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研究生:賴昱澄
研究生(外文):Yu-Cheng Lai
論文名稱:振盪器頻率牽引效應對鎖相迴路影響之系統模型建立
論文名稱(外文):Modeling of the Oscillator Pulling Effects within a Phase-Locked Loop
指導教授:李健榮李健榮引用關係
指導教授(外文):Chien-Jung Li
口試委員:陳奇燦吳建銘彭康峻
口試委員(外文):Qi-Can ChenJian-Ming WuKang-Jun Peng
口試日期:2013-07-19
學位類別:碩士
校院名稱:國立臺北科技大學
系所名稱:電腦與通訊研究所
學門:工程學門
學類:電資工程學類
論文種類:學術論文
論文出版年:2013
畢業學年度:101
語文別:中文
論文頁數:58
中文關鍵詞:頻率牽引鎖相迴路注入鎖定相式自我注入鎖定
外文關鍵詞:frequency pullingphase-locked loopinjection-lockedphase- and self-injection-locked
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  在無線通訊系統中,本地振盪源多以鎖相迴路為基礎的頻率合成器設計為主,而頻率合成器的頻譜純淨度乃是影響訊號品質的關鍵之一。由於振盪器容易受到訊號干擾的特性,將使得鎖相迴路的輸出頻譜在受到訊號注入情況下受到汙染。由於振盪器受訊號注入的影響是一種高度非線性的機制,在數學分析中往往需要配合特殊的假設才能更進一步導出結果;由此可知,注入干擾訊號對實際系統影響分析的困難度已不言而喻,這也使得設計者很難評估干擾訊號對系統所造成的影響。本論文旨在將傳統的注入鎖定方程式推廣為離散時域方程式,進而可以發展出一種基於電腦輔助設計軟體的注入鎖定振盪器模型,使注入訊號的影響可以借助電腦演算來完成。有別於現有文獻的方法,本論文使用波包模擬的觀念來實現注入鎖定振盪器的行為模型,在相同的準確性下能夠具有更好的模擬效率。本論文將此模型之演算結果與實際受注入的振盪器輸出頻譜進行比較,以確認此受注入影響振盪器模型之準確性。隨後,以鎖相迴路之鎖相振盪器為基礎,將所建立的注入鎖定振盪器模型套用於鎖相式自我注入鎖定架構之上並進行完整的模擬與量測結果比較。

  In the wireless communication systems, the local oscillator (LO) is usually based on the phase-locked loop (PLL) in the transceiver to generate a carrier with purity. The spectral purity of the synthesized output is one of the reasons that affect the system output quality. Since the oscillator is susceptible to the interferences, the PLL output spectrum is subject to degradation due to external disturbances. It is difficult to analyze the oscillator under injection, because of the highly nonlinear mechanism, unless some particular conditions are restricted. This thesis has developed an injection-locked oscillator (ILO) model based on the discrete-time algorithm driven from the Adler’s equation. The developed ILO model can lead the designers to evaluate the influence of injection in a simple manner. In this study, the accuracy of the ILO model was experimentally examined. The model was finally applying itself to a 2.4 GHz phase- and self-injection-locked (PSIL) radar to predict the vital-sign sensing results.

摘 要 i
ABSTRACT ii
誌 謝 iii
目 錄 iv
表目錄 vi
圖目錄 vii
第一章 序論 1
1.1 簡介 1
1.2 研究動機 2
1.3 章節規劃 2
第二章 振盪器注入鎖定與頻率牽引現象 4
2.1 歷史沿革 4
2.2 弱注入分析 5
2.2.1 穩定的條件 9
2.2.2 同頻的現象 10
2.2.3 鎖定範圍內的現象 11
2.2.4 鎖定範圍外的現象 13
2.2.4.1 準鎖定(quasi-lock) 14
2.2.4.2 快速跳動(fast beat) 17
2.3 強注入分析 17
第三章 受注入影響之振盪器模擬平台建立 21
3.1 離散時域模型 21
3.2 電路波包模擬原理 23
3.3 SDD與FDD 26
3.4 ADS模擬平台建立 28
3.5 受注入之振盪器模擬與實驗 29
第四章 受注入影響之鎖相迴路模擬平台建立 36
4.1 受注入之鎖相迴路理論分析 36
4.1.1 離散時域方法 37
4.1.2 頻域方法 38
4.1.2.1 注入轉移函數 39
4.1.2.2 ILO的雜訊轉移函數 40
4.1.2.3 PLO的雜訊轉移函數 42
4.2 ADS模擬平台建立 43
4.3 受注入之鎖相迴路模擬與實驗 46
第五章 結論 55
參考文獻 56


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