Nanoelectronic Mixed-Signal System Design

by: Saraju P. Mohanty, Ph.D.


Abstract: Cutting-edge nanoelectronic mixed-signal system design methods. Written by the director of the NanoSystem Design Laboratory at the University of North Texas, this authoritative resource discusses mixed-signal circuit and system design based on existing and emerging nanoelectronic technologies. The book features coverage of both digital and analog applications using nanoscale CMOS and post-CMOS. Key techniques required for design for excellence and manufacturability are discussed in this practice-driven text. Nanoelectronic Mixed-Signal System Design covers: • Opportunities and challenges of nanoscale technology and systems • Emerging systems designed as analog/mixed-signal system-on-chips (AMS-SoCs) • Nanoelectronics issues in design for excellence • Phase-locked loop component circuits • Electronic signal converter circuits • Sensor circuits and systems • Memory in the AMS-SoCs • Mixed-signal circuit and system design flow • Mixed-signal circuit and system simulation • Power-, parasitic-, and thermal-aware AMS-SoC design methodologies • Variability-aware AMS-SoC design methodologies • Metamodel-based fast AMS-SoC design methodologies
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Book Details

Title: Nanoelectronic Mixed-Signal System Design

Publisher: McGraw-Hill Education: New York, Chicago, San Francisco, Athens, London, Madrid, Mexico City, Milan, New Delhi, Singapore, Sydney, Toronto

Copyright / Pub. Date: 2015 McGraw-Hill Education

ISBN: 9780071825719

Authors:

Saraju P. Mohanty, Ph.D. is a faculty member in the Department of Computer Science and Engineering at the University of North Texas, where he directs the NanoSystem Design Laboratory (NSDL). He obtained a Ph.D. in computer science and engineering from the University of South Florida in 2003, a master's degree in systems science and automation from the Indian Institute of Science, Bangalore, India, in 1999, and a bachelor's degree (honors) in electrical engineering from Orissa University of Agriculture and Technology, Bhubaneswar, India, in 1995. Dr. Mohanty's research is in low-power, high-performance nanoelectronics. He is an author of hundreds of peer-reviewed journal and conference publications. Dr. Mohanty holds many U.S. patents in the areas of VLSI, nanoelectronics, and security hardware. He has advised/co-advised many Ph.D. dissertations and numerous master's theses. Dr. Mohanty currently serves as the chair of the Technical Committee on Very Large Scale Integration (TCVLSI), IEEE Computer Society (IEEE-CS). He serves on the editorial board of many peer-reviewed international journals, including IET-CDS Journal, Elsevier Integration Journal, and Journal of Low Power Electronics. Dr. Mohanty has served as a guest editor for many journals, including ACM Journal on Emerging Technologies in Computing Systems (JETC) for an issue titled "New Circuit and Architecture-Level Solutions for Multidiscipline Systems," August 2012, and IET Circuits, Devices & Systems (CDS) for an issue titled "Design Methodologies for Nanoelectronic Digital and Analog Circuits," September 2013. He serves on the organizing and program committees of several international conferences. Dr. Mohanty is a senior member of the IEEE and ACM.

Description: Cutting-edge nanoelectronic mixed-signal system design methods. Written by the director of the NanoSystem Design Laboratory at the University of North Texas, this authoritative resource discusses mixed-signal circuit and system design based on existing and emerging nanoelectronic technologies. The book features coverage of both digital and analog applications using nanoscale CMOS and post-CMOS. Key techniques required for design for excellence and manufacturability are discussed in this practice-driven text. Nanoelectronic Mixed-Signal System Design covers: • Opportunities and challenges of nanoscale technology and systems • Emerging systems designed as analog/mixed-signal system-on-chips (AMS-SoCs) • Nanoelectronics issues in design for excellence • Phase-locked loop component circuits • Electronic signal converter circuits • Sensor circuits and systems • Memory in the AMS-SoCs • Mixed-signal circuit and system design flow • Mixed-signal circuit and system simulation • Power-, parasitic-, and thermal-aware AMS-SoC design methodologies • Variability-aware AMS-SoC design methodologies • Metamodel-based fast AMS-SoC design methodologies