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博士論文

Multi-Band Bandpass Filters and Filtering Power Dividers Based on Dual-Mode Resonators

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DOI[10.24561/00019021]to the data of the same series

Multi-Band Bandpass Filters and Filtering Power Dividers Based on Dual-Mode Resonators

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博士論文
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文, 品
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埼玉大学大学院理工学研究科
Date granted
2019-09-20
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埼玉大学,博士(工学)
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Multi-band microwave components are expected to be used in modern high-integration wireless communication systems, which can support multi-services si...

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Multi-band microwave components are expected to be used in modern high-integration wireless communication systems, which can support multi-services si...

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Provided by:国立国会図書館デジタルコレクション

  • 2023-09-05 再収集

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Material Type
博士論文
Title
Multi-Band Bandpass Filters and Filtering Power Dividers Based on Dual-Mode Resonators
Author/Editor
文, 品
Author Heading
文, 品
Publication, Distribution, etc.
埼玉大学大学院理工学研究科
Publication Date
2019
Publication Date (W3CDTF)
2019
Alternative Title
デュアルモード共振器を用いたマルチバンド帯域通過フィルタとフィルタリングパワーディバイダに関する研究
Periodical title
博士論文(埼玉大学大学院理工学研究科(博士後期課程))
Degree Grantor
埼玉大学
Date Granted
2019-09-20
Date Granted (W3CDTF)
2019-09-20
Dissertation Number
甲第1140号
Degree Type
博士(工学)
Conferring No. (Dissertation)
甲第1140号
Text Language Code
eng
Target Audience
一般
Note (General)
Multi-band microwave components are expected to be used in modern high-integration wireless communication systems, which can support multi-services simultaneously without adding additional receive or transmit links. For this reason, multi-band microwave components are attracting great attention and becoming research hotspot in microwave passive components domain. Particularly, in the development of multi-band bandpass filters (BPFs) and filtering power dividers (FPDs), how to realize high selectivity, small circuit size, low loss, wide stopband, and flexible control of the channel frequencies and bandwidths are challenging problems. Moreover, balanced-to-unbalanced (BTU) filtering power divider is also one of the key passive components in RF/microwave front-ends for connecting the balanced ports and single-ended port to achieve conversion between balanced and unbalanced signals with common-mode noise suppression. This dissertation is intended to propose new types of multi-mode resonators (MMRs) and develop dual-band and tri-band BPFs, dual-band FPDs, and BTU filtering power dividers with small circuit size, independent control of channel frequencies and bandwidths, and other excellent frequency characteristics.Firstly, a novel type of stub-loaded stepped-impedance resonator (SL-SIR) is proposed. With different schematics of the loaded stubs, the SL-SIR has flexibly controllable dual-modes or tri-modes to construct dual-band or tri-band BPFs. Detailed mode analysis of the resonator is conducted, and parametric variations of the modes are investigated. Next, dual-band and tri-band BPFs are proposed and designed using the dual-mode or tri-mode SL-SIRs. Multiple geometrical parameters in both the external feeding structure and the internal couplings between neighboring resonators are employed to make the individual control of the two or three passbands possible. Furthermore, separately changeable multiple coupling paths between the resonators and the coupling paths between the source and load are devised to create multiple transmission zeros, which not only enhance significantly the selectivity of the passbands, but also widen greatly the stopband of the BPFs. A small H-shaped composite resonator is also proposed, and its even-mode and odd-mode are used to configure a miniaturized dual-band BPF with a flexible center frequency ratio. Three transmission zeros are produced by introducing a mixed electric and magnetic coupling between the resonators, which improves significantly the selectivity and out-band rejection performance. All the designed dual-band and tri-band BPFs are fabricated, and their measured frequency responses agree well with the theoretically predicted ones.Secondly, a novel compact dual-band filtering power divider (DB-FPD) is developed which can reduce significantly the circuit size of a RF/microwave front-end. The proposed DB-FPD consists of a small U-shaped Wilkinson power divider, two pairs of dual-resonance resonators (DRRs), and a pair of spur-lines. With the simultaneous use and appropriate design of the coupled feedlines, mixed electric and magnetic couplings between the DRRs, and spur-lines with different lengths, multiple TZs are produced which result in two passbands with desired power division, high frequency selectivity, good isolation, and an ultrawide stopband. A prototype DB-FPD is designed, fabricated and measured. The measured responses agree well with the design simulations, exhibiting a stopband up to 13.8 GHz (6f0) with 20-dB rejection level. This is the widest stopband of DB-FPDs reported thus far.Finally, two novel balanced to unbalanced filtering power dividers with variable bandwidth are proposed based on stub-loaded dual-mode resonators (SL-DMRs). Two SL-DMRs are used to replace the 90° horizontal transmission lines to realize filtering responses. With the even- and odd-mode analysis method and traditional transmission line theory, closed-form analytical equations and detail design procedures are derived. Moreover, a pair of parallel coupled-lines are used to feed the SL-DMRs, which not only realize variable bandwidth but also improve the stopband performance. Three transmission zeros (TZs) locate on both sides of the passband, which improve the selectivity of the passband. To verify the analytical theory and design method prediction, two prototypes are designed, fabricated, and measured. The measured responses agree well with the design simulations, exhibiting a good frequency selectivity, isolation, and common-mode suppression.
