177 research outputs found
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
Analyse et caractérisation des couplages substrat et de la connectique dans les circuits 3D : Vers des modèles compacts
The 3D integration is the most promising technological solution to track the level of integration dictated by Moore's Law (see more than Moore, Moore versus more). It leads to important research for a dozen years. It can superimpose different circuits and components in one box. Its main advantage is to allow a combination of heterogeneous and highly specialized technologies for the establishment of a complete system, while maintaining a high level of performance with very short connections between the different circuits. The objective of this work is to provide consistent modeling via crossing, and / or contacts in the substrate, with various degrees of finesse / precision to allow the high-level designer to manage and especially to optimize the partitioning between the different strata. This modelization involves the development of multiple views at different levels of abstraction: the physical model to "high level" model. This would allow to address various issues faced in the design process: - The physical model using an electromagnetic simulation based on 2D or 3D ( finite element solver ) is used to optimize the via (materials, dimensions etc..) It determines the electrical performance of the via, including high frequency. Electromagnetic simulations also quantify the coupling between adjacent via. - The analytical compact of via their coupling model, based on a description of transmission line or Green cores is used for the simulations at the block level and Spice type simulations. Analytical models are often validated against measurements and / or physical models.L’intégration 3D est la solution technologique la plus prometteuse pour suivre le niveau d’intégration dictée par la loi de Moore (cf. more than Moore, versus more Moore). Elle entraine des travaux de recherche importants depuis une douzaine d’années. Elle permet de superposer différents circuits et composants dans un seul boitier. Son principal avantage est de permettre une association de technologies hétérogènes et très spécialisées pour la constitution d’un système complet, tout en préservant un très haut niveau de performance grâce à des connexions très courtes entre ces différents circuits. L’objectif de ce travail est de fournir des modélisations cohérentes de via traversant, ou/et de contacts dans le substrat, avec plusieurs degrés de finesse/précision, pour permettre au concepteur de haut niveau de gérer et surtout d’optimiser le partitionnement entre les différentes strates. Cette modélisation passe par le développement de plusieurs vues à différents niveaux d’abstraction: du modèle physique au modèle « haut niveau ». Elle devait permettre de répondre à différentes questions rencontrées dans le processus de conception :- le modèle physique de via basé sur une simulation électromagnétique 2D ou 3D (solveur « éléments finis ») est utilisé pour optimiser l’architecture du via (matériaux, dimensions etc.) Il permet de déterminer les performances électriques des via, notamment en haute fréquence. Les simulations électromagnétiques permettent également de quantifier le couplage entre via adjacents. - le modèle compact analytique de via et de leur couplage, basé sur une description de type ligne de transmission ou noyaux de Green, est utilisé pour les simulations au niveau bloc, ainsi que des simulations de type Spice. Les modèles analytiques sont souvent validés par rapport à des mesures et/ou des modèles physiques
Skin-Effect Loss Models for Time- and Frequency-Domain PEEC Solver
published_or_final_versio
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
Signaling in 3-D integrated circuits, benefits and challenges
Three-dimensional (3-D) or vertical integration is a design and packaging paradigm that can mitigate many of the increasing challenges related to the design of modern integrated systems. 3-D circuits have recently been at the spotlight, since these circuits provide a potent approach to enhance the performance and integrate diverse functions within amulti-plane stack. Clock networks consume a great portion of the power dissipated in a circuit. Therefore, designing a low-power clock network in synchronous circuits is an important task. This requirement is stricter for 3-D circuits due to the increased power densities. Synchronization issues can be more challenging for 3-D circuits since a clock path can spread across several planes with different physical and electrical characteristics. Consequently, designing low power clock networks for 3-D circuits is an important issue. Resonant clock networks are considered efficient low-power alternatives to conventional clock distribution schemes. These networks utilize additional inductive circuits to reduce power while delivering a full swing clock signal to the sink nodes. In this research, a design method to apply resonant clocking to synthesized