Advanced Digital Integrated Circuits
EE203:高级数字集成电路视频课程
Instructor: Professor Jan Rabaey
课程共27讲,每讲约80分钟
UC Berkekey 电子工程专业研究生课程
Advanced Digital Integrated Circuits 是 UC Berkekey 研究生课程,共27讲,每讲80分钟左右;课程视频全为.rm格式,同时有与视频课程内容配套的完整的课程讲义;有了课程讲义让您的学习更有效,在潜移默化中提高专业知识和英语能力。
加州大学伯克莱分校(UC Berkeley)作为世界一流大学,有着世界顶级的大师,所设课程也都是精品中的精品,紧跟最新科技的进展。本站推出的美国一流大学电子、射频、通信精品视频课程套装,让您足不出户就能一睹世界一流大学大师教学的风采;聆听大师的声音、拓展国际化的视野、与国际水平看齐、实现自我价值的提升。
This course aims to convey a knowledge of advanced concepts of circuit design for digital VLSI components in state of the art MOS technologies. Emphasis is on the circuit design, optimization, and layout of either very high speed, high density or low power circuits for use in applications such as micro-processors, signal and multimedia processors, memory and periphery. Special attention will devoted to the most important challenges facing digital circuit designers today and in the coming decade, being the impact of scaling, deep submicron effects, interconnect, signal integrity, power distribution and consumption, and timing.
This semester, extra focus will be given to the following topics: Low power and low-voltage, process variations and robustness, and memory design in the nano scale era. This will reflected in both the lectures and the preferred projects
J. Rabaey, A. Chandrakasan, B. Nikolic, Digital Integrated Circuits: A Design Perspective , 2nd Edition, Prentice Hall, 2003.
Other books:
1. S. Narendra and A. Chandrakasan, "Leakage in Nanometer CMOS Technologies", Springer, 2006.
2. B. Wong et al, "Nano-CMOS Circuit and Physical Design", Wiley, 2005.
3. C. Piguet Ed, "Low Power Electronics Design," CRC Press, 2004.
4. A. Chandrakasan, W. Bowhill, F. Fox, "Design of High-Performance Microprocessor Circuits", IEEE Press, 2001.
5. W.J. Dally and J.W. Poulton, "Digital System Engineering", Cambridge University Press, 1998.
6. K. Bernstein, et al, "High Speed CMOS Design Styles," Kluwer Academic Publishers, 1998.
7. V.G. Oklobdzija, "High-Performance System Design: Circuits and Logic," IEEE Press, 1999.
8. A. Chandrakasan and R. Brodersen, "Low-Power CMOS Design", IEEE Press, 1998..
● Introduction and future prospects
● Transistor Modeling
● Delay models
● Optimization for speed
● Static and PT Logic
● Dynamic Logic
● Other high-speed logic
● Low power design
● Voltage scaling
● Dealing with leakage
● Energy recovery
● Ultra-Low Voltage
● Power distribution
● Process Variations
● Timing concepts, Alternative timing
● Clock distribution
● Memory
● Arithmetic