Abstract................................................................................................................... iiiAcknowledgements ......................................................................................................... vTable of Contents ........................................................................................................... viChapter 1 Introduction .............................................................................................. 101.1 Motivation and Objectives ................................................................................... 101.2 Literature Review on Multi-Band Filters .............................................................. 131.3 Literature Review on Filtering Power Dividers .................................................... 191.4 Literature Review on Balanced-to-Unbalanced Filtering Power Dividers ........... 231.5 Organization of Chapters ................................ ...................................................... 27References ................................................................................................................... 29Chapter 2 Fundamental Design Theory of Filters and Power Dividers .................. 352.1 Overview ............................................................................................................... 352.2 Basic Concepts and Coupled-Line Filters ............................................................. 352.2.1 General Definitions of Filters ........................................................................ 352.2.2 Coupled Resonantors ..................................................................................... 362.2.3 Coupled Transmission Lines .......................................................................... 382.3 Microwave Network Analysis ............................................................................... 412.3.1 Equivalent Voltages and Currents ................................................................ .. 412.3.2 Impedance and Admittance Matrices ............................................................. 452.3.3 The Scattering Matrix .................................................................................... 462.3.4 The Transmission Matrix ............................................................................... 472.4 Basic Properties and Theory of Power Dividers ................................................... 492.4.1 Three-Port Network ....................................................................................... 492.4.2 The Wilkinson Power Divider ........................................................................ 512.5 Differential Circuit and Mixed-Mode S-Parameters ............................................. 532.5.1 Mixed-Mode Scattering Parameter ................................................................ 542.5.2 Standard S-Parameter and Mixed-Mode S-Parameter Transformation ......... 552.6 Conclusion ............................................................................................................ 56References .................................................................................................................. 57Chapter 3 Multi-Band Bandpass Filters Using Multi-Mode Resonators ................ 583.1 Overview ............................................................................................................... 583.2 Analysis of the Two-Types of Dual-Mode Resonators (DMRs) ........................... 583.2.1 Stub-Laded Dual-Mode Resonator (SL-DMR) ............................................. 583.2.2 Dual-Resonance Resonator (DRR) ................................................................ 623.3 Compact Dual-Band Bandpass Filters Using Stub-Loaded Stepped Impedance Resonators ................................................................ ................................................... 643.3.1 Analysis of the Modified Stub-Loaded Quarter-Wavelength SIR ................. 653.3.2 Design and Implement of the Dual-Band BPF with MEMC ......................... 663.3.3 Experimental Results and Discussion ............................................................ 683.4 Novel Compact Dual-Band Bandpass Filter Using Stub-Loaded Shorted Stepped-Impedance Resonators ................................................................................................ 693.4.1 Analysis the Stub-Loaded Shorted SIR.......................................................... 703.4.2 Key Parameters Study of the Dual-Band FPD ............................................... 723.4.3 Experimental Results and Discussion ............................................................ 743.5 Individually Controllable Dual-Band Bandpass Filter With Multiple Transmission Zeros and Wide Stopband ........................................................................................... 