SOC design methodologies : IFIP TC10/WG10.5 Eleventh International Conference on Very Large Scale Integration of Systems-on-Chip (VLSI-SOC'01), December 3-5, 2001, Montpellier, France

著者

    • IFIP TC10/WG10.5 International Conference on Very Large Scale Integration of Systems-on-Chip
    • Robert, Michel

書誌事項

SOC design methodologies : IFIP TC10/WG10.5 Eleventh International Conference on Very Large Scale Integration of Systems-on-Chip (VLSI-SOC'01), December 3-5, 2001, Montpellier, France

edited by Michel Robert ... [et al.]

(The International Federation for Information Processing, 90)

Kluwer Academic Publishers, c2002

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注記

Includes bibliographical references and indexes

内容説明・目次

内容説明

The 11 th IFIP International Conference on Very Large Scale Integration, in Montpellier, France, December 3-5,2001, was a great success. The main focus was about IP Cores, Circuits and System Designs & Applications as well as SOC Design Methods and CAD. This book contains the best papers (39 among 70) that have been presented during the conference. Those papers deal with all aspects of importance for the design of the current and future integrated systems. System on Chip (SOC) design is today a big challenge for designers, as a SOC may contain very different blocks, such as microcontrollers, DSPs, memories including embedded DRAM, analog, FPGA, RF front-ends for wireless communications and integrated sensors. The complete design of such chips, in very deep submicron technologies down to 0.13 mm, with several hundreds of millions of transistors, supplied at less than 1 Volt, is a very challenging task if design, verification, debug and industrial test are considered. The microelectronic revolution is fascinating; 55 years ago, in late 1947, the transistor was invented, and everybody knows that it was by William Shockley, John Bardeen and Walter H. Brattein, Bell Telephone Laboratories, which received the Nobel Prize in Physics in 1956. Probably, everybody thinks that it was recognized immediately as a major invention.

目次

  • Preface. Conference Committees. Architecture for Signal & Image Processing. Two ASIC for Low and Middle Levels of Real Time Image Processing
  • P. Lamaty, et al. 64 x 64 Pixels General Purpose Digital Vision Chip
  • T. Komuro, M. Ishikawa. A Vision System on Chip for Industrial Control
  • E. Senn, E. Martin.Fast Recursive Implementation of the Gaussian Filter
  • D. Demigny, L. Kessal, J. Pons. Dynamically Re-configurable Architectures. A Dynamically Reconfigurable Architecture for Low-Power Multimedia Terminals
  • R. David, et al. Dynamically Reconfigurable Architectures for Digital Signal Processing Application
  • G. Sassatelli, et al. Reconfigurable Architecture Using High Speed FPGA
  • L. Kessal, et al. CAD Tools. Design Technology for Systems-on-Chip
  • R. Camposano, D. MacMillen. Distributed Collaborative Design over Cave2 Framework
  • L.S. Indrusiak, et al. High Performance Java Hardware Engine and Software Kernel for Embedded Systems
  • M.H. Miki, et al. An Object-Oriented Methodology for Modeling the Precise Behavior of Processor Architectures
  • J.C. Otero, F.R. Wagner. Interconnect Capacitance Modelling in a VDSM CMOS Technology
  • D. Bernard, et al. IP Design & Reuse. Abstract Communication Model and Automatic Interface generation for IP integration in Hardware/Software Co-design
  • C. Araujo, E. Barros. An Evolutionary Approach for Pareto-optimal Configurations in SOC Platforms
  • G. Ascia, et al. Design of a Branch-Based Carry-Select Adder IP Portable in 0.25 mum Bulk and Silicon-On-Insulator CMOS Technologies
  • A. Neve, D. Flandre. High Level Design Methodologies. A Standardized Co-simulation Backbone
  • B.A. De Mello, F.R. Wagner. Automatic Code-Transformation and Architecture Refinementfor Application-Specific Multiprocessor SoCs with Shared Memory
  • S. Meftali, et al. Power Issues. Modeling Power Dynamics for an Embedded DSP Processor Core. An Empirical Model
  • C.H. Gebotys, R. Muresan. Power Consumption Model for the DSP OAK Processor
  • P. Guitton-Ouhamou, C. Belleudy. Design for Specific Constraints. Integration of Robustness in the Design of a Cell
  • J.M. Dutertre, et al. Impact of Technology Spreading on MEMS design Robustness
  • V. Beroulle, et al. Architectures. A New Efficient VLSI Architecture for Full Search Block Matching Motion Estimation
  • N. Roma, L. Sousa. Design Considerations of a Low-Complexity, Low-Power Integer Turbo Decoder
  • S.M. Pisuk, P.H. Wu. Low Power, Low Voltage. Low-Voltage Embedded-RAM Technology: Present and Future
  • K. Itoh, H. Mizuno. Low-Voltage 0,25 m CMOS Improved Power Adaptive Issue Queue for Embedded Microprocessors
  • B. Curran, et al. Gate Sizing for Low Power Design
  • P. Maurine, et al. Timing Issues. Modeling and Design of Asynchronous Priority Arbiters for On-Chip Communication Systems
  • J-B. Rigaud, et al. Feasible Delay Bound Definition
  • N. Azemard, et al. Advance in Mixed Signal. CMOS Mixed-signal Circuits Design on a Digital Array Using Minimum Transistors
  • J.H. Choi, S. Bampi. A VHDL-AMS Case Study: The Incremental Design of an Efficient 3rd Generation MOS Model of a Deep Sub Micron Transistor
  • C. Lallement, et al. Verification & Validation. Speeding Up Verification of RTL Designs by Computing One-to-one Abstractions with Reduced Signal Widths
  • P. Johannsen, R. Drechsler. Functional Test Generation using Constraint Logic Programming
  • Z. Zeng, et al. Test.

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