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姓名	蔡文偉(Wen-Wei Tsai)  查詢紙本館藏	畢業系所	電機工程學系
論文名稱	緊湊且高隔離度的四通帶功率分波器 (Compact and High-Isolation Quadruplexer Power divider)
相關論文	★ 應用於微波之多頻帶通濾波器之設計 ★ 使用可開關式帶通濾波器之低相位雜訊雙頻振盪器研製 ★ 共平面波導饋入槽孔偶極天線之寬頻與多頻應用 ★ 可具任意通帶之可調式多工器 ★ 利用非對稱步階式阻抗設計寬通帶寬止帶雙工器 ★ 基於散佈式耦合饋入架構之可開關式帶通濾波器 ★ 共平面波導饋入之寬頻雙圓極化天線 ★ 基於多共振路徑所設計之印刷式多頻帶天線 ★ 四通道可切換式帶通濾波器之研究 ★ 雙模態寬阻帶之基板合成波導濾波器 ★ 微小化倍頻壓抑直交分合波器之研製 ★ 可繞式小型偶極天線之研製 ★ 使用多重模態共振器實現多功能帶通濾波器 ★ 應用於Radio-over-Fiber系統之超高速微波光子發射器 ★ 使用長饋入線架構研製小型且具有高隔絕度的多工器 ★ 具有寬截止頻帶的帶通濾波器之研製
檔案	[Endnote RIS 格式]    [Bibtex 格式]    [相關文章]   [文章引用]   [完整記錄]   [館藏目錄]   至系統瀏覽論文 (2026-8-1以後開放)
摘要(中)	本論文提出了具有帶通濾波器效應的功率分波四工器，共設計了三組不同的電路架構，其中二組用傳統半波長C型共振器去實現，另外一組是利用半波長共振器跟一端短路四分之波長共振器去抑制諧振頻率，最後一組使用雙模態共振器並用Via hole取代電感，相比前二組電路，面積減少了約一組半波長共振器，本電路設計使用chebyshev原型參數並計算出對應的Q值及M值去匹配。 第一組電路按照傳統的半波長共振器設計出四個通帶，使用RO4003C，厚度為0.41mm、介電常數為3.55的板材，考量到若使用直接饋入方式電路匹配會相當困難所以採用耦合饋入，四個通帶設計完成後輸出port接上Wilkinson power divider，以達成提出的設計目標。 第二組電路使用半波長共振器及四分之波長共振器分別在共振器的末端打Via hole，在倍頻明顯被抑制掉，直接半波長共振器接兩個輸出port雖然對稱性會比使用Wilkinson power divider的電路稍差，但電路面積可以減少。 第三組電路使用雙模態共振器去實現，並在輸出port接上Wilkinson power divider達到功率分波的效果，藉由調整Via hole的大小可以調整電路的頻寬，只用了一組半波長共振器，實現的面積減少許多，此三組電路的通帶中心頻率分別為2GHz、3GHz、4GHz、5GHz。 文中會具體介紹帶通濾波器效應的功率分波四工器的原理及設計流程，且實作去驗證設計理念，並比較這三組電路的優缺點。
摘要(英)	This thesis proposes a compact and high-isolation microstrip quadruplexer power divider. One of the circuit consists of two traditional half-wavelength resonators C-type, another of the circuit consists of a half-wavelength resonator and a quarter-wavelength resonator with short end, the other of circuit consists of a dual-mode resonator with a via hole replace inductor. In this thesis, three different circuit architectures are designed using the different resonator. These circuits can use the Chebyshev prototype parameters to design the bands systematically. The first circuit is a quadruplexer. There are two traditional half-wavelength resonators on a 0.41 mm Rogers4003C substrate with a relative permittivity of 3.55 and a loss tangent of 0.0027. In order to matching circuit by coupling feeding line, output feeding lines and uniform resonator pairs. Finally, the output ports add wilkinson power divider to achieve design concept. The second circuit is asymmetric. It consists of a half-wavelength resonator and a short-end quarter-wavelength resonator. Due to the asymmetric structure, the harmonic response is suppressed and the circuit area is reduced. The third circuit uses a dual-mode resonator to design a filtering power divider. Similarly, the output ports add wilkinson power divider to implement. Through the change diameter of via hole and the gap of the coupling structure, the achievable bandwidth of the circuit is adjusted. Compare to the three circuits area, the last proposed is smallest. The center frequencies of four pass-band are 2 GHz, 3 GHz, 4 GHz, and 5 GHz. In this content, the design process of the quadruplexer power divider is recorded in detail and implemented to verify the design concept. The advantages and disadvantages of the three circuits are compared.