753.5.1 Analysis of the Open-Ended Stub-Loaded Shorted-Circuited Stepped Impedance Resonator .............................................................................................. 753.5.2 Design of Dual-Band Bandpass Filter ........................................................... 773.5.3 Implementation and Experimental Results of the Proposed Dual-Band BPF 803.5.4 Analysis of Transmission Zeros and Performances Comparison ................... 813.6 Design of Compact Tri-Band Bandpass Filter Using Stub-Loaded Quarter-Wavelength SIRs ......................................................................................................... 833.6.1 Analysis of the Modified Stub-Loaded Stepped-Impedance Resonator ........ 833.6.2 Design of Tri-Band BPF ................................................................................ 853.6.3 Experimental Results and Discussion ................................ ............................ 863.7 Miniaturized Dual-Band Bandpass Filter Using Composite Resonators With Flexible Frequency Ratio ............................................................................................ 883.7.1 Implement of the Dual-Band FPD ................................................................. 883.7.2 Experimental Results and Discussion ............................................................ 893.8 Conclusion .......................................................................................................... 90References ................................................................................................................... 91Chapter 4 Dual-Band Filtering Power Divider Using Dual-Resonance Resonators with Ultra-Wide Stopband ........................................................................................... 944.1 Overview ............................................................................................................... 944.2 Analysis of the Stepped-Impedance DRR ............................................................. 954.3 Dual-Band Filtering Power Divider Design ......................................................... 974.3.1 Design Procedure of the Dual-Band FPD ...................................................... 984.3.2 Analysis of the Ultrawide Stopband Performance ....................................... 1004.3.3 Experimental Results and Discussion .......................................................... 1014.4 Conclusion .......................................................................................................... 104References ................................................................................................................. 104Chapter 5 Balanced-to-Unbalanced Filtering Power Dividers Using Multi-Mode Resonators with Variable Bandwidth........................................................................ 1065.1 Overview ............................................................................................................. 1065.2 Analysis of the Mixed-Mode Scattering Matrix of Balanced-to-Unbalanced Network ................................................................ ................................ ..................... 1085.3 Narrowband Balanced-to-Unbalanced Filtering Power Divider .......................... 1115.3.1 Analysis of the Equivalent Circuits With the DM and CM Excitations ....... 1115.3.2 Parameters Study ................................ ......................................................... 1155.3.3 Analysis of the Controllability of Bandwidth .............................................. 1175.3.4 Implement of the Narrowband BTU FPD .................................................... 1195.3.5 Experimental Results and Discussion .......................................................... 1205.4 High-Selectivity Narrowband Balanced-to-Unbalanced Filtering Power Divider ................................................................................................ ................................... 1225.4.1 Analysis of the Multiple Transmission Zeros .............................................. 1225.4.2 Experimental Results and Discussion .......................................................... 1245.5 Conclusion .......................................................................................................... 126References ................................................................................................................. 127Chapter 6 Conclusion and Future Work .................................................................. 1296.1 Conclusions ......................................................................................................... 1296.2 Future Work ........................................................................................................ 131Author’s Publications ................................................................................................. 133
主指導教員 : 馬哲旺
DOI
10.24561/00019021
https://doi.org/10.24561/00019021Leave the NDL website.
Persistent ID (NDL)
info:ndljp/pid/11551867
https://dl.ndl.go.jp/pid/11551867
Collection
障害者向け資料
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国立国会図書館デジタルコレクション > デジタル化資料 > 博士論文
https://dl.ndl.go.jp/collections/A00014
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博士論文(自動収集)
Date Accepted (W3CDTF)
2020-10-06T21:18:06+09:00
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https://doi.org/10.24561/00019021Leave the NDL website.
http://id.nii.ac.jp/1586/00019021/Leave the NDL website.
Data Provider (Database)
国立国会図書館 : 国立国会図書館デジタルコレクション
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Digital

