عنوان
پدید آورنده
موضوع
رده
TK 7874 .78 .Y46
TK
7874
.
78
.
Y46
کتابخانه
محل استقرار
عنوان و نام پديدآور
عنوان اصلي
Design of CMOS RF integrated circuits and systems
وضعیت نشر و پخش و غیره
محل نشرو پخش و غیره
Singapore
نام ناشر، پخش کننده و غيره
World Scientific
تاریخ نشرو بخش و غیره
2010
مشخصات ظاهری
نام خاص و کميت اثر
xv, 341 p. : ill. ; 24 cm.
يادداشت کلی
متن يادداشت
Includes bibliographical references and index
یادداشتهای مربوط به عنوان و پدیدآور
متن يادداشت
Kiat Seng Yeo, Manh Anh Do, Chirn Chye Boon
یادداشتهای مربوط به مندرجات
متن يادداشت
Chapter 1. RF CMOS Systems on Chips -- 1.1. Modern RF Mobile Technologies -- 1.2. The RF Transceiver System -- 1.3. Modulation and Demodulation Techniques -- 1.4. Multiple Access Techniques -- 1.5. Receiver Sensitivity and Linearity -- 1.6. On-chip Power Amplifier -- 1.7. The Cellular Phone Concept -- 1.8. The CMOS RF Technology -- References -- Chapter 2. RF CMOS Devices and Process Design Kits -- 2.1. Introduction -- 2.2. RF Transistors -- 2.2.1. BSIM3v3 Model -- 2.2.2. BSIM4 Model -- 2.2.3. Figure of Merit -- 2.2.3.1. fT definition and extraction -- 2.2.3.2. fMAX definition and extraction -- 2.2.4. RF Parasitics in MOSFETs -- 2.2.5. Scalable RF CMOS Transistor Modeling -- 2.2.5.1. RF MOSFET model -- 2.2.5.2. Gate resistance modeling -- 2.2.5.3. Source and drain resistance modeling -- 2.2.5.4. Gate to substrate capacitance and resistance modeling -- 2.2.5.5. Gate to source and gate to drain capacitance modeling -- 2.2.5.6. Drain to source capacitance modeling -- 2.2.5.7. Substrate resistance modeling -- 2.3. On-chip Inductors -- 2.3.1. Spiral Inductors on Silicon -- 2.3.1.1. Figure of merits -- 2.3.2. Advantages of Silicon-based Spiral Inductors -- 2.3.3. Identifying Loss Mechanisms in Silicon-based Spiral Inductors -- 2.3.3.1. Metallization resistive loss -- 2.3.3.2. Substrate capacitive and resistive loss -- 2.3.3.3. Substrate eddy current -- 2.3.4. Q-Factor Enhancement Techniques -- 2.3.4.1. Q-factor enhancement using processing technologies -- 2.3.4.2. Q-factor enhancement using active inductors -- 2.3.4.3. Q-factor enhancement using coupled spiral coils -- 2.3.4.4. Q-factor enhancement using layout optimization -- 2.3.4.5. Q-factor enhancement using inductor device model -- 2.3.4.6. Figure of merits for differential spiral inductors -- 2.4. Baluns/Transformers -- 2.4.1. The Ideal Transformer -- 2.4.2. Transformer Types -- 2.4.3. Inductance, Capacitance, and Resistance -- 2.4.4. Coupling Coefficient k, Turn Ratio n, and Quality Factor Q -- 2.4.5. Patterned Ground Shield -- 2.4.6. Designing the Transformer -- 2.5. RF Interconnects -- 2.5.1. Transmission Line Concept -- 2.5.1.1. Transmission line constants -- 2.5.1.2. Transmission line impedances -- 2.5.1.3. Reflection and voltage standing wave ratio -- 2.5.1.4. Frequency-dependent charge distribution -- 2.5.1.5. Effects of dielectric on interconnects -- 2.5.2. Existing Methodologies to Tackle Post Layout Parasitics -- 2.5.3. Proposed Figure of Merit for RF Interconnects -- 2.6. Varactors -- 2.6.1. Functions of Varactors -- 2.6.2. Varactor Design -- 2.7. RF Capacitors -- 2.7.1. Capacitance -- 2.7.2. Geometry -- 2.7.3. Quality Factor and Series Resistance -- 2.7.4. Capacitance Modeling -- 2.7.5. Impedances -- 2.7.6. Design Considerations -- 2.8. Process Design Kits -- 2.8.1. Benefits -- 2.8.2. Advanced Device Modeling and Front-end Design -- 2.8.3. Back-end Design and Accelerated Layout -- 2.8.4. Physical Verification and Silicon Analysis -- 2.8.5. Future of Process Design Kits -- 2.9. Summary -- References -- Chapter 3. RF CMOS Low Noise Amplifiers -- 3.1. Basic Concepts of LNAs -- 3.1.1. Operating Frequency -- 3.1.2. Sensitivity -- 3.1.3. Noise Figure and Voltage Gain -- 3.1.4. 