺服驱动器的电磁兼容分析与研究[D].硕士论文.电子科技大学.2008.10
[7]邱扬.田锦.EMC设计技术[M].西安:西安电子科技大学,2001.8.
[8]杨克俊.EMC原理与设计技术[M].北京:人民邮电出版社,2004.6.
[9]孟进,马伟明,张磊,潘启军,赵治华.变换器传导电磁千扰集中等效模型参数估计方法[J].电工技术学报,2005.20(6).
[10]和军平,姜建国,陈斌.电力电子装置传导电磁干扰特性测量的新方法[Z].电力电子技术,2001.5.
[11]陈斌,姜建国,孙旭东.PWM逆变器感应电机驱动系统中接地电流EMI问题的分析[Z].中国电机工程学报,2003.23(2).
[12]和军平,陈为,姜建国.开关电源共模传导干扰模型的研究[J].中国电机工程学报.2005.25(8):50-55.
[13]Dr. Todd H. Hubing. Survey of Numerical Electromagnetic Modeling Techniques. [R].UMR EMC Lab:Universiy of Missouri-Rolla Electromagnetic Compatibiliy Laboratory Technical Reports.1991.
[14]Bruce Arcbambeault. Modeling and Simulation Validation for EMC Applications. IEEE International Symposium on Electromagnetic Compatibiliy. 1999 (1):492-496.
[15]Bruce Arcbambeault. Concerns and Approaches for Accurate EMC Simulation Validation.2003 IEEE International Symposium on Electromagnetic Compatibiliy.
[16]R. Neurnayer. Continuous Simulation of System-Level Automotive EMC Problems. IEEE Symposium on Electromagnetic Compatibiliy 2003(1):409-413.
[17]张玉莲.电子设备电磁兼容仿真建模研究.硕士论文.西安电子科技大学,2007.1
[18]刘国强.Ansoft工程电磁场有限元分析[M].北京:电子工业出版社,2006.2.
[19]金建铭,电磁场有限元方法[M].西安:西安电子科技大学出版社,1998.3.
[20]盛新庆.计算电磁学要论[M].北京:科学出版社,2005.6.
[21]王长清,祝西里.电磁场计算中的时域有限差分法[M].北京:北京大学出版社,1990.9.
[22]朱加铭,欧贵宝,何蕴增.有限元与边界元法[M].哈尔滨:哈尔滨工程大学出版社,2002.1.
[23]尹海平.传导性电磁兼容关键技术研究[D].硕士论文.南京师范大学,2008.6
[24]赵阳,李世锦等.传导性EMI噪声的模态分离与噪声抑制问题探讨[J].南京师范大学学报(工程技术版),2004,vol.4,No.4,1-4.
[25]Kye Yak See, Junhong Deng. Measurement of noise source imPedanee of SMPS using a two current probes approach, IEEE transactions on Power Electronies.2004. VOI.19, No.3,862-868.
[26]Franco Fiori, Vincenzo. P, Modified gummel-poon model for susceptibility prediction[J]. IEEE transactions on electromagnetic compatibility,2000. 42(2):206-213.
[27]张文彬,通信产品电子线路EMC的分析与预测[D],哈尔宾工业大学,信息科学与技术学院,2001.7.
[28]谭波.汽车电子控制系统的电磁兼容性研究[D].硕士论文.重庆大学,2009.5.
[29]靳江红,EMC的计算机预测[J],中国职业安全卫生管理体系认证,2001,(4):42-43;
[30]Seibert G, Metzner D, Klotz F. Behavioral modelling of ICs for investigations of conducted emissions in automotive systems[C] 17th International Zurich Symposium on Electromagnetic Compatibility,2006.27(2):356-358.
[31]Hara O M, Colebrooke J. Automotive EMC test harnesses:standard lengths and their effect on conducted emissions IEEE International Symposium on Electromagnetic Compatibility[C],2003.11 (5):233-236.
[32]Makaran J E, Lovetri J. Prediction of conducted RFI emissions in BLDC motors for automotive applications[C]. IEEE International Symposium on Electromagnetic Compatibility,2001.1 (8):21-25.