Summary, etc.
Multi-band microwave components are expected to be used in modern high-integration wireless communication systems, which can support multi-services simultaneously without adding additional receive or transmit links. For this reason, multi-band microwave components are attracting great attention and becoming research hotspot in microwave passive components domain. Particularly, in the development of multi-band bandpass filters (BPFs) and filtering power dividers (FPDs), how to realize high selectivity, small circuit size, low loss, wide stopband, and flexible control of the channel frequencies and bandwidths are challenging problems. Moreover, balanced-to-unbalanced (BTU) filtering power divider is also one of the key passive components in RF/microwave front-ends for connecting the balanced ports and single-ended port to achieve conversion between balanced and unbalanced signals with common-mode noise suppression. This dissertation is intended to propose new types of multi-mode resonators (MMRs) and develop dual-band and tri-band BPFs, dual-band FPDs, and BTU filtering power dividers with small circuit size, independent control of channel frequencies and bandwidths, and other excellent frequency characteristics. Firstly, a novel type of stub-loaded stepped-impedance resonator (SL-SIR) is proposed. With different schematics of the loaded stubs, the SL-SIR has flexibly controllable dual-modes or tri-modes to construct dual-band or tri-band BPFs. Detailed mode analysis of the resonator is conducted, and parametric variations of the modes are investigated. Next, dual-band and tri-band BPFs are proposed and designed using the dual-mode or tri-mode SL-SIRs. Multiple geometrical parameters in both the external feeding structure and the internal couplings between neighboring resonators are employed to make the individual control of the two or three passbands possible. Furthermore, separately changeable multiple coupling paths between the resonators and the coupling paths between the source and load are devised to create multiple transmission zeros, which not only enhance significantly the selectivity of the passbands, but also widen greatly the stopband of the BPFs. A small H-shaped composite resonator is also proposed, and its even-mode and odd-mode are used to configure a miniaturized dual-band BPF with a flexible center frequency ratio. Three transmission zeros are produced by introducing a mixed electric and magnetic coupling between the resonators, which improves significantly the selectivity and out-band rejection performance. All the designed dual-band and tri-band BPFs are fabricated, and their measured frequency responses agree well with the theoretically predicted ones. Secondly, a novel compact dual-band filtering power divider (DB-FPD) is developed which can reduce significantly the circuit size of a RF/microwave front-end. The proposed DB-FPD consists of a small U-shaped Wilkinson power divider, two pairs of dual-resonance resonators (DRRs), and a pair of spur-lines. With the simultaneous use and appropriate design of the coupled feedlines, mixed electric and magnetic couplings between the DRRs, and spur-lines with different lengths, multiple TZs are produced which result in two passbands with desired power division, high frequency selectivity, good isolation, and an ultrawide stopband. A prototype DB-FPD is designed, fabricated and measured. The measured responses agree well with the design simulations, exhibiting a stopband up to 13.8 GHz (6f0) with 20-dB rejection level. This is the widest stopband of DB-FPDs reported thus far. Finally, two novel balanced to unbalanced filtering power dividers with variable bandwidth are proposed based on stub-loaded dual-mode resonators (SL-DMRs). Two SL-DMRs are used to replace the 90° horizontal transmission lines to realize filtering responses. With the even- and odd-mode analysis method and traditional transmission line theory, closed-form analytical equations and detail design procedures are derived. Moreover, a pair of parallel coupled-lines are used to feed the SL-DMRs, which not only realize variable bandwidth but also improve the stopband performance. Three transmission zeros (TZs) locate on both sides of the passband, which improve the selectivity of the passband. To verify the analytical theory and design method prediction, two prototypes are designed, fabricated, and measured. The measured responses agree well with the design simulations, exhibiting a good frequency selectivity, isolation, and common-mode suppression.
DOI
10.24561/00019021
https://doi.org/10.24561/00019021Leave the NDL website.
Format (IMT)
application/pdf
Source
GD0001146.pdf (fulltext)
https://sucra.repo.nii.ac.jp/record/19052/files/GD0001146.pdfLeave the NDL website.
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インターネット公開
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国立情報学研究所 : 学術機関リポジトリデータベース(IRDB)(機関リポジトリ)
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Original Data Provider (Database)
埼玉大学 : 埼玉大学学術情報リポジトリ(SUCRA)
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