Recently,radiated electromagnetic interference(EMI)has become a research hotspot in power electronics systems,as the switching frequencies of power electronics systems have increased significantly with the adoption of...Recently,radiated electromagnetic interference(EMI)has become a research hotspot in power electronics systems,as the switching frequencies of power electronics systems have increased significantly with the adoption of wide-bandgap devices.In this article,a generalized radiated EMI model for power electronics converters with power cables is first reviewed.The radiated EMI model is then developed for a flyback power converter with critical ground impedance included.Based on the developed model,accurate high-frequency parameter extraction techniques and a radiated EMI prediction technique are developed and experimentally validated.Finally,essential measurement techniques are identified and developed to accurately extract parameters for accurate EMI prediction.The effects of the resolution bandwidth of the spectrum analyzer and critical PCB ground impedance on the radiated EMI are experimentally validated.PCB’s impact on the common-mode(CM)choke’s impedance and the radiated EMI is further validated.Techniques for minimizing the undesired near-field couplings in parameter extraction are discussed.The predicted EMI properly agreed with the measured EMI in the range of 30-230 MHz based on the EN550323 m class B standard.展开更多
Flyback converters in consumer and commercial products must adhere to strict regulatory standards for conducted and radiated electromagnetic interference(EMI).Managing EMI has become increasingly complex in mod-ern po...Flyback converters in consumer and commercial products must adhere to strict regulatory standards for conducted and radiated electromagnetic interference(EMI).Managing EMI has become increasingly complex in mod-ern power electronics,particularly with the integration of high-speed wide bandgap(WBG)devices into compact sys-tem layouts.A review of established modeling techniques and mitigation strategies for conducted EMI is presented,fo-cusing on differential mode(DM)and common mode(CM)noise,alongside radiated EMI in flyback converters.The discussion encompasses solutions at both component-level design and converter system optimization.展开更多
文摘Recently,radiated electromagnetic interference(EMI)has become a research hotspot in power electronics systems,as the switching frequencies of power electronics systems have increased significantly with the adoption of wide-bandgap devices.In this article,a generalized radiated EMI model for power electronics converters with power cables is first reviewed.The radiated EMI model is then developed for a flyback power converter with critical ground impedance included.Based on the developed model,accurate high-frequency parameter extraction techniques and a radiated EMI prediction technique are developed and experimentally validated.Finally,essential measurement techniques are identified and developed to accurately extract parameters for accurate EMI prediction.The effects of the resolution bandwidth of the spectrum analyzer and critical PCB ground impedance on the radiated EMI are experimentally validated.PCB’s impact on the common-mode(CM)choke’s impedance and the radiated EMI is further validated.Techniques for minimizing the undesired near-field couplings in parameter extraction are discussed.The predicted EMI properly agreed with the measured EMI in the range of 30-230 MHz based on the EN550323 m class B standard.
文摘Flyback converters in consumer and commercial products must adhere to strict regulatory standards for conducted and radiated electromagnetic interference(EMI).Managing EMI has become increasingly complex in mod-ern power electronics,particularly with the integration of high-speed wide bandgap(WBG)devices into compact sys-tem layouts.A review of established modeling techniques and mitigation strategies for conducted EMI is presented,fo-cusing on differential mode(DM)and common mode(CM)noise,alongside radiated EMI in flyback converters.The discussion encompasses solutions at both component-level design and converter system optimization.