[33]Loeckx J, Gielen G. Efficient identification of major contributions to EMI-induced rectification effects in analog automotive circuits[C].17th International Zurich Symposium on Electromagnetic Compatibility,2006.27 (2):148-151.
[34]王健,高勇.汽车电子转向器电磁传导敏感度测试技术研究[J],西安理工大学学报,2007.23(2):168-171.
[35]马喜来.汽车电磁兼容性预估计的研究[D].博士论文.吉林大学,2008.4
[36]Piazza Di, Ragusa A.A model of electromagnetic radiated emissions for dual automotive electrical systems[C]. IEEE International Symposium on industrial Elec 2004.1(5):317-322.
[37]Sun Shishuang, Drewniak J, Pommerenke D. Common-mode radiation resultin handassembled cable bundles on automotive platforms[C]. IEEE International SymposElectromagnetic Compatibility,2006.2 (8):298-303.
[38]汪泉弟,刘春艳,俞集辉.汽车火花点火系统电磁干扰的抑制方法[J].重庆大学学报(自然科学版),2007.30(7):46-49.
[39]Ankarson, P., Carlsson, J. FDTD simulation of the electrical environment for vehicles by using CAD data[C]. Electromagnetic Compatibility,2002 3rd International Symposium on 21-24 May 2002:272-275.
[40]Anzaldi, G., Riu, P. J., Fernandez, M., Silva, F. Validation procedure for final users applied to automotive environments[C]. Validation of Computational Electromagnetic,IEE Seminar on 30 March 2004:43-47.
[41]Reineix, A., Jecko, F., Jecko, B. Time Domain Modeling Techniques improvement for new EMC problems[C]. Electromagnetic Compatibility,1997. IEEE 1997 International Symposium on 18-22 Aug.1997:231-235.
[42]Chingchi Chen. Predicting Vehicle-Level Radiated EMI Emissions Using Module-Level Conducted EMIs and Harness Radiation Efficiencies [C]. Electromagnetic Compatibility,2001.EMC.2001 IEEE International Symposium on Volume 2,13-17 Aug.2001,1146-1151 vol.2.
[43]Geping Liu, Chingchi Chen, Yuhua Tu, Drewniak, J. L. Anticipating full vehicle radiated EMI from module-level testing in automobiles[C]. Electromagnetic Compatibility,2002 IEEE International Symposium on Volume 2,19-23 Aug.2002:982-986.
[44]Shiraki, Y., Sugahara, K., Tanabe, S., Nakamoto, K., Watanabe, T. Electromagnetic field distribution inside an automobile vehicle[C]. Electromagnetic Compatibility,2003 IEEE International Symposium on Volume 2,18-22 Aug.2003:730-734.
[45]Anzaldi, G., Riu, P. J., Silva, F., Santos, R. Finite difference time domain low cost modeling for automotive environments. Electromagnetic Compatibility[C].EMC2004.2004 International Symposium on Volume 3.9-13 Aug.2004:775-780.
[46]徐立.汽车电磁干扰及其影响[J].汽车电子应用,2006.2:46-49.
[47]陈天殷.汽车电器电磁兼容性及电磁干扰的抑制[J].汽车电器,2007.1:56-59.
[48]余勇,李建秋,周明等,车用柴油机ECU的电磁兼容性分析与设计[J].汽车工程,2001.6,23(6):395-400.
[49]张臻,先进汽车电子控制单元ECU的改进与发展[J].机械与电子,2006.7:36-38.
[50]李鸿强,刘志春等,汽车电子控制单元ECU的设计[J].汽车电子,2006.22(11):271-274.
[51]赖后翔.高频开关电源DC-DC模块的研究[D].硕士论文,湖南大学,2003.4.
[52]王鸿麟,景占荣.通信基础电源(第二版)[M].西安:西安电子科技大学出版社,2002.2.
[53]王虎刚.平均电流模式高效降压型DC-DC集成电路设计[D].硕士论文,西安电子科技大学,2005.1.
