Solid State Circuits Technologies

The evolution of solid-state circuit technology has a long history within a relatively short period of time. This technology has lead to the modern information society that connects us and tools, a large market, and many types of products and applications. The solid-state circuit technology continuously evolves via breakthroughs and improvements every year. This book is devoted to review and present novel approaches for some of the main issues involved in this exciting and vigorous technology. The book is composed of 22 chapters, written by authors coming from 30 different institutions located in 12 different countries throughout the Americas, Asia and Europe. Thus, reflecting the wide international contribution to the book. The broad range of subjects presented in the book offers a general overview of the main issues in modern solid-state circuit technology. Furthermore, the book offers an in depth analysis on specific subjects for specialists. We believe the book is of great scientific and educational value for many readers. I am profoundly indebted to the support provided by all of those involved in the work. First and foremost I would like to acknowledge and thank the authors who worked hard and generously agreed to share their results and knowledge. Second I would like to express my gratitude to the Intech team that invited me to edit the book and give me their full support and a fruitful experience while working together to combine this book

Improvement of a Propagation Delay Model for CMOS Digital Logic Circuits

Propagation delay models, for CMOS Digital Circuits, provide an initial design solution for Integrated Circuits. Resources, both monetary and manpower, constrain the design process, leading to the need for a more accurate entry point further along in the design cycle. By verifying an existing propagation delay method, and its resulting delay model, calibration for any given process technology can be achieved. Literature reviews and detailed analysis of each step in the model development allow for greater understanding of each contributing parameter, and ultimately, adjustments to the model calibration result in a more accurate analytical model. An existing model was verified and improved upon using TSMC 0.18um and IBM 0.13um SPICE decks, and the resulting improvements can be used to further assist individuals needing a method and model for deriving an initial circuit design solution for integrated circuits

Carbon Nanotube Interconnect Modeling for Very Large Scale Integrated Circuits

In this research, we have studied and analyzed the physical and electrical properties of carbon nanotubes. Based on the reported models for current transport behavior in non-ballistic CNT-FETs, we have built a dynamic model for non-ballistic CNT-FETs. We have also extended the surface potential model of a non-ballistic CNT-FET to a ballistic CNT-FET and developed a current transport model for ballistic CNT-FETs. We have studied the current transport in metallic carbon nanotubes. By considering the electron-electron interactions, we have modified two-dimensional fluid model for electron transport to build a semi-classical one-dimensional fluid model to describe the electron transport in carbon nanotubes, which is regarded as one-dimensional system. Besides its accuracy compared with two-dimensional fluid model and Lüttinger liquid theory, one-dimensional fluid model is simple in mathematical modeling and easier to extend for electronic transport modeling of multi-walled carbon nanotubes and single-walled carbon nanotube bundles as interconnections. Based on our reported one-dimensional fluid model, we have calculated the parameters of the transmission line model for the interconnection wires made of single-walled carbon nanotube, multi-walled carbon nanotube and single-walled carbon nanotube bundle. The parameters calculated from these models show close agreements with experiments and other proposed models. We have also implemented these models to study carbon nanotube for on-chip wire inductors and it application in design of LC voltage-controlled oscillators. By using these CNT-FET models and CNT interconnects models, we have studied the behavior of CNT based integrated circuits, such as the inverter, ring oscillator, energy recovery logic; and faults in CNT based circuits

