Reconfigurable surface acoustic wave(SAW)phase shifters have garnered significant attention owing to their potential applications in emerging fields such as secure wireless communication,adaptable signal processing,an...Reconfigurable surface acoustic wave(SAW)phase shifters have garnered significant attention owing to their potential applications in emerging fields such as secure wireless communication,adaptable signal processing,and intelligent sensing systems.Among various modulation methods,employing gate voltage-controlled tuning methodologies that leverage acoustoelectric interactions has proven to be an efficient modulation approach that requires a low bias voltage.However,current acoustoelectric devices suffer from limited tunability,intricate heterogeneous structures,and complex manufacturing processes,all of which impede their practical applications.In this study,we present a novel material system for voltage-tunable SAW phase shifters.This system incorporates an atomic layer deposition ZnO thin-film transistors on LiNbO_(3)structure.This structure combines the benefits of LiNbO_(3)'s high electromechanical coupling coefficient(K^(2))and ZnO's superior conductivity adjustability.Besides,the device possesses a simplified structural configuration,which is easy to fabricate.Devices with different mesa lengths were fabricated and measured,and two of the different modes were compared.The results indicate that both the maximum phase shift and attenuation of the Rayleigh mode and longitudinal leaky SAW(LLSAW)increase proportionally with mesa length.Furthermore,LLSAW with larger effective electromechanical coupling coefficients(K_(eff)^(2))values exhibits greater phase velocity shifts and attenuation coefficients,with a maximum phase velocity tuning of 1.22%achieved.It is anticipated that the proposed devices will find utility in a variety of applications necessitating tunable acoustic components.展开更多
Medium voltage distribution networks usually suffer from single-ground arcing fault,especially high impedance arcing fault.Moreover,induced intermittent arcing faults can severely endanger the reliability and safety o...Medium voltage distribution networks usually suffer from single-ground arcing fault,especially high impedance arcing fault.Moreover,induced intermittent arcing faults can severely endanger the reliability and safety of power systems.The arc model is important for high impedance arcing fault suppression and detection to effectively eliminate the single-ground arcing fault.This paper proposes an improved arc model,which is concise and explicit,based on a single-ground arcing fault conducted on a 10 kV experimental platform under different fault conditions.Characteristic parameters of single-ground arcing faults are obtained based on test results.Furthermore,characteristic parameters under different fault conditions of the improved arc model are presented.Finally,verification of the improved arc model is supported by PSCAD-EMTDC.Comparisons of the proposed arc model between three typical black-box arc models indicate that the proposed model has better performance and higher accuracy than that of the three typical arc models as fault resistance is in a range of 0.1 kΩto 2.4 kΩ.Thus,its accuracy is acceptable and it is helpful to the simulation and suppression of arc fault overvoltage.展开更多
基金supported by National Natural Science Foundation of China(Grant Nos:62122004 and 62274082)Beijing Natural Science Foundation(Grant No.Z210006)+5 种基金Hong Kong Research Grant Council(Grant Nos.27206321,17205922,17212923,C1009-22G and T45-701/22-R)Shenzhen Science and Technology Innovation Commission(SGDX20220530111405040,JCYJ20220530115411025 and JCYJ20210324120409025)Research on mechanism of source/drain ohmic contact and the related Ga N p-FET(Grant No:2023A1515030034)Research on high-reliable Ga N power device and the related industrial power system(Grant No:HZQB-KCZYZ-2021052)supported by ACCESS-AI Chip Center for Emerging Smart Systems,sponsored by Innovation and Technology Fund(ITF),Hong Kong SARthe assistance of SUSTech Core Research Facilities。
文摘Reconfigurable surface acoustic wave(SAW)phase shifters have garnered significant attention owing to their potential applications in emerging fields such as secure wireless communication,adaptable signal processing,and intelligent sensing systems.Among various modulation methods,employing gate voltage-controlled tuning methodologies that leverage acoustoelectric interactions has proven to be an efficient modulation approach that requires a low bias voltage.However,current acoustoelectric devices suffer from limited tunability,intricate heterogeneous structures,and complex manufacturing processes,all of which impede their practical applications.In this study,we present a novel material system for voltage-tunable SAW phase shifters.This system incorporates an atomic layer deposition ZnO thin-film transistors on LiNbO_(3)structure.This structure combines the benefits of LiNbO_(3)'s high electromechanical coupling coefficient(K^(2))and ZnO's superior conductivity adjustability.Besides,the device possesses a simplified structural configuration,which is easy to fabricate.Devices with different mesa lengths were fabricated and measured,and two of the different modes were compared.The results indicate that both the maximum phase shift and attenuation of the Rayleigh mode and longitudinal leaky SAW(LLSAW)increase proportionally with mesa length.Furthermore,LLSAW with larger effective electromechanical coupling coefficients(K_(eff)^(2))values exhibits greater phase velocity shifts and attenuation coefficients,with a maximum phase velocity tuning of 1.22%achieved.It is anticipated that the proposed devices will find utility in a variety of applications necessitating tunable acoustic components.
基金supported by National Natural Science Foundation of China under Grant No.51477018 and No.52077019。
文摘Medium voltage distribution networks usually suffer from single-ground arcing fault,especially high impedance arcing fault.Moreover,induced intermittent arcing faults can severely endanger the reliability and safety of power systems.The arc model is important for high impedance arcing fault suppression and detection to effectively eliminate the single-ground arcing fault.This paper proposes an improved arc model,which is concise and explicit,based on a single-ground arcing fault conducted on a 10 kV experimental platform under different fault conditions.Characteristic parameters of single-ground arcing faults are obtained based on test results.Furthermore,characteristic parameters under different fault conditions of the improved arc model are presented.Finally,verification of the improved arc model is supported by PSCAD-EMTDC.Comparisons of the proposed arc model between three typical black-box arc models indicate that the proposed model has better performance and higher accuracy than that of the three typical arc models as fault resistance is in a range of 0.1 kΩto 2.4 kΩ.Thus,its accuracy is acceptable and it is helpful to the simulation and suppression of arc fault overvoltage.