clock trees is proposed. Manufacturing processes for 3-D circuits include some additional steps as compared to standard CMOS processes which makes 3-D circuits more susceptible to manufacturing defects and lowers the overall yield of the bonded 3-D stack. Testing is another complicated task for 3-D ICs, where pre-bond test is a prerequisite. Pre-bond testability, in turn, presents new challenges to 3-D clock network design primarily due to the incomplete clock distribution networks prior to the bonding of the planes. A design methodology of resonant 3-D clock networks that support wireless pre-bond testing is introduced. To efficiently address this issue, inductive links are exploited to wirelessly transmit the clock signal to the disjoint resonant clock networks. The inductors comprising the LC tanks are used as the receiver circuit for the links, essentially eliminating the need for additional circuits and/or interconnect resources during pre-bond test. Recent FPGAs are quite complex circuits which provide reconfigurablity at the cost of lower performance and higher power consumption as compared to ASIC circuits. Exploiting a large number of programmable switches, routing structures are mainly responsible for performance degradation in FPAGs. Employing 3-D technology can providemore efficient switches which drastically improve the performance and reduce the power consumption of the FPGA. RRAM switches are one of the most promising candidates to improve the FPGA routing architecture thanks to their low on-resistance and non-volatility. Along with the configurable switches, buffers are the other important element of the FPGAs routing structure. Different characteristics of RRAM switches change the properties of signal paths in RRAM-based FPGAs. The on resistance of RRAMswitches is considerably lower than CMOS pass gate switches which results in lower RC delay for RRAM-based routing paths. This different nature in critical path and signal delay in turn affect the need for intermediate buffers. Thus the buffer allocation should be reconsidered. In the last part of this research, the effect of intermediate buffers on signal propagation delay is studied and a modified buffer allocation scheme for RRAM-based FPGA routing path is proposed
Advanced modelling and design considerations for interconnects in ultra- low power digital system
PhD ThesisAs Very Large Scale Integration (VLSI) is progressing in very Deep
submicron (DSM) regime without decreasing chip area, the importance
of global interconnects increases but at the cost of
performance and power consumption for advanced System-on-
Chip (SoC)s. However, the growing complexity of interconnects
behaviour presents a challenge for their adequate modelling,
whereby conventional circuit theoretic approaches cannot provide
sufficient accuracy. During the last decades, fractional differential
calculus has been successfully applied to modelling
certain classes of dynamical systems while keeping complexity
of the models under acceptable bounds. For example, fractional
calculus can help capturing inherent physical effects in electrical
networks in a compact form, without following conventional
assumptions about linearization of non-linear interconnect components.
This thesis tackles the problem of interconnect modelling in
its generality to simulate a wide range of interconnection configurations,
its capacity to emulate irregular circuit elements
and its simplicity in the form of responsible approximation. This
includes modelling and analysing interconnections considering
their irregular components to add more flexibility and freedom
for design. The aim is to achieve the simplest adaptable model
with the highest possible accuracy. Thus, the proposed model
can be used for fast computer simulation of interconnection
behaviour. In addition, this thesis proposes a low power circuit
for driving a global interconnect at voltages close to the noise
level. As a result, the proposed circuit demonstrates a promising
solution to address the energy and performance issues related
to scaling effects on interconnects along with soft errors that
can be caused by neutron particles.
The major contributions of this thesis are twofold. Firstly, in
order to address Ultra-Low Power (ULP) design limitations, a novel
driver scheme has been configured. This scheme uses a bootstrap
circuitry which boosts the driver’s ability to drive a long
interconnect with an important feedback feature in it. Hence,
this approach achieves two objectives: improving performance
and mitigating power consumption. Those achievements are essential
in designing ULP circuits along with occupying a smaller
footprint and being immune to noise, observed in this design as
well. These have been verified by comparing the proposed design
to the previous and traditional circuits using a simulation tool.
Additionally, the boosting based approach has been shown beneficial
in mitigating the effects of single event upset (SEU)s, which
are known to affect DSM circuits working under low voltages.
