臺灣博碩士論文加值系統

印刷電路板提供電子零組件在安裝與電子訊號互連時的主要支撐結構，是所有電子產品無法或缺的基礎零件。目前軟性印刷電路板因為具有好的低損耗，低雜訊與高速傳送之電性規格廣泛使用在高頻電子電路。本文針對在軟性印刷電路板上平面傳輸線之特性阻抗進行探討，並對兩種典型平面傳輸線例如微帶線與帶狀線，在不同幾何參數與介電常數對特性阻抗作分析與模擬。利用成品的模擬與量測數據，以呈現影響特性阻抗線路製造的關鍵參數。同時利用實驗量測，探討傳輸線長度與頻寬的關係。

The printed circuit board (PCB) is an essential component for all electronic products because it provides a supporting structure for the electronic component assembly and the interconnection between electronic components and signals. Recently, a flexible PCB is widely used to the radio frequency circuit. Therefore, the flexible PCB with good electrical specifications such as low loss, low noise and high speed transmission are most significant. In this thesis, the characteristic impedance formula of the planar transmission line on the flexible PCB is discussed. Two types of typical planar transmission lines such as the microstrip line and stripline for the characteristic impedance in varying the geometric parameters and dielectric constants are analyzed and simulated. By analyzing the simulated and measured results, a key fabricating parameter for the influence of the characteristic impedance can be obtained. Furthermore, the relation between the transmission line length and the transmission bandwidth is also discussed by the measured results.

中文摘要 ------------------------------------------------------------------- i
英文摘要 ------------------------------------------------------------------- ii
致謝 ------------------------------------------------------------------- iv
目錄 ------------------------------------------------------------------- v
表目錄 ------------------------------------------------------------------- viii
圖目錄 ------------------------------------------------------------------- ix

第一章 緒論 --------------------------------------------------------------- 1
1.1 研究目的與動機 ------------------------------------------------------- 1
1.1.1 研究動機 ---------------------------------------------------- 2
1.1.2 研究目的 ---------------------------------------------------- 4
1.2 研究方法 ------------------------------------------------------------ 4
1.2.1 研究架構 ---------------------------------------------------- 5
1.2.2 研究方法 ---------------------------------------------------- 6
1.2.3 研究範圍與限制 ----------------------------------------------- 6
1.2.4 研究工具 ---------------------------------------------------- 7
1.2.5 研究步驟 ---------------------------------------------------- 8
1.3 文獻導覽 ------------------------------------------------------------ 10
1.4 內容摘要 ------------------------------------------------------------ 12

第二章 軟性印刷電路板與傳輸線特性阻抗簡介 -------------------------------------- 14
2.1 軟性印刷電路版製作流程 ------------------------------------------------ 14
2.2 傳輸線特性阻抗意義與線路實際應用 ----------------------------------------- 24
2.2.1 傳輸線特性阻抗理論 --------------------------------------------- 24
2.2.2 傳輸線特性阻抗實際應用 ------------------------------------------ 32
2.3 傳輸線特性阻抗線路實際製作之瓶頸 ----------------------------------------- 35
第三章 研究方法與步驟 ------------------------------------------- ----------- 45
3.1 模擬軟體"Polar"與硬體設備"TDR"簡介 ----------------------------------- 45
3.1.1 模擬軟體"Polar" -------------------------------------------- 45
3.1.2 硬體設備"TDR" ----------------------------------------------- 51
3.2 影響傳輸線特性阻抗因素 ------------------------------------------------ 59
3.2.1 魚骨圖分析 -------------------------------------------------- 62
3.2.2 銅材類種類與厚度 --------------------------------------------- 63
3.2.3 設計方式(網銅mesh /實銅 dummy) ------------------------------ 65
3.2.4 製程能力(銅電均勻度 /蝕刻縱橫比) ------------------------------ 65
3.3 模擬與量測設置 ------------------------------------------------------ 65
3.3.1 模擬條件設定 ------------------------------------------------ 67
3.3.2 量測儀器設置 ------------------------------------------------ 70
第四章 實驗結果分析與討論 --------------------------------------------------- 72
4.1 銅材料影響傳輸線特性阻抗模擬與實驗結果 ---------------------------------- 72
4.2 製程能力影響傳輸線特性阻抗模擬與實驗結果 --------------------------------- 75
4.3 設計方式影響傳輸線特性阻抗模擬與實驗結果 --------------------------------- 77
4.4 三種因素對傳輸線特性阻抗影響比較分析 ------------------------------------- 79
4.5 三種因素對傳輸線頻寬穩定性影響比較分析 ------------------------------------ 80
第五章 結論與展望------------------------------------------------------------ 83
5.1 結論 ---------------------------------------------------------------- 83
5.2 未來展望 ------------------------------------------------------------- 84
參考文獻 --------------------------------------------------------------------- 86
簡歷 --------------------------------------------------------------------- 89

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