Title page for ETD etd-03062002-100652 ( Browse

Type of Document

Dissertation

Author

Ahn, Jiyong

URN

etd-03062002-100652

Title

A CUSTOM ARCHITECTURE FOR DIGITAL LOGIC SIMULATION

Degree

Doctor of Philosophy

Program

Electrical Engineering

School

School of Engineering

Advisory Committee

Advisor Name	Title
Raymond R. Hoare	Committee Chair
James T. Cain	Committee Member
Marlin H. Mickle	Committee Member
Mary E. Besterfield-Sacre	Committee Member
Ronald G. Hoelzeman	Committee Member

Keywords

Hardware Logic Simulator
Discrete Event Simulation
Behavioral Modeling

Date of Defense

2002-01-30

Availability

restricted

Abstract

As VLSI technology advances, designers can pack larger circuits into a single chip. According to the International Technology Roadmap for Semiconductors, in the year 2005, VLSI circuit technology will produce chips with 200 million transistors in total, 40 million logic gates, 2 to 3.5 GHz clock rates, and 160 watts of power-consumption. Recently, Intel announced that they will produce a billion-transistor processor before 2010. However, current design methodologies can only handle tens of millions of transistors in a single design.
In this thesis, we focus on the problem of simulating large digital devices at the gate level. While many software solutions to gate-level simulation exist, their performance is limited by the underlying general-purpose workstation architecture. This research defines an architecture that is specifically designed for gate-level logic simulation that is at least an order of magnitude faster than software running on a workstation.
We present a custom processor and memory architecture design that can simulate a gate level design orders of magnitude faster than the software simulation, while maintaining 4-levels of signal strength. New primitives are presented and shown to significantly reduce the complexity of simulation. Unlike most simulators, which only use zero or unit time delay models, this research provides a mechanism to handle more complex full-timing delay model at pico-second accuracy. Experimental results and a working prototype will also be presented.

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