Secondly, the CMOS circuit driving a distributed RLC load has
been brought in its analysis into the fractional order domain. This
model will make the on-chip interconnect structure easy to adjust
by including the effect of fractional orders on the interconnect
timing, which has not been considered before. A second-order
model for the transfer functions of the proposed general structure
is derived, keeping the complexity associated with second-order
models for this class of circuits at a minimum. The approach
here attaches an important trait of robustness to the circuit
design procedure; namely, by simply adjusting the fractional
order we can avoid modifying the circuit components. This can
also be used to optimise the estimation of the system’s delay
for a broad range of frequencies, particularly at the beginning
of the design flow, when computational speed is of paramount
importance.Iraqi Ministry of Higher Education
and Scientific Researc
Miniaturized Transistors, Volume II
In this book, we aim to address the ever-advancing progress in microelectronic device scaling. Complementary Metal-Oxide-Semiconductor (CMOS) devices continue to endure miniaturization, irrespective of the seeming physical limitations, helped by advancing fabrication techniques. We observe that miniaturization does not always refer to the latest technology node for digital transistors. Rather, by applying novel materials and device geometries, a significant reduction in the size of microelectronic devices for a broad set of applications can be achieved. The achievements made in the scaling of devices for applications beyond digital logic (e.g., high power, optoelectronics, and sensors) are taking the forefront in microelectronic miniaturization. Furthermore, all these achievements are assisted by improvements in the simulation and modeling of the involved materials and device structures. In particular, process and device technology computer-aided design (TCAD) has become indispensable in the design cycle of novel devices and technologies. It is our sincere hope that the results provided in this Special Issue prove useful to scientists and engineers who find themselves at the forefront of this rapidly evolving and broadening field. Now, more than ever, it is essential to look for solutions to find the next disrupting technologies which will allow for transistor miniaturization well beyond silicon’s physical limits and the current state-of-the-art. This requires a broad attack, including studies of novel and innovative designs as well as emerging materials which are becoming more application-specific than ever before
Cutting Edge Nanotechnology
The main purpose of this book is to describe important issues in various types of devices ranging from conventional transistors (opening chapters of the book) to molecular electronic devices whose fabrication and operation is discussed in the last few chapters of the book. As such, this book can serve as a guide for identifications of important areas of research in micro, nano and molecular electronics. We deeply acknowledge valuable contributions that each of the authors made in writing these excellent chapters
Modelling and Test Generation for Crosstalk Faults in DSM Chips
In the era of deep submicron technology (DSM), many System-on-Chip (SoC) applications require the components to be operating at high clock speeds. With the shrinking feature size and ever increasing clock frequencies, the DSM technology has led to a well-known problem of Signal Integrity (SI) more especially in the connecting layout design. The increasing aspect ratios of metal wires and also the ratio of coupling capacitance over substrate capacitance result in electrical coupling of interconnects which leads to crosstalk problems. In this thesis, first the work carried out to model the crosstalk behaviour between aggressor and victim by considering the distributed RLGC parameters of interconnect and the coupling capacitance and mutual conductance between the two nets is presented. The proposed model also considers the RC linear models of the CMOS drivers and receivers. The behaviour of crosstalk in case of under etching problem has been studied and modelled by distributing and approximating the defect behaviour throughout the nets. Next, the proposed model has also been extended to model the behaviour of crosstalk in case of one victim is influenced by several aggressors by considering all aggressors have similar effect (worst-case) on victim. In all the above cases simulation experiments were also carried out and compared with well-known circuit simulation tool PSPICE. It has been proved that the generated crosstalk model is faster and the results generated are within 10% of error margin compared to latter simulation tool. Because of the accuracy and speed of the proposed model, the model is very useful for both SoC designers and test engineers to analyse the crosstalk behaviour. Each manufactured device needs to be tested thoroughly to ensure the functionality before its delivery. The test pattern generation for crosstalk faults is also necessary to test the corresponding crosstalk faults. In this thesis, the well-known PODEM algorithm for stuck-at faults is extended to generate the test patterns for crosstalk faults between single aggressor and single victim. To apply modified PODEM for crosstalk faults, the transition behaviour has been divided into two logic parts as before transition and after transition. After finding individually required test patterns for before transition and after transition, the generated logic vectors are appended to create transition test patterns for crosstalk faults. The developed algorithm is also applied for a few ISCAS 85 benchmark circuits and the fault coverage is found excellent in most circuits. With the incorporation of proposed algorithm into the ATPG tools, the efficiency of testing will be improved by generating the test patterns for crosstalk faults besides for the conventional stuck-at faults. In generating test patterns for crosstalk faults on single victim due to multiple aggressors, the modified PODEM algorithm is found to be more time consuming. The search capability of Genetic Algorithms in finding the required combination of several input factors for any optimized problem fascinated to apply GA for generating test patterns as generating the test pattern is also similar to finding the required vector out of several input transitions. Initially the GA is applied for generating test patterns for stuck-at faults and compared the results with PODEM algorithm. As the fault coverage is almost similar to the deterministic algorithm PODEM, the GA developed for stuck-at faults is extended to find test patterns for crosstalk faults between single aggressor and single victim. The elitist GA is also applied for a few ISCAS 85 benchmark circuits. Later the algorithm is extended to generate test patterns for worst-case crosstalk faults. It has been proved that elitist GA developed in this thesis is also very useful in generating test patterns for crosstalk faults especially for multiple aggressor and single victim crosstalk faults
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