1 -dB Compression Point -- 3.1.5. The 3rd Order Intercept Point -- 3.1.6. S-Parameters -- 3.2. Input Architecture of LNAs -- 3.2.1. Common Source Stage with Resistive Termination -- 3.2.2. Common Gate Stage -- 3.2.3. Common Source Stage with Shunt Feedback -- 3.2.4. Common Source Stage with Source Inductive Degeneration -- 3.3. Input Matching Analysis -- 3.4. Design of a Single-band LNA )LNA1( -- 3.4.1. Noise Figure Optimization -- 3.4.2. Design Methodology -- 3.4.3. Measurement Results -- 3.5. Summary -- References -- Chapter 4. RF Mixers -- 4.1. Introduction -- 4.2. Common Configurations of Active Mixers -- 4.3. Active Mixer with Current Booster -- 4.4. Passive Mixers -- 4.5. Port Isolation and DC Offset in Direct Conversion Mixers -- 4.6. Image Reject Mixers for Low IF Architectures -- References -- Chapter 5. RF CMOS Oscillators -- 5.1. Introduction -- 5.1.1. Ring Oscillator -- 5.1.2. LC Oscillator -- 5.2. Various LC VCO Topologies -- 5.2.1. Colpitts and HartleyLC VCOs -- 5.2.2. Differential LC VCOs -- 5.2.2.1. Complementary LC VCOs -- 5.2.2.2. Tail current source of LC VCOs -- 5.3. LC VCO Design Methodology -- 5.3.1. Topology -- 5.3.1.1. Operation theory -- 5.3.1.2. Equivalent circuit of cross-coupled LC tank VCO -- 5.3.2. Associated Noise Sources of Complementary LC Tank VCO -- 5.3.2.1. Noise sources of the LC tank -- 5.3.2.2. Upconversion of 1/f noise in the tail transistor -- 5.3.3. Noise Sources in Active Devices -- 5.3.3.1. High frequency noise -- 5.3.3.2. Noise sources in cross-coupled transistors -- 5.3.3.3. Optimization of channel length Lch -- 5.3.4. Linear Time Variant )LTV( Phase Noise Analysis -- 5.3.4.1. Definition of Impulse Sensitivity Function )ISF(-د(بخ۹0t( -- 5.3.4.2. Parameterized phase impulse response h۶د )t, ۴د( using ISF -- 5.3.4.3. Phase noise calculation -- 5.3.4.4. Steps to achieve minimal phase noise -- 5.3.5. A 2GHz Cross-Coupled LC Tank VCO -- 5.3.5.1. 2GHz cross-coupled LC tank VCO -- 5.3.5.2. Verifications and discussions -- 5.3.5.3. Experimental results -- 5.3.6. A 9.3 ٶ؟گ 01.4GHz Cross-Coupled Complementary Oscillator -- 5.3.6.1. Phase noise estimation for 01GHzLC tank VCO -- 5.3.6.2. Experimental results -- 5.4. Summary -- References -- Chapter 6. RF CMOS Phase-Locked Loops -- 6.1. Fundamental Principles of a Phase-Locked Loop )PLL( -- 6.2. Transient Characteristics - Tracking -- 6.3. Loop Bandwidth - Second Order PLL -- 6.4. Acquisition -- 6.5. Phase Detector and Loop Filter -- 6.5.1. Phase Detector -- 6.5.1.1. Multiplier -- 6.5.1.2. EXOR gate -- 6.5.1.3. Flip-flop phase detector -- 6.5.1.4. Phase frequency detector -- 6.5.2. Loop Filter -- 6.6. Charge Pump PLL Filter -- 6.7. Noise Characteristics of PLL Building Blocks -- 6.7.1. Phase Noise of VCO -- 6.7.2. Phase Noise of Reference Input Signal -- 6.7.3. Phase Noise of Frequency Divider -- 6.7.4. Phase Noise of Loop Filter -- 6.7.5. Optimum Loop Bandwidth -- 6.8. Summary -- References -- Chapter 7. RF CMOS Prescalers -- 7.1. Prescaler -- 7.1.1. Dual-Modulus Prescaler -- 7.1.2. Dual-Modulus Prescaler with Pulse Swallow Counter -- 7.1.3. Integer-N Architecture through Dual-Modulus Prescaler with Pulse Swallow Counter -- 7.2. DFFs for Prescaler -- 7.2.1. MCML -- 7.2.2. CMOS Dynamic Circuit -- 7.3. Design and Optimization of CMOS Dynamic Circuit )CDC( Based Prescaler -- 7.3.1. E-TSPC Based Divide-by-2 Unit -- 7.3.2. E-TSPC Based Divide-by-2/3 Unit -- 7.3.3. Design Example -- 7.3.4. Simulation and SiliNoise Sources in Active Devices -- 5.3.3.1. High
موضوع (اسم عام یاعبارت اسمی عام)
عنصر شناسه ای
، Radio frequency integrated circuits
عنصر شناسه ای
، Metal oxide semiconductors, Complementary
عنصر شناسه ای
، Wireless communication systems
رده بندی کنگره
شماره رده
TK
7874
.
78
.
Y46
نام شخص به منزله سر شناسه - (مسئولیت معنوی درجه اول )
تاريخ
4691-
عنصر شناسه اي
Yeo, Kiat Seng
کد نقش
AU
نام / عنوان به منزله شناسه افزوده
عنصر شناسه اي
AU Do, Manh Anh
عنصر شناسه اي
AU Boon, Chirn Chye
عنصر شناسه اي
TI
