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SECTION II: CMOS THZ SIGNAL GENERATION
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SECTION II: CMOS THZ SIGNAL GENERATION
by Hao Yu
Design of CMOS Millimeter-Wave and Terahertz Integrated Circuits with Metamaterials
Contents (1/2)
Contents (2/2)
List of Figures (1/3)
List of Figures (2/3)
List of Figures (3/3)
List of Tables
Preface
Acknowledgments
SECTION I: FUNDAMENTALS
Chapter 1: Introduction
1.1 Overview of Terahertz Technology
1.1.1 Terahertz Applications
1.1.2 Optics-Based Terahertz System
1.2 CMOS THz Electronics
1.3 CMOS THz Applications (1/2)
1.3 CMOS THz Applications (2/2)
1.3.1 THz CMOS Imaging
1.3.2 THz CMOS Communication
Chapter 2: CMOS Metamaterial Devices
2.1 Introduction
2.2 Non-Resonant-Type Metamaterial (1/3)
2.2 Non-Resonant-Type Metamaterial (2/3)
2.2 Non-Resonant-Type Metamaterial (3/3)
2.2.1 Composite Right-/Left-Handed T-Line
2.2.2 Magnetic Plasmon Waveguide
2.3 Resonant-Type Metamaterial
2.3.1 T-Line Loaded with Split Ring Resonator
2.3.2 T-Line Loaded with Complementary Split Ring Resonator
2.4 CMOS Coherent THz Electronics by Metamaterial
2.4.1 Coherent Source
2.4.2 Coherent Transmission
2.4.3 Coherent Detection
2.4.4 Transceiver Architecture
Chapter 3: CMOS THz Modeling
3.1 Introduction
3.2 Fractional-Order T-Line Model
3.2.1 Fractional Calculus
3.2.2 Fractional-Order Capacitance and Inductance
3.2.3 Fractional-Order T-Line Model
3.2.4 Fractional-Order CRLH T-Line Model
3.3 Model Extraction and Causality Analysis
3.3.1 Fractional-Order Model Extraction
3.3.2 Causal LTI System and Causality Enforcement
3.3.3 Causality of T-Line Model
3.4 Prototyping and Measurement (1/3)
3.4 Prototyping and Measurement (2/3)
3.4 Prototyping and Measurement (3/3)
3.4.1 T-Line Fractional-Order Model Verification
3.4.2 CRLH T-Line Fractional-Order Model Verification
3.4.3 Causality Verification and Comparison
3.5 Conclusion
SECTION II: CMOS THZ SIGNAL GENERATION
Chapter 4: Oscillator
4.1 Introduction
4.2 Frequency Tuning by Loaded Transformer (1/3)
4.2 Frequency Tuning by Loaded Transformer (2/3)
4.2 Frequency Tuning by Loaded Transformer (3/3)
4.2.1 Inductive Tuning Analysis
4.2.2 Inductor-Loaded Transformer by Switching Return-Path
4.3 Frequency Tuning by CRLH T-Line
4.3.1 CRLH T-Line-Based RTW-VCO
4.3.2 Wide-Band Tuning for CRLH T-Line-Based RTW-VCO
4.4 Circuit Prototyping and Measurement (1/4)
4.4 Circuit Prototyping and Measurement (2/4)
4.4 Circuit Prototyping and Measurement (3/4)
4.4 Circuit Prototyping and Measurement (4/4)
4.4.1 60-GHz VCO Prototype with Asymmetric Implementation of Inductive Tuning
4.4.2 60-GHz VCO Prototype with Symmetric Implementation of Inductive Tuning
4.4.3 90-GHz VCO Prototype with CRLH T-LineBased RTW
4.5 Conclusion
Chapter 5: Coupled Oscillator Network
5.1 Introduction
5.2 In-Phase Signal Generation by MPW
5.3 Circuit Prototyping and Measurement (1/5)
5.3 Circuit Prototyping and Measurement (2/5)
5.3 Circuit Prototyping and Measurement (3/5)
5.3 Circuit Prototyping and Measurement (4/5)
5.3 Circuit Prototyping and Measurement (5/5)
5.3.1 60 GHz CON Signal Source
5.3.2 140 GHz CON Signal Source
5.3.3 280 GHz CON Signal Source
5.4 Conclusion
Chapter 6: Phase-Locked Loop
6.1 Introduction
6.2 60-GHz PLL Design
6.3 Circuit Prototyping and Simulation
6.3.1 Divider Measurement Results
6.3.2 PLL Simulation Results
SECTION III: CMOS THZ SIGNAL AMPLIFICATION AND TRANSMISSION
Chapter 7: Power Combiner
7.1 Introduction
7.2 In-Phase Signal Transmission by CRLH Zero-Phase-Shifter
7.3 PA Design with Power Combining Network (1/5)
7.3 PA Design with Power Combining Network (2/5)
