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博碩士論文 etd-0929113-121513 詳細資訊
Title page for etd-0929113-121513
論文名稱
Title
含積體化被動元件之寬頻與低功率金氧半導體射頻積體電路設計
Design of Wideband and Low-Power CMOS RFICs with Integrated Passive Devices
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
116
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
2013-10-24
繳交日期
Date of Submission
2013-10-29
關鍵字
Keywords
寬頻CMOS射頻前端積體電路、玻璃積體被動元件基板、覆晶式射頻前端模組封裝、CMOS注入鎖定頻率鍵移接收機、CMOS 共閘極低雜訊放大器
Wideband CMOS RF front-end IC, flip-chip RF front-end module package, CMOS injection-locked FSK receiver, CMOS common-gate LNA, glass integrated passive device substrate
統計
Statistics
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The thesis/dissertation has been browsed 7240 times, has been downloaded 0 times.
中文摘要
未來的無線通訊系統將更關注具有高資料傳輸率或者低功率消耗之特徵。本論文致力於研究並實現寬頻接收機之射頻前端積體電路,以及具有高能源效率之射頻接收機。基於上述目標,本論文涵蓋三個主題。首先,本論文提出具有創新架構之兩款寬頻CMOS 共閘極低雜訊放大器,藉由雙迴授機制讓低雜訊放大器同時做到輸入與雜訊阻抗匹配,並透過晶片上變壓器使電路之增益頻寬得以延伸。第二,本論文提出覆晶式射頻前端模組封裝,讓CMOS 射頻前端晶片堆疊在一玻璃積體被動元件基板上,除了在一特定寬頻範圍內具有高線性度與低雜訊指數之特性,還有模組尺寸微型化之優點。最後,本論文提出兩款CMOS 頻率鍵移射頻接收機,因採用注入鎖定技術而免除本地振盪源所依賴之鎖相迴路,故具有架構複雜度低之優點,再配合自我振盪混波器或除二頻器加次諧波混波器等電路,能使接收機在很低的功耗下具有優異之靈敏度。
Abstract
Future wireless communication systems will be more focused on having high data rates or low-power consumption. This dissertation aims to investigate and implement wideband receiver radio-frequency (RF) front-end integrated circuits (ICs) and high energy-efficient RF receivers. Based on this aim, the dissertation includes three major topics. First of all, two novel wideband CMOS common-gate low-noise amplifiers (LNAs) are proposed. They use dual-feedback schemes to simultaneously achieve input and noise impedance matching. Moreover, using an on-chip transformer in these LNAs significantly enhances the bandwidth of the associated gain factors. Next, a flip-chip RF front-end module package which stacks a CMOS RF front-end IC above a glass integrated passive device substrate is studied. This package has not only high linearity and low noise figure over a specific wide frequency range, but also a miniature size. Finally, two frequency shift-keying (FSK) receivers with low
complexity are presented. These receivers utilize an injection-locking technique to remove the widely used phase-locked loop in a local oscillator. Furthermore, combined with a self-oscillating mixer or a divide-by-2 frequency divider plus a subharmonic mixer, the presented FSK receivers achieve superior sensitivity with very low power consumption.
目次 Table of Contents
1 Introduction 1
1.1 Research Motivation 1
1.2 Multi-Band/Multi-Standard Receiver Architectures 3
1.2.1 Front-End Receiver with Multi-Path RF Input 3
1.2.2 Front-End Receiver with Single-Path RF Input 5
1.3 Energy-Efficient Receiver Using Injection Locking Scheme 7
1.4 Dissertation Objectives and Organization 12
2 CMOS Wideband Common-Gate Low-Noise Amplifiers 14
2.1 Introduction 14
2.2 Differential CG LNA with a Gm-Boosted Feedback 15
2.3 Differential CG LNA with a Gm-Boosted and Shunt-Series Dual Feedback 17
2.3.1 Input Impedance Analysis 17
2.3.2 Noise Analysis 18
2.3.3 Voltage Gain and 3-dB Gain Bandwidth Analysis 19
2.4 Differential CG LNA with a Gm-Boosted and Shunt–Shunt Dual Feedback 20
2.4.1 Input Impedance Analysis 20
2.4.2 Noise Analysis 22
2.4.3 Voltage Gain and 3-dB Gain Bandwidth Analysis 23
2.5 Stability Condition and Design Guide 24
2.5.1 Stability 24
2.5.2 Design Guide 24
2.5.3 Comparison of |S11|, BWER, and NF 26
2.6 Circuit Implementation and Experimental Results 29
2.6.1 Circuit Design 29
2.6.2 Experimental Results 31
2.7 Summary 37
3 CMOS Wideband Receiver Front-End Stacked with Glass Integrated Passive Devices 38
3.1 Introduction 38
3.2 Wideband RFE Architectures 40
3.3 Analysis and Design of Wideband RFE 43
3.3.1 Wideband Low-Voltage LNA with GIPD Inductors 43
3.3.2 Wideband CG Down-Conversion Mixer with a PD Linearizer 46
3.3.3 Bifilar Transformer-Based GIPD Balun 51
3.3.4 Stacked RFE with Consideration of Coupling Effects 53
3.4 Experimental Results 55
3.5 Summary 61
4 Low-Power FSK Receivers Using Injection Locking Technique 62
4.1 Introduction 62
4.2 Analysis and Design of ILO-Based FSK Receiver 63
4.2.1 Receiver Architecture 63
4.2.2 Sub-mW LNA 65
4.2.3 Self-Oscillating Mixer 66
4.2.4 Trifilar Transformer-Based Splitter 68
4.2.5 Circuit Design 68
4.2.6 Experimental Results 69
4.3 Analysis and Design of ILFD-Based FSK Receiver 73
4.3.1 Receiver Architecture 74
4.3.2 Cascoded LNA 75
4.3.3 Single-Balanced SHM 75
4.3.4 Injection-Locked ILFD 77
4.3.5 Experimental Results 77
4.4 Summary 80
5 Conclusions 82
Bibliography 84
Vita 98
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