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研究生:李信宏
研究生(外文):Lee, Shing-Horng
論文名稱:準光學功率整合器陣列之研究
論文名稱(外文):Studies of Quasi-Optical Power Combining Arrays:
指導教授:李建平, 周復芳
指導教授(外文):Chien-Ping Lee, Christina F. Jou
學位類別:博士
校院名稱:國立交通大學
系所名稱:電子工程學系
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:1998
畢業學年度:86
語文別:中文
論文頁數:130
中文關鍵詞:方柵振盪器漏波主動天線
外文關鍵詞:Grid OscillatorLeaky WaveActive Antenna
相關次數:
  • 被引用被引用:0
  • 點閱點閱:158
  • 評分評分:
  • 下載下載:0
  • 收藏至我的研究室書目清單書目收藏:1
本篇論文主要是針對準光學功率整合技術作研究。在論文第一部份
,首先我們研究了1x1、 2x2及4x4甘式二極體所製成之方柵振盪器,這準
光學振盪器陣列的頻率可用電壓控制而並不需要用移動後鏡面來調變,另
外我們也提出了一個二維分析方法來計算電場及磁場幅射場形。這種方柵
振盪器陣列有兩個優點:一是它不需要外在鎖相訊號,二是它不 像貼片天
線陣列需要電阻來消除多模的問題。雖然我們已使用後面的接地面當作散
熱片,但是實驗結果顯示當整合更多元件時,散熱將會是一個大問題,但
是這可用脈沖式直流偏壓來消除。
在論文第二部份,首先研究一個不對稱饋入的固定頻率主動漏波天線,
然後我們研究陣列部份,我們針對一、兩及四個使用甘式二極體所製作之
強藕合然的線性主動漏波天線陣列作研究,它們的功率輸出效率兩根的
是1.58倍,而四根的為0.75倍,它可以經由二極體的改變偏壓來調變主波
角度,這些天線陣列的實驗結果顯示出二維波束掃瞄器是指日可待的。
另外,一個使用甘式二極體的X頻帶的共平面轉槽線饋入之頻率掃描式主
動漏波天線 被成功的製造出來。這種線路提供了我們能夠製造出小,簡
單,重量輕,便宜而且是可掃描頻率的微波源。
因為共振穿隧二極體有著比任何元件都高的截止頻率,所以它是最適合作
高頻單石微波源的器件。因此我們在論文的後段研究了適合作單石積體電
路用的共振穿隧二極體。我們也使用了直接在晶片上量測及去嵌入(de-
embedding) 的方法來萃取此二極體的等效高 頻參數,這個方法可適用於
任何二極元件。
The quasi-optical power-combining technique is investigated
in this thesisIn part I of the thesis, the performance of 1x1,
2x2, and 4x4 varactor-tuned Gunn diodes grid oscillators has
been studied. The frequency of this quasi- optical oscillator
array is tunable electrically, not mechanically moving the
mirror in behind. A two-dimensional analytical method is
established to predict the E-H radiation pattern. The
advantages of the grid oscillator arrayis its simple bias
structure, and no external injection locking is needed,and no
resistors is required to eliminate multimode problem like in the
patch array. Although, we take the back ground plane as a
heat sink, the results shows that the heating problem will
occur if more devices are combined.However,this problem can be
eliminated by using pulsed dc bias input. Therefore,usingpulsed
bias, it can easily combine a large number of devices on the
same plane In part II of the thesis, first, an asymmetrically
feeding Gunn diode active leaky-wave antenna has been
demonstrated in Ku band.And we demonstrated the
frequency scanning capability of this active leaky wave
antenna. The microstrip leaky wave active antenna array of one,
two and four elements are studied. And the beam scanning
phenomenon of four element Gunn diode oscillator leaky wave
antenna array is measured. diode oscillator leaky wave antenna
array is measured.The main beam angle could change from 36°to
48°for the Gunn VCO frequency tuned from 12.065GHz to
11.867GHz. Their result appears that two dimensional beam
scanning source is amenable. Secondly, a X-band CPW-
to-Slotline feeding to microstrip line leaky wave active
antenna using Gunn diode oscillator is investigated. The
circuits offers a possibility for completely monolithic
millimeter wave circuits, which provide a small, simple,
light weight, low cost, and a frequency scanning source
for many applications.
Resonant tunneling diodes (RTDs) are suitable devices to design
for a monolithic high frequency source, because it has the
highest cutoff frequency than any other devices. Therefor, in
the appendix, a study of monolithic RTD device has been
included. A good DC characteristic is measured. And a method to
extract the high frequency RTD equivalent model has been
developed including on wafer testing and de-embeding
considerations. This process could be very suit for any other
two terminal devices, such as Gunn diodes, IMPATT diode et al.
Cover
Abstract (Chinese)
Abstract (English)
Acknowledgments
Contents
Table Captions
Figure Captions
Chapter 1 Introduction
1.1 Motivation and Objectives of this Thesis
1.2 Organization of the Dissertation
References for Chapter 1
Chapter 2. Quasi-Optical Varactor-Tune Gunn Diode Oscillator Array
2.1 Introductions
2.2 Analysis of Grid Oscillators''Array
2.3 Measurement setup for Grid Oscillators
2.4 Design,Analysis and Performance of Varactor-Tuned X-band Grid Oscillator
2.5 Conclusions
References for Chapter 2
Chapter 3 Scanning Active-Integrated Leaky wave antenna
3.1 Introduction
3.2 Ku-Band Active-Integrated Leaky Wave Antenna Design
3.3 X-band Frequency Scanning Active Leaky Wave Antenna
3.4 Microstrip Leaky Wave Antenna Array
3.5 conclusions
References for Chapter 3
Chapter 4 A conductor-Backed CPW-to-Slotline Feeding Leaky Wave Antenna
4.1 Introduction
4.2 Design of CPW-to-Slotline Feeding Leaky wave antenna
4.3 Conclusions
References for Chapter 4
Chapter 5 Conclusions
Appendix: Study of Solid State Devices for MMIC (RTDs)
A.1. Introduction
A.2. Molecular Beam Epitaxy Growth
A.3. Degice Processing
A.4. Measurements and Results
A.5. Conclusions
References for Appendis
Vita
Publication List
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