7.3 PA Design with Power Combining Network (3/5)
7.3 PA Design with Power Combining Network (4/5)
7.3 PA Design with Power Combining Network (5/5)
7.3.1 SEDFDA-Based PA Design
7.3.2 ZPS-Based 2D Distributed Power Combining for PA
7.3.3 Stabilization Techniques
7.3.4 Digital Control
7.4 Circuit Prototyping and Measurement (1/5)
7.4 Circuit Prototyping and Measurement (2/5)
7.4 Circuit Prototyping and Measurement (3/5)
7.4 Circuit Prototyping and Measurement (4/5)
7.4 Circuit Prototyping and Measurement (5/5)
7.4.1 60 GHz PA Design with Single-Ended 2x2 Power Combining
7.4.2 60 GHw PA Design with Differential 2x4 Power Combining
7.4.3 60 GHz PA Prototype with Differential 4 x 4 Power Combining and Digital Control
7.5 Conclusion
Chapter 8: Antenna
8.1 Introduction
8.2 CRLH T-Line-Based Leaky Wave Antenna
8.3 Circularly Polarized SIW Antenna
8.4 Circuit Prototyping and Measurement (1/2)
8.4 Circuit Prototyping and Measurement (2/2)
8.4.1 280-GHz LWA
8.4.2 280-GHz SIW
8.5 Conclusion
SECTION IV: CMOS THZ SIGNAL DETECTION
Chapter 9: Resonator
9.1 Introduction
9.2 Differential TL-SRR Resonator
9.2.1 Stacked SRR Layout
9.2.2 Comparison with Single-Ended TL-SRR Resonator
9.2.3 Comparison with Standing-Wave Resonator
9.3 Differential TL-CSRR Resonator
9.4 Circuit Prototyping and Measurement (1/2)
9.4 Circuit Prototyping and Measurement (2/2)
9.4.1 76-GHz Differential TL-SRR Resonator
9.4.2 96-GHz Differential TL-CSRR Resonator
9.4.3 Measurements
9.5 Conclusion
Chapter 10: Super-Regenerative Detection
10.1 Introduction
10.2 Fundamentals of Super-Regenerative Amplification
10.2.1 Equivalent Circuit of SRA
10.2.2 Frequency Response of SRA
10.2.3 Sensitivity of SRA
10.3 Super-Regenerative Receiver by SRR/CSRR Resonator (1/2)
10.3 Super-Regenerative Receiver by SRR/CSRR Resonator (2/2)
10.3.1 Quench-Controlled Oscillation
10.3.2 SRX Design by TL-CSRR
10.3.3 SRX Design by TL-SRR
10.4 Circuit Prototyping and Measurement
10.4.1 DTL-CSRR-Based SRX at 96 GHz
10.4.2 DTL-SRR-Based SRX at 135 GHz
10.4.3 Comparison and Discussion
10.5 Conclusion
Chapter 11: In-Phase Detection
11.1 Introduction
11.2 SRX Sensitivity Enhancement by ZPS-Coupled CON
11.3 Circuit Prototyping and Measurement
11.3.1 SRX Circuit Design
11.3.2 Measurements
11.4 Conclusion
SECTION V: APPLICATIONS
Chapter 12: CMOS THz Imaging
12.1 Introduction
12.2 135-GHz Narrow-Band Imager by DTL-SRR-Based SRX
12.2.1 THz Imaging by SRA Detection
12.2.2 Narrow-Band Imaging Results
12.3 240
12.3 240 ∼ 280-GHz Wide-Band Imager with Heterodyne Receiver
12.3.1 Architecture and System Specification
12.3.2 Down-Conversion Mixer
12.3.3 Power Gain Amplifier
12.3.4 Wide-Band Imaging Results
12.3.5 Wide-Band THz Imaging
12.4 280-GHz Reflective Imaging System (1/3)
12.4 280-GHz Reflective Imaging System (2/3)
12.4 280-GHz Reflective Imaging System (3/3)
12.4.1 Differential Down-Conversion Receiver
12.4.2 2D On-Chip Leaky Wave Antenna Array
12.4.3 Transceiver Integration
12.5 Conclusion
Chapter 13: CMOS THz Wireless Communication
13.1 Introduction
13.2 Massive MIMO Transceiver
13.3 Conclusion
Chapter 14: CMOS THz Wireline Communication
14.1 Introduction
14.2 Surface Plasmon Polariton T-Line (1/3)
14.2 Surface Plasmon Polariton T-Line (2/3)
14.2 Surface Plasmon Polariton T-Line (3/3)
14.3 SRR Modulator (1/2)
14.3 SRR Modulator (2/2)
14.4 Multi-Channel I/O Transceiver (1/2)
14.4 Multi-Channel I/O Transceiver (2/2)
14.5 Conclusion
References (1/7)
References (2/7)
References (3/7)
References (4/7)
References (5/7)
References (6/7)
References (7/7)
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Chapter 4: Oscillator
CMOS
THZ
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