PLAWE: A piecewise linear circuit simulator using asymptotic waveform evaluation

Ankara : Department of Electrical and Electronics Engineering and the Institute of Engineering and Science of Bilkent University, 1994.Thesis (Ph.D.) -- Bilkent University, 1994.Includes bibliographical references leaves 73-81.A new circuit simulation program, PLAWE, is developed for the transient analysis of VLSI circuits. PLAWE uses Asymptotic Waveform Evaluation (AWE) technique, which is a new method to analyze linear(ized) circuits, and Piecewise Linear (PWL) approach for DC representation of nonlinear elements. AWE employs a form of Pade approximation rather than numerical integration techniques to approximate the response of linear(ized) circuits in either the time or the frequency domain. AWE is typically two or three orders of magnitude faster than traditional simulators in analyzing large linear circuits. However, it can handle only linear(ized) circuits, while the transient analysis problem is generally nonlinear due to the presence of nonlinear devices such as diodes, transistors, etc.. We have applied the AWE technique to the transient simulation of nonlinear circuits by using static PWL models for nonlinear elements. But, finding a good static PWL model which fits well to the actual i — v characteristics of a nonlinear device is not an easy task and in addition, static PWL modelling results in low accuracy. Therefore, we have developed a dynamic PWL modeling technique which uses SPICE models for nonlinear elements to enhance the accuracy of the simulation while preserving the efficiency gain obtained with AWE. Hence, there is no modelling problem and we can adjust the accuracy level by varying some parameters. If the required level of accuracy is increased, more simulation time is needed. Practical examples are given to illustrate the significant improvement in accuracy. For circuits containing especially weakly nonlinear devices, this method is typically at least one order of magnitude faster than HSPICE. A fast and convergent iteration method for piecewise-linear analysis of nonlinear resistive circuits is presented. Most of the existing algorithms are applicable only to a limited class of circuits. In general, they are either not convergent or too slow for large circuits. The new algorithm presented in this thesis is much more efficient than the existing ones and can be applied to any piecewise-linear circuit. It is based on the piecewise-linear version of the Newton-Raphson algorithm. As opposed to the NewtonRaphson method, the new algorithm is globally convergent from an arbitrary starting point. It is simple to understand and it can be easily programmed. Some numerical examples are given in order to demonstrate the effectiveness of the presented algorithm in terms of the amount of computation.Topçu, SatılmışPh.D

Modeling and simulation of VLSI interconnections with moments

Also issued as Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 1989.Includes bibliographical references.Supported in part by the Joint Services Electronics Program. DAAL03-86-K-0002Steven Paul McCormick

Modeling and simulation of full-component integrated circuits in transient ESD events

This thesis presents a methodology to model and simulate transient electrostatic discharge (ESD) responses of integrated circuits (IC). To obtain valid simulation results, the IC component must be represented by a circuit netlist composed of device models that are valid under the ESD conditions. Models of the nonlinear devices that make up the ESD protection network of the IC must have transient I-V responses calibrated against measurements that emulate ESD events. Interconnects, power distribution networks, and the silicon substrate on the chip die as well as on the IC package must be faithfully constructed to emulate the fact that ESD current flows in a distributed manner across the entire IC component. The resultant equivalent circuit model therefore contains a huge number of nodes and devices, and the simulation runtime may be prohibitively long. Techniques must be devised to make the numerical simulation process more efficient without sacrifice of accuracy. These techniques include reasonable abstraction of the distributed full-component circuit netlist, dynamic piecewise-linear device models, and customized efficient transient circuit simulator. With the simulation streamlining techniques set up properly, comprehensive and predictive transient ESD simulation can be carried out efficiently to investigate the weakest link in the target IC, and the design can be fine-tuned to achieve optimal performance in both functionality and ESD reliability

System formulation for parallel circuit analysis

Advances in communication systems and VLSI circuits increase the performance requirements and complexity of circuits. During the design process, there is a need to perform computationally demanding numerical simulations to verify the functionality of circuits under design. One way to reduce computing time is to use parallel processing. This thesis discusses different techniques for parallel circuit analysis with emphasis in the formulation of equations for a circuit decomposed in subcircuit blocks. For manually decomposed circuit, this thesis introduces two approaches to formulate circuit equations. The two formulations allow to independently analyze each subcircuit block by periodically exchanging information with a master process. A node-tearing process is used to divide the system Jacobian in blocks. The first formulation is base on the nodal voltages and currents at the interface nodes. The second formulation is presented in this thesis for the first time and uses scattering waves to exchange information between subcircuits. The two formulations are described in detail and implemented in a general circuit simulator. Simulation results comparing the performance of the proposed formulations for different circuits are presented. These results indicate that there is no advantage in using waves to exchange information between subcircuits. Moreover, at least with the current software implementation the formulation based on nodal variables is significantly more efficient. This thesis concludes with a road map for future work