CMOS Integrated analog to digital and digital to analog converter

Tom Lee: The Design of CMOS Radio-Frequency Integrated Circuits, 2nd Ed cmos射频集成电路设计

Multicore and GPU Programming An Integrated Approach.pdf

The second edition of Design of Analog CMOS Integrated Circuits by Behzad Razavi, deals with the analysis and design of analog CMOS integrated circuits, emphasizing fundamentals as well as new paradigms that students and practicing engineers need to master in today's industry. Since analog design requires both intuition and rigor, each concept is first introduced from an intuitive perspective and subsequently treated by careful analysis. The objective is to develop both a solid foundation and methods of analyzing circuits by inspection so that the reader learns what approximations can be made in which circuits and how much error to expect in each approximation. This approach also enables the reader to apply the concepts to bipolar circuits with little additional effort. Table of Contents Chapter 1 Introduction to Analog Design Chapter 2 Basic MOS Device Physics Chapter 3 Single-Stage Amplifiers Chapter 4 Differential Amplifiers Chapter 5 Current Mirrors and Biasing Techniques Chapter 6 Frequency Response of Amplifiers Chapter 7 Noise Chapter 8 Feedback Chapter 9 Operational Amplifiers Chapter 10 Stability and Frequency Compensation Chapter 11 Nanometer Design Studies Chapter 12 Bandgap References Chapter 13 Introduction to Switched-Capacitor Circuits Chapter 14 Nonlinearity and Mismatch Chapter 15 Oscillators Chapter 16 Phase-Locked Loops Chapter 17 Short-Channel Effects and Device Models Chapter 18 CMOS Processing Technology Chapter 19 Layout and Packaging

半导体激光器经典教材

Device Electronics for Integrated Circuit 3rd，中文版

ContentsForeword xvAcknowledgments xix1 Introduction to Communications Circuits 11.1 Introduction 11.2 Lower Frequency Analog Design and MicrowaveDesign Versus Radio Frequency IntegratedCircuit Design 21.2.1 Impedance Levels for Microwave and Low-Frequency Analog Design 21.2.2 Units for Microwave and Low-Frequency AnalogDesign 31.3 Radio Frequency Integrated Circuits Used in aCommunications Transceiver 41.4 Overview 6References 62 Issues in RFIC Design, Noise, Linearity, andFiltering 92.1 Introduction 9vvi Radio Frequency Integrated Circuit Design2.2 Noise 92.2.1 Thermal Noise 102.2.2 Available Noise Power 112.2.3 Available Power from Antenna 112.2.4 The Concept of Noise Figure 132.2.5 The Noise Figure of an Amplifier Circuit 142.2.6 The Noise Figure of Components in Series 162.3 Linearity and Distortion in RF Circuits 232.3.1 Power Series Expansion 232.3.2 Third-Order Intercept Point 272.3.3 Second-Order Intercept Point 292.3.4 The 1-dB Compression Point 302.3.5 Relationships Between 1-dB Compression andIP3 Points 312.3.6 Broadband Measures of Linearity 322.4 Dynamic Range 352.5 Filtering Issues 372.5.1 Image Signals and Image Reject Filtering 372.5.2 Blockers and Blocker Filtering 39References 41Selected Bibliography 423 A Brief Review of Technology 433.1 Introduction 433.2 Bipolar Transistor Description 43Current Dependence 463.33.4 Small-Signal Model 473.5 Small-Signal Parameters 483.6 High-Frequency Effects 49as a Function of Current 513.6.1 fT3.7 Noise in Bipolar Transistors 533.7.1 Thermal Noise in Transistor Components 533.7.2 Shot Noise 533.7.3 1/f Noise 54vii3.8 Base Shot Noise Discussion 553.9 Noise Sources in the Transistor Model 553.10 Bipolar Transistor Design Considerations 563.11 CMOS Transistors 573.11

During the last decades much has been prophesized that there will be little need for analog circuitry in the future because digital electronics is taking over. Far from having proven true, this contention has provoked controversial rebuttals, as epitomized by statements such as “If you cannot do it in digital, it’s got to be done in analog.” Add to this the common misconception that analog design, compared to digital design, seems to be more of a whimsical art than a systematic science, and what is the confused student to make of this controversy? Is it worth pursuing some coursework in analog electronics, or is it better to focus just on digital?

SWIM模型是一个连续的半分布式模型，包含水文、植被生长、养分循环、泥沙运动等过程。此外，模型通过与地理信息系统的耦合，可以提取高程、土地利用、土壤和植被类型的空间分布等参数和数据，创建描述水文影响单元结构的输入文件和流域汇流结构，属于中等复杂程度的生态水文过程。 该模型德国波茨坦气象影响研究所(PIK)研发。 SWIM模型是在SWAT（Arnold等，1993&1994;）和MATSALU（Krysanova等,1989)模型的基础上开发而成。

集成电路教材经典之作。 作者:拉贝 (Rabaey Jan M.) 钱德拉卡山 (Chandrakasan A) 尼科利奇 (Nikolic B.)