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博碩士論文 etd-0710118-203740 詳細資訊
Title page for etd-0710118-203740
論文名稱
Title
自我注入鎖定雷達之印刷電路板設計
Printed Circuit Board Design of Self-Injection-Locked Radar
系所名稱
Department
畢業學年期
Year, semester
語文別
Language
學位類別
Degree
頁數
Number of pages
69
研究生
Author
指導教授
Advisor
召集委員
Convenor
口試委員
Advisory Committee
口試日期
Date of Exam
2018-08-09
繳交日期
Date of Submission
2018-08-10
關鍵字
Keywords
自我注入鎖定雷達
Self-Injection-Locked Radar
統計
Statistics
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中文摘要
本論文提出兩組基於自我注入鎖定原理之微小化非接觸式感測雷達系統,從振盪器與不等功率分枝耦合器的設計概念入手,設計SIL振盪器的鎖定範圍、輸出功率、與推導不等功率分枝耦合器的矩陣分析。在論文中段將雷達收發機整合在ADS模擬環境中,透過模擬軟體得知自我注入鎖定雷達收發機的工作狀況,得出模擬與實作有相同的趨勢,最後進行雷達架構的整合,並從頻譜與示波器分析兩雷達模組的效能得出,雷達模組I有較佳的振幅表現,而雷達模組II有較佳的訊號雜訊比表現。
Abstract
This thesis proposes two miniaturized Printed-Circuit-Board(PCB) non-contact radar systems based on Self-Injection-Locked(SIL) principles. According to the design concepts of the oscillator and unequal power branch-line coupler. Design the locking range and power of Self-Injection-Locked Oscillator(SIL Oscillator) and derives the matrix analysis of the unequal power branch-line coupler. In the middle of the papper, the radar transceivers will be integrated into the Advanced Design System (ADS) simulation environment, and the working state of the SIL radar transceivers will be interpreted through a simulated software in order to obtain the same trend in the simulated and implement test environment. Integrated the radar architecture at the end. Showing the ability of this two sets of radar from triangle experiment . The measurement results demonstrate that the first set of radars perform better amplitude , while the second set of radars perform better sensitivity.
目次 Table of Contents
圖目錄 i
表目錄 I
第一章 序論 1
1.1 研究背景與動機 1
1.2 非接觸式生理感測雷達現況 2
第二章 自我注入鎖定雷達 5
2.1 自我注入鎖定雷達架構概述 5
2.1.1 自我注入鎖定雷達訊號路徑 5
2.2 自我注入鎖定理論推導 6
2.2.1 自我注入鎖定雷達量測理論 9
2.3 自我注入鎖定振盪器設計原理 11
2.3.1 自我注入鎖定振盪器設計概念 11
2.3.2 振盪器振盪原理 12
2.3.3 設計流程 13
2.3.4 量測結果與模擬 16
2.4 不等功率分枝耦合器設計原理 21
2.4.1 設計概念 21
2.4.2 設計流程 22
2.4.3 量測結果與模擬 24
第三章 微小化PCB雷達模組 27
3.1 雷達感測模組 27
3.2 雷達模組I模擬 29
3.2.1雷達模組I之SIL振盪器模擬 29
3.2.2 微帶線實驗與模擬驗證 31
3.2.3 模擬SIL振盪器負載牽引現象 33
3.3 雷達模組I 35
3.3.1 雷達模組I收發器 35
3.3.2 雷達模組I鑑頻器 36
3.3.3雷達模組I鑑頻器分析 38
3.4 雷達模組II 40
3.4.1雷達模組II收發器 40
3.4.2 雷達模組II鑑頻器 42
3.4.3 雷達模組II鑑頻器分析 43
3.5 雷達模組三角波實驗 45
補充人體量測結果 49
第四章 結論 51
參考文獻 52
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