應用於Radio-over-Fiber系統之超高速微波光子發射器

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姓名

黃榮星(Jung-hsing Huang) 查詢紙本館藏

畢業系所

電機工程學系

論文名稱

應用於Radio-over-Fiber系統之超高速微波光子發射器
(Ultra-High-Speed Microwave Integrated Photonic Transmitter for Radio-Over-Fiber Applications)

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摘要(中)

本論文以微波光子通信系統(microwave photonic communication systems)中的Radio-over-Fiber (RoF)系統應用為主，使用近彈道單載子光檢測器(near-ballistic uni-traveling-carrier photodiode, NBUTC-PD)此高速寬頻且可供光電轉換效果之主動積體元件與被動電路整合，實現出具有超高速無線傳輸功能之毫米波發射器。
為設計高速無線傳輸系統之發射端，於論文中提出NBUTC-PD之等效電路，以模擬方式即提供光電轉換與中頻響應之準確預測，提升設計效率與節省成本；將上述與射頻扼流器(RF-choke)、W頻帶帶通濾波器(W-band bandpass filter)、平面電路至導波管(Waveguide)轉接器及號角天線(Horn Antenna)等被動電路元件整合，設計並實作出光子積體傳輸器(integrated photonic transmitter)；文中亦以上述電路改良後，提出新式射頻扼流器提供元件良好散熱與提升中頻響應頻寬，有效將數位訊號無線傳輸速率提高至20 Gbit/s。

摘要(英)

In this thesis, an integrated photonic transmitter front-end is demonstrated. In essence, the front-end circuit consists of an RF-choke, a W-band bandpass filter, an uni-planar slotline-to-waveguide transition, and a W-band horn antenna. The front-end is built with a near-ballistic uni-traveling-carrier photodiode (NBUTC-PD), which exhibits an extremely broadband bandwidth as well as an ultra-wide optical-to-electrical response. It is shown that the NBUTC-PD with proper integrated front-end circuits can find applications in the Radio-over-Fiber (RoF) system for ultra-high-speed wireless data transmission.
　This thesis also presents equivalent circuits to further simplify the system design procedures. The equivalent circuit of the entire system leads to reasonably accurate W-band optical-to-electrical response and intermediate frequency (IF) modulated bandwidth. For experimental demonstration, the proposed front-end is integrated with NBUTC-PD through flip-chip bonding for realization of a W-band integrated photonic transmitter. Since the wide optical-to-electrical bandwidth (35 GHz) as well as broad IF modulated bandwidth (25 GHz), the proposed photonic transmitter is of a high data rate up to 20 Gbit/s and expected to find applications in the broadband wireless-over-fiber system.

關鍵字(中)

★ 微波光子發射器
★ 近彈道單載子光檢測器
★ 光電檢測器
★ 光二極體
★ 光子積體發射器
★ 超高速無線傳輸
★ 光纖無線通信
★ W頻段

關鍵字(英)

★ NBUTC-PD
★ Microwave Integrated Photonic Transmitter
★ ultra-high-speed wireless data rate
★ RoF
★ Radio-over-Fiber
★ W-band
★ photonic diode
★ photodetector

論文目次

摘要　i
Abstract　ii
目錄　iii
圖目錄　v
表目錄　ix
第一章　序論　
1.1　研究動機與目的　　1
1.2　RoF系統簡介　　2
1.3　近彈道單載子光檢測器於RoF系統之應用　　5
1.4　文獻探討　　6
1.5　論文概述　　9
第二章　光檢測器電路模型之探討　　10
2.1　近彈道單載子光檢測器概述　　10
2.2　光電轉換等效模型建立　　12
2.3　改良之W頻帶光電轉換等效電路模型　　15
2.4　IF頻段之光電轉換等效電路模型　　17
第三章　微波光子通信系統射頻前端電路　　20
3.1　平面電路至導波管轉接器　　22
3.2　射頻扼流器　　27
3.3　W頻段帶通濾波器　　29
3.4　積體化光檢測器與被動電路連接　　32
3.5　光電轉換之整體響應　　34
3.6　中頻調變響應之模擬與量測　　39
3.7　光檢測器應用於高速無線傳輸　　40
第四章　中頻調變頻寬拓展與散熱設計　　42
4.1　射頻扼流器分析　　42
4.2　中頻調變頻寬改善方法　　48
4.3　底層金屬墊片架構　　50
4.4　改良饋入電路與系統整合　　56
4.5　中頻調變響應模擬與量測　　59
4.6　改良後無線傳輸結果　　60
4.7　散熱效果觀察　　64
4.8　文獻比較　　65
第五章　結論　　66
參考文獻　　67
附錄　　71

參考文獻

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指導教授

凃文化、陳念偉
(Wen-hua Tu、Nan-wei Chen)

審核日期

2011-8-13

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