[54]华伟.通信开关电源的五种PWM反馈控制模式研究[J].通信电源技术,2005.2.
[55]胡为东.多电源系统的高速PCB设计[D].硕士论文.西安电子科技大学,2005.1.
[561何彬.电力系统二次设备的电磁兼容问题[J].中国电力,1998.31(4):46-50.
[57]崔翔.电力系统电磁兼容研究进展[J].电力系统自动化,2003.27(4):1-5.
[58]卢铁兵,崔翔.变电站空载母线波过程的数值分析[J].中国电机工程学报,2000.20(6):39-42.
[59]李清泉,李彦明,牛亚民.变电站开关操作引起的瞬变电磁场及其防护[J].高电压技术,2001.27(4):35-37.
[60]刘帆,陈柏超,卞利钢.变电站二次电缆屏蔽层接地方式探讨[J].电网技术,2003.27(2):63-67.
[70]莫付江,阮江军,陈允平.浪涌抑制与电磁兼容[J].电网技术,2004.28(5):69-72.
[71]汪东艳,张林昌.电力电子装置电磁兼容性的研究进展[J].电工技术学报,2000.15(1):47-51.
[72]和军平,姜建国,陈斌.电力电子装置传导电磁干扰特性测量的新方法[J].电力电子技术,2001.35(5):32-35.
[73]吴维宁,张文亮,吴峡.电力系统中电子设备抗干扰技术研究与应用[J].电力自动化设备,2001.21(6):20-22.
[74]吕庆敏.浅谈电力电子技术领域中若干的研究热点[J].电力电子技术,2001.35(1):61-62.
[75]孟进,马伟明,张磊等.基于IGBT开关暂态过程建模的功率变流器电磁干扰频谱估计[J].中国电机工程学报,2005.25(20):16-20.
[76]孟进,马伟明,张磊,等.开关电源变换器传导干扰分析及建模方法[J].中国电机工程学报,2005.25(5):49-54.
[77]裴雪军,康勇,熊健,等.PWM逆变器共模传导电磁干扰[J].中国电机工程学报,2004.24(8):83-88.
[78]和军平,陈为,姜建国.开关电源共模传导干扰模型的研究[J].中国电机工程学报,2005.25(s):50-55.
[79]李庆民,徐国政,siew W.基于静态同步补偿器的变电站中电磁辐射测试分析[J].中国电机工程学报,2003.23(11):33-35.
[80]李庆民,徐国政,siew W.基于SVC的变电站中电磁辐射测试分析[J].清华大学学报,2004.43(3):1-4.
[81]马伟明,涂吕期.AC/DC变流装置产生的电磁干扰分析[J].海军工程大学学,2000.24(3):1-4.
[82]汪东艳,张林昌.电力电子装置电磁兼容性的研究进展[J].电工技术学报,2000.15(1):47-51.
[83]温郑锉,陈玉燕.适用于PsPice的晶闸管开关模型[J].电力电子技术,1995(2):37-42.
[84]温家良,刘正之,傅鹏.一种简化晶闸管宏模型及其在暂态分析中的应用[J].电力电子技术,2002.36(2):66-68.
[85]赵中原,邱毓昌,于永明,等.用晶闸管宏模型分析换流阀内电压分布特性[J].电网技术,2003.27(9):33-36.
[86]邹刚,陈祥训,郑健超.一种微观一宏观相结合的晶闸管PSPICE模型[J].中国电机工程学报,1999.19(7):6-10.
[87]马莉.用pspleE仿真oTo的瞬态特性[J].电力电子技术,1996.30(4):90-93.
[88]张纯江,王长永,乌肠伟扬.用PSPICE多瞬态分析法建立GTO仿真模型[J].电力电子技术,1999.33(2):65-67.
[89]何相宁.用PSPICE多瞬态分析法建立新型电力电子器件的模型特性[J].电力电子技术,1995.29(3):62-66.
[90]周勇,吕中宾.IGCT及其逆变电路PSPICE仿真[J].电力自动化设备,2005.25(6):77-79.
