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博碩士論文 etd-0729113-145510 詳細資訊
Title page for etd-0729113-145510
論文名稱
Title
利用無線電源之ASK訊號傳輸電路設計與實現
Design and Implementation of an ASK Signal Transmission Circuit with Wireless Power
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
64
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
2013-08-20
繳交日期
Date of Submission
2013-09-02
關鍵字
Keywords
無線能量傳輸、品質因子、磁諧振、堆疊線圈、振幅鍵控調變
stacked coil, quality factor, Wireless power transfer system, magnetically-coupled resonators, ASK
統計
Statistics
本論文已被瀏覽 5830 次,被下載 424
The thesis/dissertation has been browsed 5830 times, has been downloaded 424 times.
中文摘要
本論文利用堆疊式線圈實現高效率振幅鍵控無線能量傳輸架構,首先由磁諧振理論了解影響線圈效率的因素,嘗試提高線圈品質因子來增加效率,並利用ADS進行堆疊線圈設計與模擬。量測結果發射線圈與接收線圈Q值分別為179及76,在發射與接收線圈距離1cm和4cm時分別做阻抗匹配,其效率分別為86%及41%。接著利用上述設計堆疊線圈實現振幅鍵控無線能量傳輸架構,電路總功耗為27mW,整體效率在線圈距離1cm時 DE與PAE分別為55%與49%,傳輸速率最高可達1Mbps。
Abstract
This thesis implementsa wireless power transfer system in which an ASK data link is performed. A stacked coil structure is used to boost transfer efficiency of the system. The study begins with the theory of magnetically-coupled resonators and highlights the factors that affect the coil efficiency. To optimize transfer efficiency, of the system, the main effortis to enhance quality factor of the coils. The measured quality factors of the stacked coils in the transmitter and receiver are179 and 76, respectively. For the transmitter and receiver coils spaced 1 and 4 cm apart, the coil efficiency achieves 86% and 41%, respectively. The wireless power transfer system consumes about 27 mW DC power. With the transmitter and receiver coils spaced 1-cm apart, the system achieves a DE and PAE of 55% and 49%, respectively, and an ASK data rate of up to 1 Mbps.
目次 Table of Contents
第一章 緒論...........................................................1
1.1 研究背景與動機...............................................1
1.2 論文章節規劃..................................................5
第二章 線圈設計....................................................6
2.1 能量傳遞方式..................................................6
2.1.1 電磁感應 .....................................................7
2.1.2 磁諧振 .........................................................9
2.2 線圈設計........................................................11
2.2.1 線圈損耗 ....................................................11
2.2.2 平面線圈 ....................................................12
2.3 非堆疊式線圈模擬..........................................13
2.2.3 堆疊線圈 ....................................................17
2.3.2 並聯式堆疊模擬 .........................................19
第三章 能量和資料傳輸........................................26
3.1 能量傳輸調制.................................................26
3.1.1 幅移鍵控調制 .............................................26
3.1.2 頻移鍵控調制 .............................................28
3.1.3 二元相移鍵控調制 ......................................29
3.2 能量傳輸........................................................30
3.2.1 E 類功率放大器 ..........................................30
3.2.3 穩壓器 ...................................................... 34
3.2.4 實驗結果 ....................................................36
3.3 資料傳輸........................................................38
3.3.1 ASK 調制電路 ........................................... 38
3.3.2 ASK 解調電路 ............................................42
3.3.3 實驗結果 ...................................................44
第四章結論..........................................................47
參考文獻.............................................................48
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