Extending systems-on-chip to the third dimension : performance, cost and technological tradeoffs.

Because of the today's market demand for high-performance, high-density portable hand-held applications, electronic system design technology has shifted the focus from 2-D planar SoC single-chip solutions to different alternative options as tiled silicon and single-level embedded modules as well as 3-D integration. Among the various choices, finding an optimal solution for system implementation dealt usually with cost, performance and other technological trade-off analysis at the system conceptual level. It has been identified that the decisions made within the first 20% of the total design cycle time will ultimately result up to 80% of the final product cost. In this paper, we discuss appropriate and realistic metric for performance and cost trade-off analysis both at system conceptual level (up-front in the design phase) and at implementation phase for verification in the three-dimensional integration. In order to validate the methodology, two ubiquitous electronic systems are analyzed under various implementation schemes and discuss the pros and cons of each of them

Real Time Signal Processing Using Systolic Arrays

This thesis discusses and presents the design of systolic arrays used in modern real time signal processing. A methodology to map a given algorithm into a systolized VLSI implementation is described. The architectural alternatives for a given signal processing algorithm are discussed and investigated at a function level using a simulation package that has been developed using the “C” programming language. The similarities and differences between wavefront array processors and systolic array processors are presented

Modelling and analysis of crosstalk in scaled CMOS interconnects

The development of a general coupled RLC interconnect model for simulating scaled bus structures m VLSI is presented. Several different methods for extracting submicron resistance, inductance and capacitance parameters are documented. Realistic scaling dimensions for deep submicron design rules are derived and used within the model. Deep submicron HSPICE device models are derived through the use of constant-voltage scaling theory on existing 0.75µm and 1.0µm models to create accurate interconnect bus drivers. This complete model is then used to analyse crosstalk noise and delay effects on multiple scaling levels to determine the dependence of crosstalk on scaling level. Using this data, layout techniques and processing methods are suggested to reduce crosstalk in system

Modeling and analysis of semiconductor manufacturing processes using petri nets

This thesis addresses the issues in modeling and analysis of multichip module (MCM) manufacturing processes using Petri nets. Building such graphical and mathematical models is a crucial step to understand MCM technologies and to enhance their application scope. In this thesis, the application of Petri nets is presented with top-down and bottom-up approaches. The theory of Petri nets is summarized with its basic notations and properties at first. After that, the capability of calculating and analyzing Petri nets with deterministic timing information is extended to meet the requirements of the MCM models. Then, using top-down refining and system decomposition, MCM models are built from an abstract point to concrete systems with timing information. In this process, reduction theory based on a multiple-input-single-output modules for deterministic Petri nets is applied to analyze the cycle time of Petri net models. Besides, this thesis is of significance in its use of the reduction theory which is derived for timed marked graphs - an important class of Petri nets

Critical design issues for gallium arsenide VLSI circuits.

The aim of this research was to design and evaluate various Gallium Arsenide circuit elements such as logic gates, adders and multipliers suitable for high speed VLSI circuits. The issues addressed are the logic gate design and optimisation, evaluation of various buffering schemes and the impact of the algorithm on adder and multiplier performance for digital signal processing applications. This has led to the development of a design approach to produce high speed and low power dissipation Gallium Arsenide VLSI circuits. This is achieved by : Evaluating the well established Direct Coupled Logic (DCFL) gates and proposing an alternative gate, namely the Source Follower DCFL (SDCFL), to improve the noise margin and speed. Suggesting various buffering schemes to maintain high speed in areas where the fanout loading is high (eg. clock drivers). Comparing various adder types in terms of delay-power and delay-area products to arrive at a suitable architecture for Gallium Arsenide implementation and to determine the influence of the algorithm and layout approach on circuit performance. To investigate this further, a multiplier was also designed to assess the performance at higher levels of integration. Applying a new layout approach, called the 'ring notation*, to the adder and multiplier circuits in order to improve their delay-area product. Finally, the critical factors influencing the performance of the circuits are reviewed and a number of suggestions are given to maintain reliable operation at high speed

VLSI Design

This book provides some recent advances in design nanometer VLSI chips. The selected topics try to present some open problems and challenges with important topics ranging from design tools, new post-silicon devices, GPU-based parallel computing, emerging 3D integration, and antenna design. The book consists of two parts, with chapters such as: VLSI design for multi-sensor smart systems on a chip, Three-dimensional integrated circuits design for thousand-core processors, Parallel symbolic analysis of large analog circuits on GPU platforms, Algorithms for CAD tools VLSI design, A multilevel memetic algorithm for large SAT-encoded problems, etc

An Electromigration and Thermal Model of Power Wires for a Priori High-Level Reliability Prediction

In this paper, a simple power-distribution electrothermal model including the interconnect self-heating is used together with a statistical model of average and rms currents of functional blocks and a high-level model of fanout distribution and interconnect wirelength. Following the 2001 SIA roadmap projections, we are able to predict a priori that the minimum width that satisfies the electromigration constraints does not scale like the minimum metal pitch in future technology nodes. As a consequence, the percentage of chip area covered by power lines is expected to increase at the expense of wiring resources unless proper countermeasures are taken. Some possible solutions are proposed in the paper

DESIGN METHODOLOGIES AND SOME ASPECTS OF VLSI AND ULSI

This is a review and considers first technical aspects and drawbacks for realizing very large scale and wafer scale integrated circuits. Among these are small geometry effects and interconnection delay. Some solutions are considered. Next, design methodologies for VLSI are discussed, considering the hierarchy of VLSI systems. Finally the influences for students education are remarked and a design system consisting of CAD tools for logic synthesis and simulation, network-and device simulation, automated layout generation and layout-verification are described