[91]KuhnH,黄慧.IGCT无吸收和串联工作电路仿真的新型有效的物理模型[J].变流技术与电力牵引,2003.10(5):2-25.
[92]蔡丽娟,邹祖冰.新型功率器件MCT关断模型[J].华南理工大学学报,2004.32(I):29-32.
[93]孙元章,刘前进.FACTS控制技术综述——模型目标与策略[J].电力系统自动化,1999.23(6):1-7.
[94]姜齐荣,王强,韩英铎.ASVG的建模与控制[J].清华大学学报,1997.37(7):21-25.
[95]黄振宇,倪以信,陈寿孙.UPFC动态模型在电力系统动态分析中的实现[J].电力系统自动化,1999.23(6):26-30.
[96]戚庆茹,焦连伟,严正.统一潮流控制器的动态向量建模与仿真[J].电力系统自动化,2003.27(15):10-4.
[97]王庆红,胡国根.统一潮流控制器的Matlab仿真建模及分析[J].电网技术,2000.24(9):22-25.
[98]张东霞,童陆园,尹忠东.描述可控串补装置暂态特性的数学模型[J].中国电机学报,1999.19(5):30-34.
[99]赵学强,陈陈.晶闸管控制的串联电容补偿模型的综合研究[J].电力系统自动化,1999,23(6):31-35.
[100]李晓露,段献忠.用基频动态等值模型研究TCSC暂态[J].清华大学学报(自然科学版),1999.39(3):24-32.
[101]张爱国.SVC装置的Simulink实现和仿真[J].陕西电力,2007.35(5):55-58.
[102]杨吟梅.变电站内电磁兼容问题(二)——变电站内主要干扰源及其特性[J].电网技术,1997.21(3):72-75.
[103]杨吟梅.变电站内电磁兼容问题(四)——抑制电磁干扰的措施[J].电网技术,1997.21(5):67-74.
[104]张重远,梁贵书,崔翔.气体绝缘变电站内电压互感器高频传输函数模型的建立[J]. 电工技术杂志,2002.21(12):26-28.
[105]汪剑鸣,许镇琳.利用混沌提高dc/dc变换器的EMC能[J].电子科技大学学报,2006.33(5):586-589.
[106]郝绣,翁存海.电力电子设备的电磁干扰对策[J].船电技术,2000.20(3):52-57.
[107]张志华.EMI专用元件的选择和使用[J].安全与电磁兼容,1994.6(I):26-31.
[108]姜晓鸿.系统内电磁兼容性(EMC)问题的建模及其优化设计[J].系统工程与电子技术,1996.18(6):22-27.
[109]吴维宁,张文亮,吴峡.电力系统中电子设备抗干扰技术研究与应用[J].电力自动化设备,2001.21(6):20-22.
[110]颜慧,钱卫东.开关电源电磁干扰的产生和抑制措施[J].广东水利电力职业技术学院学报,2005.3(3):47-49.
[111]叶志琼.电子设备的电磁兼容技术[J].通信电源技术,2005.22(1):37-40.
[112]刘宝殿,卢民牛,王南.无线电话射频感应传导干扰抗扰度测试[S].安全与电磁兼容,2003.(4):23-29.
[113]雷新.电源EMI滤波器的设计特性及其选取原则[J].电磁兼容设计与检测,2002.(4):5054.
[114]Sun, Li:Nie, Jianhong:WU, Fengjiang. StodyoneonduetedEMIsuPPressionmethod adjustablesPeedSystem[C], International Power Eleetronies Congress-CIEP, 9thIEEEInte PowerEleetroniesCongress-TehniealProeeeding. CIEP2004:230-235.
[115]林民杰.浅谈软开关电源[J].现代电影技术,2007.(6):31-33.
[116]陈小龙一种软开关电源的设计和研究[J].开关电源技术,2006.(3):5-7.
[117]王会立.开关电源的电磁兼容设计[J].电源技术应用,2003.6(4):152-155
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |