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Theoretical and Experimental Study on Transient Electrical Behavior of Coaxial Bandpass Filter With Low-Pressure Microwave Breakdown
Gas ionization causing low-pressure discharge is a major limitation for the performance of microwave components. Simple structures such as coaxial, waveguide, and resonators have been relatively easier to predict the low-pressure discharge effect compared to complex microwave components, which remai...
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| Published in: | IEEE transactions on microwave theory and techniques 2024-10, Vol.72 (10), p.5667-5678 |
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| container_end_page | 5678 |
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| container_title | IEEE transactions on microwave theory and techniques |
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| creator | Peng, Yubin Mao, Zhangsong Zhao, Xiaolong Xu, Juncheng Zeng, Mingqi Peng, Wenbo Chen, Xiong He, Yongning Yu, Ming |
| description | Gas ionization causing low-pressure discharge is a major limitation for the performance of microwave components. Simple structures such as coaxial, waveguide, and resonators have been relatively easier to predict the low-pressure discharge effect compared to complex microwave components, which remain challenging to accurately anticipate. There is still insufficient systematic research on transient response in this context. Consequently, analyzing the transient electrical behavior becomes essential when examining the mechanism of an electronic system's response to gas discharge in an avalanche-like manner. This article aims to present a quantitative method revealing the relationship between microwave breakdown and system response in a fourth-order bandpass coaxial cavity filter. Initially, the inside field simulation is utilized to predict the microwave breakdown position in the filter. Additionally, the gas ignition transient process is simulated through the Monte-Carlo method, while considering electron-surface interaction and gas ionization. The experiments were conducted over a pressure range of 100-1000 Pa. It was observed that the breakdown phenomenon occurred in the input resonant cavity as predicted by the simulation, and the measured breakdown power threshold characteristic was consistent with the theoretical simulation. Furthermore, by utilizing the forward and reverse power cancellation signals, the transient impedance change upon breakdown was obtained without the use of any probes. It was revealed that the electrical behavior of the ionized gas, plasma, shifted from a capacitive load to an inductive load with an increase in gas pressure. The measured transient impedance characteristics showed a convex curve as the gas pressure increased, while the breakdown power threshold curve of the filter displayed a concave shape. This work verified an accurate simulation approach for predicting the ionization breakdown power for complex components and proposed an effective quantitative assessment method for the transient impedance change of the system response after breakdown occurs. |
| doi_str_mv | 10.1109/TMTT.2024.3386950 |
| format | article |
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Simple structures such as coaxial, waveguide, and resonators have been relatively easier to predict the low-pressure discharge effect compared to complex microwave components, which remain challenging to accurately anticipate. There is still insufficient systematic research on transient response in this context. Consequently, analyzing the transient electrical behavior becomes essential when examining the mechanism of an electronic system's response to gas discharge in an avalanche-like manner. This article aims to present a quantitative method revealing the relationship between microwave breakdown and system response in a fourth-order bandpass coaxial cavity filter. Initially, the inside field simulation is utilized to predict the microwave breakdown position in the filter. Additionally, the gas ignition transient process is simulated through the Monte-Carlo method, while considering electron-surface interaction and gas ionization. The experiments were conducted over a pressure range of 100-1000 Pa. It was observed that the breakdown phenomenon occurred in the input resonant cavity as predicted by the simulation, and the measured breakdown power threshold characteristic was consistent with the theoretical simulation. Furthermore, by utilizing the forward and reverse power cancellation signals, the transient impedance change upon breakdown was obtained without the use of any probes. It was revealed that the electrical behavior of the ionized gas, plasma, shifted from a capacitive load to an inductive load with an increase in gas pressure. The measured transient impedance characteristics showed a convex curve as the gas pressure increased, while the breakdown power threshold curve of the filter displayed a concave shape. This work verified an accurate simulation approach for predicting the ionization breakdown power for complex components and proposed an effective quantitative assessment method for the transient impedance change of the system response after breakdown occurs.</description><identifier>ISSN: 0018-9480</identifier><identifier>EISSN: 1557-9670</identifier><identifier>DOI: 10.1109/TMTT.2024.3386950</identifier><identifier>CODEN: IETMAB</identifier><language>eng</language><publisher>New York: IEEE</publisher><subject>Band-pass filters ; Bandpass cavity filter ; Bandpass filters ; Breakdown ; Cavity resonators ; Electric breakdown ; Electric discharges ; Electronic systems ; Electrons ; Gas discharges ; Gas ionization ; Gas pressure ; Impedance ; impedance change ; Low pressure ; low-pressure microwave breakdown ; Microwave communication ; Microwave filters ; Microwave theory and techniques ; Monte Carlo simulation ; Position measurement ; Pressure effects ; Quantitative analysis ; Resonator filters ; Simulation ; system response ; Transient response ; Waveguides</subject><ispartof>IEEE transactions on microwave theory and techniques, 2024-10, Vol.72 (10), p.5667-5678</ispartof><rights>Copyright The Institute of Electrical and Electronics Engineers, Inc. (IEEE) 2024</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><cites>FETCH-LOGICAL-c246t-598a2e3afeb509000e65e300693ac1356772fefdae25fdbe5f1679e75789bc4d3</cites><orcidid>0009-0003-9142-553X ; 0000-0003-3687-0780 ; 0000-0002-2419-2858 ; 0000-0002-9678-2347 ; 0000-0003-3008-2847</orcidid></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://ieeexplore.ieee.org/document/10509829$$EHTML$$P50$$Gieee$$H</linktohtml><link.rule.ids>314,780,784,27923,27924,54795</link.rule.ids></links><search><creatorcontrib>Peng, Yubin</creatorcontrib><creatorcontrib>Mao, Zhangsong</creatorcontrib><creatorcontrib>Zhao, Xiaolong</creatorcontrib><creatorcontrib>Xu, Juncheng</creatorcontrib><creatorcontrib>Zeng, Mingqi</creatorcontrib><creatorcontrib>Peng, Wenbo</creatorcontrib><creatorcontrib>Chen, Xiong</creatorcontrib><creatorcontrib>He, Yongning</creatorcontrib><creatorcontrib>Yu, Ming</creatorcontrib><title>Theoretical and Experimental Study on Transient Electrical Behavior of Coaxial Bandpass Filter With Low-Pressure Microwave Breakdown</title><title>IEEE transactions on microwave theory and techniques</title><addtitle>TMTT</addtitle><description>Gas ionization causing low-pressure discharge is a major limitation for the performance of microwave components. Simple structures such as coaxial, waveguide, and resonators have been relatively easier to predict the low-pressure discharge effect compared to complex microwave components, which remain challenging to accurately anticipate. There is still insufficient systematic research on transient response in this context. Consequently, analyzing the transient electrical behavior becomes essential when examining the mechanism of an electronic system's response to gas discharge in an avalanche-like manner. This article aims to present a quantitative method revealing the relationship between microwave breakdown and system response in a fourth-order bandpass coaxial cavity filter. Initially, the inside field simulation is utilized to predict the microwave breakdown position in the filter. Additionally, the gas ignition transient process is simulated through the Monte-Carlo method, while considering electron-surface interaction and gas ionization. The experiments were conducted over a pressure range of 100-1000 Pa. It was observed that the breakdown phenomenon occurred in the input resonant cavity as predicted by the simulation, and the measured breakdown power threshold characteristic was consistent with the theoretical simulation. Furthermore, by utilizing the forward and reverse power cancellation signals, the transient impedance change upon breakdown was obtained without the use of any probes. It was revealed that the electrical behavior of the ionized gas, plasma, shifted from a capacitive load to an inductive load with an increase in gas pressure. The measured transient impedance characteristics showed a convex curve as the gas pressure increased, while the breakdown power threshold curve of the filter displayed a concave shape. This work verified an accurate simulation approach for predicting the ionization breakdown power for complex components and proposed an effective quantitative assessment method for the transient impedance change of the system response after breakdown occurs.</description><subject>Band-pass filters</subject><subject>Bandpass cavity filter</subject><subject>Bandpass filters</subject><subject>Breakdown</subject><subject>Cavity resonators</subject><subject>Electric breakdown</subject><subject>Electric discharges</subject><subject>Electronic systems</subject><subject>Electrons</subject><subject>Gas discharges</subject><subject>Gas ionization</subject><subject>Gas pressure</subject><subject>Impedance</subject><subject>impedance change</subject><subject>Low pressure</subject><subject>low-pressure microwave breakdown</subject><subject>Microwave communication</subject><subject>Microwave filters</subject><subject>Microwave theory and techniques</subject><subject>Monte Carlo simulation</subject><subject>Position measurement</subject><subject>Pressure effects</subject><subject>Quantitative analysis</subject><subject>Resonator filters</subject><subject>Simulation</subject><subject>system response</subject><subject>Transient response</subject><subject>Waveguides</subject><issn>0018-9480</issn><issn>1557-9670</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><recordid>eNpNkM1OwzAQhC0EEqXwAEgcLHFOseM4iY9QtYDUCiSCOFpuslZdQlzspD93HhyH9sBptaOZ3dGH0DUlI0qJuCvmRTGKSZyMGMtTwckJGlDOs0ikGTlFA0JoHokkJ-fowvtVWBNO8gH6KZZgHbSmVDVWTYUnuzU48wVNG4S3tqv22Da4cKrxJoh4UkPZuj_7AyzVxliHrcZjq3am18KNtfIeT03dgsMfpl3imd1Grw687xzguSmd3aoN4AcH6rOy2-YSnWlVe7g6ziF6n06K8VM0e3l8Ht_PojJO0jbiIlcxMKVhwYkghEDKgRGSCqZKyniaZbEGXSmIua4WwDVNMwEZz3KxKJOKDdHt4e7a2e8OfCtXtnNNeCkZDUASzhgPLnpwhZ7eO9ByHYAot5eUyB627GHLHrY8wg6Zm0PGAMA_f-iZx4L9Ao2-fXw</recordid><startdate>20241001</startdate><enddate>20241001</enddate><creator>Peng, Yubin</creator><creator>Mao, Zhangsong</creator><creator>Zhao, Xiaolong</creator><creator>Xu, Juncheng</creator><creator>Zeng, Mingqi</creator><creator>Peng, Wenbo</creator><creator>Chen, Xiong</creator><creator>He, Yongning</creator><creator>Yu, Ming</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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Simple structures such as coaxial, waveguide, and resonators have been relatively easier to predict the low-pressure discharge effect compared to complex microwave components, which remain challenging to accurately anticipate. There is still insufficient systematic research on transient response in this context. Consequently, analyzing the transient electrical behavior becomes essential when examining the mechanism of an electronic system's response to gas discharge in an avalanche-like manner. This article aims to present a quantitative method revealing the relationship between microwave breakdown and system response in a fourth-order bandpass coaxial cavity filter. Initially, the inside field simulation is utilized to predict the microwave breakdown position in the filter. Additionally, the gas ignition transient process is simulated through the Monte-Carlo method, while considering electron-surface interaction and gas ionization. The experiments were conducted over a pressure range of 100-1000 Pa. It was observed that the breakdown phenomenon occurred in the input resonant cavity as predicted by the simulation, and the measured breakdown power threshold characteristic was consistent with the theoretical simulation. Furthermore, by utilizing the forward and reverse power cancellation signals, the transient impedance change upon breakdown was obtained without the use of any probes. It was revealed that the electrical behavior of the ionized gas, plasma, shifted from a capacitive load to an inductive load with an increase in gas pressure. The measured transient impedance characteristics showed a convex curve as the gas pressure increased, while the breakdown power threshold curve of the filter displayed a concave shape. 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| subjects | Band-pass filters Bandpass cavity filter Bandpass filters Breakdown Cavity resonators Electric breakdown Electric discharges Electronic systems Electrons Gas discharges Gas ionization Gas pressure Impedance impedance change Low pressure low-pressure microwave breakdown Microwave communication Microwave filters Microwave theory and techniques Monte Carlo simulation Position measurement Pressure effects Quantitative analysis Resonator filters Simulation system response Transient response Waveguides |
| title | Theoretical and Experimental Study on Transient Electrical Behavior of Coaxial Bandpass Filter With Low-Pressure Microwave Breakdown |
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