模拟集成电路设计第一章-综述

1、Introduction of this courseLecturer: Dr. Wu Zhaohui,School of Electronic and Information Engineering , SCUT , ,ourse Name: Analysis and Design of Analog Integrated CircuitsIntroduction of this courseText book(英文版教材）英文版教材）: 1、Behzad Razavi, 模拟CMOS集成电路设计（影印版），清华大学出版社， 2005。中文翻译教材中文翻译教材: :

2、 1、模拟CMOS集成电路设计 作者：毕查德拉扎维，译：陈贵灿、程军、 张瑞智出版社：西安交通大学出版社 ，2003。Main reference book（参考书）（参考书）: 1、CMOS模拟集成电路设计（第二版）作者：phillip E. Allen, Douglas R. Holberg译：冯军、李智群出版社：电子工业出版社，2005。Introduction to Analog DesignWhy analog? (1)1. Processing of Natural SignalsNatural signals are analog, while many signals we u

3、sed are digitalSo we need ADC to convert an analog signal to digital signal and then use DSP to process the digital signal.Fig. 1.1a Digitization of a natural signalsIntroduction to Analog DesignWhy analog? (2)1. Processing of Natural SignalsWell some times, the natural signals are very small, or th

4、ere exist many interferers (干扰）. In this case, the small signal cannot be converted directly into digital correctly. Therefore, an amplifier (放大器）and a filter (滤波器）are needed before converting.Fig. 1.1b Addition of amplification and filtering for higher sensitivity (灵敏度）Introduction to Analog Design

5、Why analog? (3)2. Digital communicationsA digital signal through a long cable will be attentuated and distorted.Multi-level signal processing maybe needed to reduce the required transmission bandwidth (传输带宽）Need a DAC in the transmitter to produce multiple levels from the grouped binary data and an

6、ADC in the receiver to determine which level has been transmitted.Fig. 1.2 Attentuation（衰减） and Distortion （失真） of data through a lossy cableIntroduction to Analog DesignWhy analog? (4)Fig. 1.3 Multi-level signaling to reduce the bandwidthIntroduction to Analog DesignWhy analog? (5)3. Disk Drive Ele

7、ctronics The signal received from the magnetic head is really weak and the noise is quite high.Just like Fig. 1.1b, there needs amplification, filtering and ADC for further processing.Fig. 1.4 Data stored in and received from a hard diskIntroduction to Analog DesignWhy analog? (6)3. Wireless Receive

8、rs A radio-frequency (RF,射频) signal received by a cell phone （手机）is usually only a few microvolts and its center frequency is usually 1Ghz or higher, while the value of the interferers are higher.Therefore, a high frequency of amplifier and filter are needed.Fig. 1.5 Signal and interferers received

9、by the antenna of a wireless receiver.Introduction to Analog DesignWhy analog? (7)4. Optical Receivers High frequency signals are not suitable for transmitting over long distance in the traditional cable due to the severe interference and considerable attenuation because of the limited bandwidth of

10、the cable.In this case, the electrical high frequency signals are converted into the optical signals first by the laser diode, then these optic signals are transmitted by an optical fiber, which has extremely wide band and very low loss.In the other end, the optical signals are converted into electr

11、ical signals again by the photodiode.Introduction to Analog DesignWhy analog? (8)Since the electrical current converted by a photodiode is very small, the receiver after the photodiode must process a low-level signal at a very high speed, which requires a low noise, broadband circuit design. Fig. 1.

12、6 Optical fiber systemIntroduction to Analog DesignWhy analog? (9)5. Smart sensors When the car hits an obstacle, the drop in the speed is measured as acceleration. If this acceleration exceeds a certain threshold, the air bag will be released.Since the change of the capacitance is quite small, the

13、electrical signal received is very weak and the there exist large interference, hence the amplification, filtering and ADC are needed to handle these small signals properly.Fig. 1.7 Differential accelerometer used in the ABS (安全气囊） system of a car.Introduction to Analog DesignWhy CMOS (1)?CMOS is wi

14、dely used in digital circuit design due to its low power and low fabrication cost.In the old age, bipolar is often used in the analog circuit design because the speed of the CMOS is not high enough.After scaling down again and again, the speed of CMOS is greatly increased. Nowadays, it is comparable

15、 with BIP. Introduction to Analog DesignWhy CMOS (2)?Combining with other advantages, it is time for CMOS to replace bipolar in the analog IC design.The most important force to apply CMOS technology to analog design is the possibility of placing both analog and digital circuits on the same chip so a

16、s to improve the overall performance and reduce the cost of packaging.This is often called as mixed IC design, which is very hot in IC design nowadays.Introduction to Analog DesignLevel of abstractionFig. 1.8 Abstraction levels in circuit design数模混合IC设计实例（1）采用硅微机械加工技术的植入式记录电极及其在大鼠体内的记录结果采用硅微机械加工技术的植

17、入式记录电极及其在大鼠体内的记录结果 植入生物体的微电子电路在临床上已广泛应用于心率调节、人工耳蜗、人工视网膜修复、泌尿控制与功能性神经肌肉电刺激、以及癫痫和脊柱损伤等康复医疗中。无线植入式神经信号采集系统神经信号记录电极2. 体内至体外无线数据传送通路1. 体外至体内的无线能量及控制数据传送通路数模混合IC设计实例（2）数模混合IC设计实例（3）新型新型8通道低噪声神经信号前端放大芯片通道低噪声神经信号前端放大芯片8通道前端芯片关键指标工艺0.35m CMOS process带内等效输入噪声2.602 Vrms 总面积1700m2479m通道增益46.38dB 5kHz电源5V低频截止点8.

18、2 Hz功耗/CH39.79uA/CH高频截止点10.71K HzTHD(1%)8.1mV共模抑制比70 dB8通道前端芯片版图数模混合IC设计实例（4）低功耗低功耗12位差分位差分SAR A/DADC电路框图ADC芯片照片ADC芯片关键指标工艺0.35m CMOS process信噪失真比58.3dB 1.253kHz分辨率12bit无杂散动态范围72.6dB 1.253kHz采样速度20KS/s有效位9.4bits电源3.3V微分非线性2.2LSB输入幅度2Vpp differential积分非线性2.5LSB数模混合IC设计实例（5） 433M Class E 功率放大器功率放大器433

19、M Class E 功率放大器版图主要参数主要参数结果结果工艺最小尺寸/VDD0.18um/1.8V芯片面积(mm2)1.4*1.4功耗(mW)12S11（dB）-11S22（dB）-15功率增益（dB）11.8附加功率效率（PAE）38%数模混合IC设计实例（6） 433M AM Transmitter 主要参数主要参数测试结果测试结果工艺最小尺寸/VDD0.18m /1.8V芯片总面积(mm2)0.25载波频率(MHz)433.92功耗(mW)15输出信号包络310mVpp*调制深度52%*表3 433.92MHz AM发射芯片关键性能指标433M AM Transmitter 版图433

20、M AM Transmitter output waveform数模混合IC设计实例（7） 433M LNA 表3 433.92MHz AM发射芯片关键性能指标参数参数测试结果测试结果工艺最小尺寸/VDD0.18m/1.8V功率增益（dB）16.8功耗(mW)81dB压缩点（dB）-30噪声系数（dB）3.13433M LNA 版图433M LNA Noise FactorMaterials provided in this Lecture (1)(1) Introduction(2) Basic MOS Device Physics （基本MOS器件物理）(3) Single-Stage Amplifiers (单级放大器）(4) Differential Amplifiers （差分放大器）(5)