On-Chip Communication Architectures : System on Chip InterconnectMaterial type: TextSeries: eBooks on DemandSystems on Silicon: Publisher: Burlington : Elsevier Science, 2014Description: 1 online resource (541 p.)ISBN: 9780080558288Subject(s): Computer architecture | Interconnects (Integrated circuit technology) | Microcomputers - Buses | Systems on a chip | Systems on a chip. Microcomputers --Buses Computer architecture. Interconnects (Integrated circuit technology)Genre/Form: Electronic books.Additional physical formats: Print version:: On-Chip Communication Architectures : System on Chip InterconnectDDC classification: 621.3815 LOC classification: TK7895.E42 P4 2008Online resources: Click here to view this ebook.
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|Electronic Book||UT Tyler Online Online||TK7895.E42 P4 2008 (Browse shelf)||http://uttyler.eblib.com/patron/FullRecord.aspx?p=349545||Available||EBL349545|
Front Cover; On-Chip Communication Architectures: System on Chip Interconnect; Copyright Page; Contents; Preface; About the Authors; Acknowledgments; List of Contributors; CHAPTER 1 Introduction; 1.1. Trends in System-On-Chip Design; 1.2. Coping with Soc Design Complexity; 1.3. ESL Design Flow; 1.4. On-Chip Communication Architectures: A Quick Look; 1.5. Book Outline; CHAPTER 2 Basic Concepts of Bus-Based Communication Architectures; 2.1. Terminology; 2.2. Characteristics of Bus-Based Communication Architectures; 2.3. Data Transfer Modes; 2.4. Bus Topology Types
2.5. Physical Implementation of Bus Wires2.6. Discussion: Buses in the DSM Era; 2.7. Summary; CHAPTER 3 On-Chip Communication Architecture Standards; 3.1. Standard On-Chip Bus-Based Communication Architectures; 3.2. Socket-Based On-Chip Bus Interface Standards; 3.3. Discussion: Off-Chip Bus Architecture Standards; 3.4. Summary; CHAPTER 4 Models for Performance Exploration; 4.1. Static Performance Estimation Models; 4.2. Dynamic (Simulation-Based) Performance Estimation Models; 4.3. Hybrid Communication Architecture Performance Estimation Approaches; 4.4. Summary
CHAPTER 5 Models for Power and Thermal Estimation5.1. Bus Wire Power Models; 5.2. Comprehensive Bus Architecture Power Models; 5.3. Bus Wire Thermal Models; 5.4. Discussion: PVT Variation-Aware Power Estimation; 5.5. Summary; CHAPTER 6 Synthesis of On-Chip Communication Architectures; 6.1. Bus Topology Synthesis; 6.2. Bus Protocol Parameter Synthesis; 6.3. Bus Topology and Protocol Parameter Synthesis; 6.4. Physical Implementation Aware Synthesis; 6.5. Memory-Communication Architecture Co-synthesis; 6.6. Discussion: Physical and Circuit Level Design of On-Chip Communication Architectures
6.7. SummaryCHAPTER 7 Encoding Techniques for On-Chip Communication Architectures; 7.1. Techniques for Power Reduction; 7.2. Techniques for Reducing Capacitive Crosstalk Delay; 7.3. Techniques for Reducing Power and Capacitive Crosstalk Effects; 7.4. Techniques for Reducing Inductive Crosstalk Effects; 7.5. Techniques for Fault Tolerance and Reliability; 7.6. Summary; CHAPTER 8 Custom Bus-Based On-Chip Communication Architecture Design; 8.1. Split Bus Architectures; 8.2. Serial Bus Architectures; 8.3. CDMA-Based Bus Architectures; 8.4. Asynchronous Bus Architectures
8.5. Dynamically Reconfigurable Bus Architectures8.6. Summary; CHAPTER 9 On-Chip Communication Architecture Refinement and Interface Synthesis; 9.1. On-Chip Communication Architecture Refinement; 9.2. Interface Synthesis; 9.3. Discussion: Interface Synthesis; 9.4. Summary; CHAPTER 10 Verification and Security Issues in On-Chip Communication Architecture Design; 10.1. Verification of On-Chip Communication Protocols; 10.2. Compliance Verification for IP Block Integration; 10.3. Basic Concepts of SoC Security; 10.4. Security Support in Standard Bus Protocols
10.5. Communication Architecture Enhancements for Improving SoC Security
Over the past decade, system-on-chip (SoC) designs have evolved to address the ever increasing complexity of applications, fueled by the era of digital convergence. Improvements in process technology have effectively shrunk board-level components so they can be integrated on a single chip. New on-chip communication architectures have been designed to support all inter-component communication in a SoC design. These communication architecture fabrics have a critical impact on the power consumption, performance, cost and design cycle time of modern SoC designs. As application complexity strains
Description based upon print version of record.