關鍵字(中)	★ 四通帶 ★ 功率分波器	關鍵字(英)
論文目次	摘要 i Abstract i 致謝 iii 目錄 iv 圖目錄 vi 表目錄 viii 第一章 緒論 1 1.1 研究動機 1 1.2 文獻回顧 2 1.3 論文架構 3 第二章 濾波器的基本原理 4 2.1 集總式濾波器 4 2.2 分散式濾波器 8 2.3 外部品質因數 12 2.4 耦合係數 14 第三章 運用環形共振器設計四工功率分波器 18 3.1 利用環形半波長共振器設計四工器 18 3.2 理論及抑制倍頻 19 3.3 四工器模擬結果 21 3.4 威爾京生功率分波器 23 3.5 四工功率分波器模擬結果 26 第四章 運用末端短路共振器設計四通帶功率分波器 33 4.1 簡介 33 4.2 Via大小對共振器頻率的影響 35 4.3 外部品質因數和耦合係數 36 4.4 四通帶功率分波器模擬與量測 38 第五章 運用雙模共振器設計四通帶功率分波器 49 5.1 開路及短路殘段共振器原理 49 5.2 使用短路殘段共振器設計濾波器 54 5.3 雙模四通帶功率分波器模擬與量測 55 第六章 結論 69 參考文獻 70
參考文獻	[1] C. F. Chen, T. Y. Huang, C. P. Chou, and R. B. Wu, "Microstrip Diplexers Design With Common Resonator Sections for Compact Size,But High Isolation," IEEE Trans. Microw. Theory Tech., vol. 54, no. 5, pp.1945–1952, May 2006. [2] T. Yang, P. L. Chi, T. Itol , "High Isolation and Compact Diplexer Using the Hybrid Resonators," IEEE Access., IEEE Microw. Wirel. Compon. Lett.,Vol. 20, no. 10, April 2010 [3] H. W. Wu, K. Shu, R. Y. Yang, M. H. Weng, J. R. Chen, and Y. K. Su, " Design of A Compact Microstrip Triplexer for Multiband Applications," Proceedings of the 37th European Microwave Conference .,2007 ,pp.834-837. [4] T. Yang, P. L. Chi, T. Itol , " Compact Quarter-Wave Resonator and Its Applications to Miniaturized Diplexer and Triplexer," IEEE Microw. Wirel. Compon. Lett., Vol. 59, no. 2, April 2011 . [5] S. J. Zeng, J. Y. Wu , and W. H. Tu, " Compact and High-Isolation Quadruplexer Using Distributed Coupling Technique ", IEEE Microw. Wirel. Compon. Lett., Vol. 21, no. 4, April 2011 [6] S. S. Lo, K. W. Hsu, and W. H. Tu " Compact and High-Isolation Microstrip Quadruplexer," Asia-Pacific Microwave Conference Proceedings, 2013. [7] C. F. Chen, T. M. Shen, T. Y. Huang, and R. B. Wu, " Design of Compact Quadruplexer Based on the Tri-Mode Net-Type Resonators," IEEE Microw. Wirel. Compon. Lett., Vol. 21, no. 10, Octorber 2011 [8] W. M. Chau, K. W. Hsu, and W. H. Tu, " Filter-Based Wilkinson Power Divider," IEEE Microw. Wirel. Compon. Lett., Vol. 24, no. 4, April 2014 [9] W. H. Tu, " Switchable Microstrip Bandpass Filters With Reconfigurable On-State Frequency Responses," IEEE Microw. Wirel. Compon. Lett., Vol. 20, no. 5, May 2010 [10] P. H. Deng, W. Lo, B. L. Chen, and C. H. Lin, " Designs of Diplexing Power Dividers," IEEE Access., date of publication January 11, 2018, date of current version February 28, 2018 [11] C. F. Chen, K. W. Zhou, R. Y. Chen, Z. C. Wang, and C. H. Lin, " Design of a Microstrip Diplexer-Integrated Filtering Power Divider," IEEE Access., date of publication August 5, 2019, date of current version August 16, 2019 [12] L. Tang , X. Zhang, F. Jiao, S. Liu, G. Zhang and J. Yang, "Design of a Compact Microstrip Triplexer-Power Divider With E-shaped Resonator," School of Electrical & Automation Engineering, Nanjing Normal University, Nanjing 210046 China. [13] W.-H. Tu, "Compact double-mode cross-coupled microstrip bandpass filter with tunable transmission zeros," IET Microw. Antennas Propag., vol. 2, no. 4, pp. 373-377, June 2008. [14] X. Y. Zhang, J. X. Chen, Q. Xue, S. M. Li, " Dual-Band Bandpass Filters Using Stub-Loaded Resonators," IEEE Microw. Wirel. Compon. Lett., vol. 17, no. 8, August 2007 [15] F. Huang, J. Wang, and L. Zhu, " A New Approach to Design a Microstrip Dual-Mode Balun Bandpass Filter," IEEE Microw. Wirel. Compon. Lett., vol. 26, no. 4, April 2016 [16] M. Matsuo, H. Yabuki and M. Makimoto, "Dual-mode stepped-impedance ring resonator for bandpass filter applications," IEEE Trans. Microw. Theory Tech., vol. 49, no. 7, pp. 1235-1240, July 2001. [17] J. S. Hong and M. J. Lancaster, Microstrip filters for RF/microwave applications, 2nd ed. New York: Wiley, 2001. [18] D. M. Pozar, Microwave Engineering, 4th ed. New York: Wiley, 2012.
指導教授	凃文化(Wen-Hua Tu)	審核日期	2021-8-13
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