1.Introduction.- 2.Smart Electronic Systems: An Overview.- 3.Design domains and abstraction levels for effective smart system simulation.- 4. Energy-Efficient Digital Processing via Approximate Computing.- 5.Discrete Power Devices and Power Modules.- 6.MEMS System-Level Modeling and Simulation in Smart Systems.- 7.Modeling and Simulation of the Power Flow in Smart Systems.- 8. Smart system case studies.
Massimo Poncino is Full Professor of Computing
Engineering at Politecnico di Torino. His research interests include the design
automation of digital systems, with special emphasis on low-power embedded
systems. He has coauthored more than 300 publications in the above areas.
Massimo Poncino has served as member of Technical Program Committee of more
than 50 IEEE and ACM conferences. He was the Technical Program Chair of the
2011 IEEE/ACM Symposium on Low-Power Electronics and Design and General co-Chair for the same conference in 2012. He has
served in the Editorial Board of the IEEE Transactions on CAD, IEEE Design
& Test, ACM Transactions on Design Automation of Electronic Systems. Prof.
Poncino is a Senior Member of IEEE and member of the ACM SIGDA Low-Power
Technical Committee.
Nicola Bombieri received the PhD in Computer
Science from the University of Verona in 2008. Since 2008, he is researcher and
Professor Assistant at the Dept. of Computer Science of the University of
Verona. His research activity focuses on design and verification of embedded
systems, automatic generation and optimization of embedded SW, and high
performance computing. He has been involved in several national and
international research projects and has published more than 70 papers on
conference proceedings and journals in the above areas.
Graziano
Pravadelli, IEEE member, is an associate professor at the Computer Science
Department of the University of Verona (Italy) and co-founder of EDALab s.r.l.
(Italy). He received the Laurea Degree and the PhD in Computer Science at
University of Verona, respectively in 2001 and 2004. In 2007, he co-founded
EDALab s.r.l., a SME whose mission consists of giving support for innovation
and technology transfer in embedded system modeling and verification. His main
interests focus on modeling, simulation and semi-formal verification of HW/SW
embedded systems and cyber physical systems, with particular regards to virtual
prototyping, correct-by-construction embedded SW generation, TLM and RTL
modeling, abstraction and refinement techniques, mutation analysis and mutation
testing, functional qualification and assertion-based verification. In this
context, he collaborated in several national and European projects (e.g.,
VERTIGO, COCONUT, COMPLEX, SMAC, CONTREX) and he published more than 100 papers
in international conferences and journals.
This book-presents new methods and tools for the integration and simulation of smart devices. The design approach described in this book explicitly accounts for integration of Smart Systems components and subsystems as a specific constraint. It includes methodologies and EDA tools to enable multi-disciplinary and multi-scale modeling and design, simulation of multi-domain systems, subsystems and components at all levels of abstraction, system integration and exploration for optimization of functional and non-functional metrics.
By covering theoretical and practical aspects of smart device design, this book targets people who are working and studying on hardware/software modelling, component integration and simulation under different positions (system integrators, designers, developers, researchers, teachers, students etc.). In particular, it is a good introduction to people who have interest in managing heterogeneous components in an efficient and effective way on different domains and different abstraction levels. People active in smart device development can understand both the current status of practice and future research directions.
Provides a comprehensive overview of smart systems design, focusing on design challenges and cutting-edge solutions;
Enables development of a co-simulation and co-design environment that accounts for the peculiarities of the basic subsystems and components to be integrated;
Describes development of modeling and design techniques, methods and tools that enable multi-domain simulation and optimization at various levels of abstraction and across different technological domains.