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研究生: 魏庚生
Wei, Geng-Sheng
論文名稱: 28 GHz I/Q調變器與單邊帶混頻器設計
Design of a 28 GHz I/Q Modulator and a Single-Sideband Mixer
指導教授: 蔡政翰
Tsai, Jeng-Han
口試委員: 楊弘源 李威璁 蔡政翰
口試日期: 2022/01/07
學位類別: 碩士
Master
系所名稱: 電機工程學系
Department of Electrical Engineering
論文出版年: 2022
畢業學年度: 110
語文別: 中文
論文頁數: 125
中文關鍵詞: 互補式金氧半導體製程I/Q調變器單邊帶混頻器鏡像拒斥比
英文關鍵詞: Complementary Metal Oxide Semiconductor (CMOS), I/Q Modulator, Single-Sideband Mixer (SSB Mixer), Image Rejection Ratio (IRR)
研究方法: 實驗設計法紮根理論法主題分析
DOI URL: http://doi.org/10.6345/NTNU202200330
論文種類: 學術論文
相關次數: 點閱:133下載:35
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  • 隨著第五代行動通訊技術的發展,毫米波升降頻收發機扮演著重要的角色,其中發射機需將基頻訊號升頻至毫米波頻段後,再透過相位陣列(Phased Array)天線進行無線傳輸,因此調變器與混頻器成為不可或缺的元件。近年來得益於互補式金氧半導體製程(CMOS)的進步,CMOS具有低功率消耗、低成本及高整合度的優勢,且已經可以與大部分的射頻電路整合在一塊。本論文將使用TSMC 90-nm CMOS RF製程與TSMC 65-nm CMOS RF製程,設計實現28 GHz I/Q調變器與單邊帶混頻器。
    第一個電路為28 GHz I/Q調變器,以I/Q調變訊號的方式饋入兩顆混頻器來消除鏡像訊號,並透過加入匹配來達成寬頻的鏡像拒斥比。量測與模擬之特性貼近。當電晶體偏壓為0.35 V,LO驅動功率為3 dBm時,頻帶為25~32 GHz,增益範圍為-9.4 ± 0.5 dB,鏡像拒斥比則有-30 dBc,整體晶片佈局面積為730 μm × 700 μm。
    第二個電路為28 GHz單邊帶混頻器,藉由給予兩顆混頻器正交訊號,將相位差180°的輸出訊號合成後,會達到鏡像抑制之功能。由於LO端匹配電容對於製程變異相當敏感,因此最後實現的單邊帶混頻器有頻飄的狀況。當電晶體偏壓為0.35 V,LO驅動功率為3 dBm時,頻帶為23~28 GHz,增益範圍為-22.5 ± 0.5 dB,鏡像拒斥比則有-30 dBc,整體晶片佈局面積為755 μm × 730 μm。

    As the progress of the fifth-generation mobile communication technology, millimeter wave transceivers play an important role, the transmitters need to up-convert the baseband signal to the millimeter wave frequency band and then perform wireless transmission through a phased array antenna design. Therefore, modulators and mixers become indispensable components. Recently, thanks to advances in Complementary Metal Oxide Semiconductor (CMOS) process. The modern CMOS process has the advantages of low power consumption, low cost and high integration, and it is suitable for the implementation of the RF circuits. In this thesis, a 28 GHz I/Q Modulator and a Single-Sideband Mixer (SSB Mixer) are presented, and implemented in TSMC 90-nm CMOS RF technology and TSMC 65-nm CMOS RF technology, respectively.
    The first circuit is a 28 GHz I/Q modulator, which eliminates the image signal by applying I/Q modulation signals into two mixers, and achieves a wide-band image rejection ratio by adding matching network. The characteristics of measurement and simulation have good agreement. When the gate bias is 0.35 V and LO drive power is 3 dBm, the conversion gain is -9.4 ± 0.5 dB from 25 to 32 GHz with the image rejection ratio of -30 dBc. The chip size is 730 μm × 700 μm.
    Second, a 28 GHz SSB Mixer has designed and implemented. By applying quadrature signals into two mixers, the two output signals with 180° phase difference are combined to achieve the image suppression function. However, the LO matching capacitor is sensitive to the process variation. Therefore, the SSB Mixer frequency shifted. When the gate bias is 0.35 V and LO drive power is 3 dBm, the conversion gain is -22.5 ± 0.5 dB from 23 to 28 GHz with the image rejection ratio of -30 dBc. The chip size is 755 μm × 730 μm.

    第一章 緒論 1 1.1 研究背景與動機 1 1.2 文獻探討 1 1.3 研究成果 2 1.4 論文架構 3 第二章 混頻器介紹 4 2.1 混頻器之原理 4 2.2 混頻器之架構 4 2.2.1 被動電阻式環形混頻器(Passive Resistive Ring Mixer) 7 2.2.2 單邊帶混頻器(Single-Sideband Mixer, SSB Mixer) 8 2.2.3 同差式發射機(Homodyne Transmitter) 9 2.2.4 外差式發射機(Heterodyne Transmitter) 10 2.3 混頻器之設計參數 11 2.3.1 轉換增益/損耗(Conversion Gain/Loss) 11 2.3.2 轉換增益對LO驅動功率(Conversion Gain vs LO Power) 11 2.3.3 鏡像拒斥比(Image Rejection Ratio, IRR) 12 2.3.4 線性度(Linearity) 13 2.3.5 隔離度(Isolation) 14 2.3.6 選擇度(Selectivity)與靈敏度(Sensitivity) 15 第三章 28 GHz I/Q調變器設計 17 3.1 簡介 17 3.2 I/Q調變器設計 17 3.2.1 電晶體尺寸與偏壓分析選擇 18 3.2.2 RF端與LO端巴倫器(Balun) 25 3.2.3 耦合器(Coupler) 29 3.2.4 匹配網路設計 31 3.2.5 威爾金森功率合成器(Wilkinson Power Combiner) 34 3.3 I/Q調變器之模擬結果 36 3.3.1 混頻器模擬結果 36 3.3.2 I/Q調變器模擬結果 40 3.4 I/Q調變器之量測結果 45 3.5 問題與討論 55 3.5.1 PDK corner變異 55 3.5.2 耦合器電阻變異 56 3.5.3 電磁模擬變異 58 3.6 總結 62 第四章 28 GHz單邊帶混頻器設計 63 4.1 簡介 63 4.2 單邊帶混頻器設計 63 4.2.1 電晶體尺寸與偏壓分析選擇 64 4.2.2 RF端與LO端巴倫器(Balun) 71 4.2.3 耦合器(Coupler) 75 4.2.4 匹配網路設計 77 4.2.5 威爾金森功率合成器(Wilkinson Power Combiner) 80 4.2.6 多相位濾波器(Poly Phase Filter) 81 4.3 單邊帶混頻器之模擬結果 86 4.3.1 混頻器模擬結果 86 4.3.2 單邊帶混頻器模擬結果 90 4.4 單邊帶混頻器之量測結果 95 4.5 問題與討論 105 4.5.1 PDK corner變異 105 4.5.2 匹配電容變異 106 4.5.3 多相位濾波器電阻電容變異 108 4.5.4 LO端振幅與相位不平衡對鏡像抑制的影響 109 4.5.5 IF端振幅與相位不平衡對鏡像抑制的影響 112 4.5.6 振幅與相位不平衡與鏡像拒斥比量測結果 116 4.6 總結 118 第五章 結論 119 參 考 文 獻 120 自  傳 125 學 術 成 就 125

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