Overview

The move to higher levels of integration has increased the fraction of application-specific integrated circuit (ASIC) designs containing both analog and digital circuits. While the die area for the analog portion of these chips is modest, the design time is often significant. This has motivated the development of automated analog physical design tools for cell-level place-and-route and system-level signal-integrity-routing. To date, there is no tool that has specifically addressed the critical design task of synthesizing the power distribution for the analog portion of an analog or mixed-signal ASIC. This text describes algorithms for analog power distribution synthesis and demonstrates their effectivenes. Existing digital power bus synthesis algorithms have failed to address critical concerns for analog circuitry, thus yielding unacceptable results. These tools synthesize only the bus component of power distribution networks and only consider simplified DC aspects of macros and buses. This work addresses power distribution synthesis for mixed-signal integrated circuits. Several key challenges in power distribution design are identified and automated methods to overcome them are described. The text presents a formulation for the analog power distribution synthesis problem which synthesizes both the power busses power I/O cell assignment by evaluating DC, AC, and transient interaction between the macros, busses, chip substrate, and package. Furthermore, algorithms are introduced which simultaneously optimize power I/O cell assignment, macro cell substrate coupling, power bus topology selection and power bus sizing. The book should be of interest to CAD designers and researchers specializing in physical design, modelling and circuit synthesis.

Full Product Details

Author:   Balsha R. Stanisic ,  Rob A. Rutenbar ,  L. Richard Carley
Publisher:   Springer
Imprint:   Springer
Edition:   1996 ed.
Dimensions:   Width: 15.50cm , Height: 1.40cm , Length: 23.50cm
Weight:   1.120kg
ISBN:  

9780792397342

ISBN 10:   0792397347
Pages:   208
Publication Date:   31 May 1996
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Hardback
Publisher's Status:   Active
Availability:   In Print  
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Table of Contents

1 Introduction.- 1.1 Focus.- 1.2 Motivation.- 1.3 Research Overview.- 1.4 Preview of Results.- 1.5 Book Organization.- 2 Power Distribution Noise and Physical Design Methods.- 2.1 Analog Design Problem Characteristics.- 2.2 Design Style Concerns.- 2.3 Analog Power Distribution Design Concerns.- 2.4 Previous Research in Power Distribution Synthesis.- 2.5 Critical Analysis.- 2.6 Concluding Remarks.- 3 Physical Design and Optimization.- 3.1 New Optimization-based Strategy.- 3.2 Design Style Selection.- 3.3 Power Bus Topology Selection and Sizing.- 3.4 Power I/O Cell Assignment.- 3.5 Simultaneous Power Bus and I/O Cell Optimization.- 3.6 Review of Simulated Annealing.- 3.7 Simulated Annealing Formulation.- 3.8 Concluding Remarks.- 4 DC, AC, and Transient Electrical Models and Analysis.- 4.1 Electrical Formulation Objectives.- 4.2 Mapping Power Bus and I/O Cell Geometry to Electricity.- 4.3 Modeling Macrocells.- 4.4 Modeling Interconnect.- 4.5 Modeling Chip Substrate.- 4.6 DC Behavior Evaluation Methods.- 4.7 AC and Transient Behavior Evaluation Methods.- 4.8 Review of Asymptotic Waveform Evaluation (AWE).- 4.9 AWE-based Single Input Switching Behavior.- 4.10 AWE-based Simultaneous Switching Behavior.- 4.11 Concluding Remarks.- 5 Experimental Results.- 5.1 Experimental Plan.- 5.2 Example Nonconvex.- 5.3 Example Analog 1.- 5.4 Example Mixed-Signal1.- 5.5 Example Mixed-Signal2.- 5.6 Example Mixed-Signal3.- 5.7 Example Config 1.- 5.8 Example Stanford.- 5.9 Example Mixed-Signal4.- 5.10 Example CMU.- 5.11 SQP and Annealing, Revisited.- 5.12 Concluding Remarks.- 6 Conclusions.- 6.1 Summary.- 6.2 Contributions.- 6.3 Future Directions.- A Symbolic Convolution of Special Waveforms.- A.1 Specialized Waveforms.- A.1.1 Trap.- A.1.2. Sinsq.- A.2 Fundamental Waveforms.- A.2.1 Step.- A.2.2Ramp.- A.2.3 Cosine.- B Circuit Element Approximation of Chip Substrate.- B.1 Underlying Treatment.- B.2 General Bulk Field Derivation.- B.3 Box Integration.

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