Overview

Until the late 1980s, information processing was associated with large mainframe computers and huge tape drives. During the 1990s, this trend shifted toward information processing with personal computers, or PCs. The trend toward miniaturization continues and in the future the majority of information processing systems will be small mobile computers, many of which will be embedded into larger products and interfaced to the physical environment. Hence, these kinds of systems are called embedded systems. Embedded systems together with their physical environment are called cyber-physical systems. Examples include systems such as transportation and fabrication equipment. It is expected that the total market volume of embedded systems will be significantly larger than that of traditional information processing systems such as PCs and mainframes. Embedded systems share a number of common characteristics. For example, they must be dependable, efficient, meet real-time constraints and require customized user interfaces (instead of generic keyboard and mouse interfaces). Therefore, it makes sense to consider common principles of embedded system design. Embedded System Design starts with an introduction into the area and a survey of specification models and languages for embedded and cyber-physical systems. It provides a brief overview of hardware devices used for such systems and presents the essentials of system software for embedded systems, like real-time operating systems. The book also discusses evaluation and validation techniques for embedded systems. Furthermore, the book presents an overview of techniques for mapping applications to execution platforms. Due to the importance of resource efficiency, the book also contains a selected set of optimization techniques for embedded systems, including special compilation techniques. The book closes with a brief survey on testing. Embedded System Design can be used as a text book for courses on embedded systems and as a source which provides pointers to relevant material in the area for PhD students and teachers. It assumes a basic knowledge of information processing hardware and software. Courseware related to this book is available at http://ls12-www.cs.tu-dortmund.de/~marwedel.

Full Product Details

Author:   Peter Marwedel
Publisher:   Springer
Imprint:   Springer
Edition:   2nd ed. 2011
Dimensions:   Width: 15.50cm , Height: 2.10cm , Length: 23.50cm
Weight:   1.270kg
ISBN:  

9789400702561

ISBN 10:   9400702566
Pages:   400
Publication Date:   25 November 2010
Audience:   Professional and scholarly ,  Professional & Vocational
Replaced By:   9783319560434
Format:   Paperback
Publisher's Status:   Out of Print
Availability:   In Print  
Limited stock is available. It will be ordered for you and shipped pending supplier's limited stock.

Table of Contents

Preface. Acknowledgments. 1. INTRODUCTION. 1.1 Application areas and examples. 1.2 Common characteristics. 1.3 Challenges in Embedded System Design. 1.4 Design Flows. 1.5 Structure of this book. 1.6 Assignments. 2. SPECIFICATIONS AND MODELING. 2.1 Requirements. 2.2 Models of computation. 2.3 Early design phases. 2.4 Communicating finite state machines (CFSMs). 2.5 Data flow. 2.6 Petri nets. 2.7 Discrete event based languages. 2.8 Von-Neumann languages. 2.9 Levels of hardware modeling. 2.10 Comparison of models of computation. 2.11 Assignments. 3. EMBEDDED SYSTEM HARDWARE. 3.1 Introduction. 3.2 Input. 3.3 Processing Units. 3.4 Memories. 3.5 Communications. 3.6 Output. 3.7 Secure hardware. 3.8 Assignments. 4. SYSTEM SOFTWARE. 4.1 Embedded Operating Systems. 4.2 ERIKA. 4.3 Hardware abstraction layers. 4.4 Middleware. 4.5 Real-time databases. 4.6 Assignments. 5. EVALUATION AND VALIDATION. 5.1 Introduction. 5.2 Performance evaluation. 5.3 Energy and power models. 5.4 Thermal models. 5.5 Risk- and dependability analysis. 5.6 Simulation. 5.7 Rapid prototyping and emulation. 5.8 Formal Verification. 5.9 Assignments. 6. APPLICATION MAPPING. 6.1 Problem definition. 6.2 Scheduling in real-time systems. 6.3 Hardware/software partitioning. 6.4 Mapping to heterogeneous multi-processors. 6.5 Assignments. 7. OPTIMIZATION. 7.1 Task level concurrency management. 7.2 High-level optimizations. 7.3 Compilers for embedded systems. 7.4 Power Management and Thermal Management. 7.5 Assignments. 8. TEST. 8.1 Scope. 8.2 Test procedures. 8.3 Evaluation of test pattern sets and system robustness. 8.4 Design for testability. 8.5 Assignments. Appendices. A. Integer linear programming. B. Kirchhoff's laws and operational amplifiers. References. About the author. List of Figures. Index.

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Author Information

Dr. Peter Marwedel received his PhD in Physics from the University of Kiel in 1974. He is one of the early researchers in high level synthesis, working on the MIMOLA system for a number of years. Dr. Marwedel is a professor at the University of Dortmund since 1989. He has served as the chairman of the computer science department, has played a leading role in establishing the Design, Automation and Test in Europe (DATE) conference and is the chairman of the Informatik Centrum Dortmund (ICD), a technology transfer centre.

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