Circuit design for embedded memory in low-power integrated circuits

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2012.Cataloged from PDF version of thesis.Includes bibliographical references (p. 141-152).This thesis explores the challenges for integrating embedded static random access memory (SRAM) and non-volatile memory-based on ferroelectric capacitor technology-into lowpower integrated circuits. First considered is the impact of process variation in deep-submicron technologies on SRAM, which must exhibit higher density and performance at increased levels of integration with every new semiconductor generation. Techniques to speed up the statistical analysis of physical memory designs by a factor of 100 to 10,000 relative to the conventional Monte Carlo Method are developed. The proposed methods build upon the Importance Sampling simulation algorithm and efficiently explore the sample space of transistor parameter fluctuation. Process variation in SRAM at low-voltage is further investigated experimentally with a 512kb 8T SRAM test chip in 45nm SOI CMOS technology. For active operation, an AC coupled sense amplifier and regenerative global bitline scheme are designed to operate at the limit of on current and off current separation on a single-ended SRAM bitline. The SRAM operates from 1.2 V down to 0.57 V with access times from 400ps to 3.4ns. For standby power, a data retention voltage sensor predicts the mismatch-limited minimum supply voltage without corrupting the contents of the memory. The leakage power of SRAM forces the chip designer to seek non-volatile memory in applications such as portable electronics that retain significant quantities of data over long durations. In this scenario, the energy cost of accessing data must be minimized. This thesis presents a ferroelectric random access memory (FRAM) prototype that addresses the challenges of sensing diminishingly small charge under conditions favorable to low access energy with a time-to-digital sensing scheme. The 1 Mb IT1C FRAM fabricated in 130 nm CMOS operates from 1.5 V to 1.0 V with corresponding access energy from 19.2 pJ to 9.8 pJ per bit. Finally, the computational state of sequential elements interspersed in CMOS logic, also restricts the ability to power gate. To enable simple and fast turn-on, ferroelectric capacitors are integrated into the design of a standard cell register, whose non-volatile operation is made compatible with the digital design flow. A test-case circuit containing ferroelectric registers exhibits non-volatile operation and consumes less than 1.3 pJ per bit of state information and less than 10 clock cycles to save or restore with no minimum standby power requirement in-between active periods.by Masood Qazi.Ph.D

Integrated Circuits/Microchips

With the world marching inexorably towards the fourth industrial revolution (IR 4.0), one is now embracing lives with artificial intelligence (AI), the Internet of Things (IoTs), virtual reality (VR) and 5G technology. Wherever we are, whatever we are doing, there are electronic devices that we rely indispensably on. While some of these technologies, such as those fueled with smart, autonomous systems, are seemingly precocious; others have existed for quite a while. These devices range from simple home appliances, entertainment media to complex aeronautical instruments. Clearly, the daily lives of mankind today are interwoven seamlessly with electronics. Surprising as it may seem, the cornerstone that empowers these electronic devices is nothing more than a mere diminutive semiconductor cube block. More colloquially referred to as the Very-Large-Scale-Integration (VLSI) chip or an integrated circuit (IC) chip or simply a microchip, this semiconductor cube block, approximately the size of a grain of rice, is composed of millions to billions of transistors. The transistors are interconnected in such a way that allows electrical circuitries for certain applications to be realized. Some of these chips serve specific permanent applications and are known as Application Specific Integrated Circuits (ASICS); while, others are computing processors which could be programmed for diverse applications. The computer processor, together with its supporting hardware and user interfaces, is known as an embedded system.In this book, a variety of topics related to microchips are extensively illustrated. The topics encompass the physics of the microchip device, as well as its design methods and applications

Caractérisation, mécanismes et applications mémoire des transistors avancés sur SOI

Ce travail présente les principaux résultats obtenus avec une large gamme de dispositifs SOI avancés, candidats très prometteurs pour les futurs générations de transistors MOSFETs. Leurs propriétés électriques ont été analysées par des mesures systématiques, agrémentées par des modèles analytiques et/ou des simulations numériques. Nous avons également proposé une utilisation originale de dispositifs FinFETs fabriqués sur ONO enterré en fonctionnalisant le ONO à des fins d'application mémoire non volatile, volatile et unifiées. Après une introduction sur l'état de l'art des dispositifs avancés en technologie SOI, le deuxième chapitre a été consacré à la caractérisation détaillée des propriétés de dispositifs SOI planaires ultra- mince (épaisseur en dessous de 7 nm) et multi-grille. Nous avons montré l excellent contrôle électrostatique par la grille dans les transistors très courts ainsi que des effets intéressants de transport et de couplage. Une approche similaire a été utilisée pour étudier et comparer des dispositifs FinFETs à double grille et triple grille. Nous avons démontré que la configuration FinFET double grille améliore le couplage avec la grille arrière, phénomène important pour des applications à tension de seuil multiple. Nous avons proposé des modèles originaux expliquant l'effet de couplage 3D et le comportement de la mobilité dans des TFTs nanocristallin ZnO. Nos résultats ont souligné les similitudes et les différences entre les transistors SOI et à base de ZnO. Des mesures à basse température et de nouvelles méthodes d'extraction ont permis d'établir que la mobilité dans le ZnO et la qualité de l'interface ZnO/SiO2 sont remarquables. Cet état de fait ouvre des perspectives intéressantes pour l'utilisation de ce type de matériaux aux applications innovantes de l'électronique flexible. Dans le troisième chapitre, nous nous sommes concentrés sur le comportement de la mobilité dans les dispositifs SOI planaires et FinFET en effectuant des mesures de magnétorésistance à basse température. Nous avons mis en évidence expérimentalement un comportement de mobilité inhabituel (multi-branche) obtenu lorsque deux ou plusieurs canaux coexistent et interagissent. Un autre résultat original concerne l existence et l interprétation de la magnétorésistance géométrique dans les FinFETs.L'utilisation de FinFETs fabriqués sur ONO enterré en tant que mémoire non volatile flash a été proposée dans le quatrième chapitre. Deux mécanismes d'injection de charge ont été étudiés systématiquement. En plus de la démonstration de la pertinence de ce type mémoire en termes de performances (rétention, marge de détection), nous avons mis en évidence un comportement inattendu : l amélioration de la marge de détection pour des dispositifs à canaux courts. Notre concept innovant de FinFlash sur ONO enterré présente plusieurs avantages: (i) opération double-bit et (ii) séparation de la grille de stockage et de l'interface de lecture augmentant la fiabilité et autorisant une miniaturisation plus poussée que des Finflash conventionnels avec grille ONO.Dans le dernier chapitre, nous avons exploré le concept de mémoire unifiée, en combinant les opérations non volatiles et 1T-DRAM par le biais des FinFETs sur ONO enterré. Comme escompté pour les mémoires dites unifiées, le courant transitoire en mode 1T-DRAM dépend des charges non volatiles stockées dans le ONO. D'autre part, nous avons montré que les charges piégées dans le nitrure ne sont pas perturbées par les opérations de programmation et lecture de la 1T-DRAM. Les performances de cette mémoire unifiée multi-bits sont prometteuses et pourront être considérablement améliorées par optimisation technologique de ce dispositif.The evolution of electronic systems and portable devices requires innovation in both circuit design and transistor architecture. During last fifty years, the main issue in MOS transistor has been the gate length scaling down. The reduction of power consumption together with the co-integration of different functions is a more recent avenue. In bulk-Si planar technology, device shrinking seems to arrive at the end due to the multiplication of parasitic effects. The relay has been taken by novel SOI-like device architectures. In this perspective, this manuscript presents the main achievements of our work obtained with a variety of advanced fully depleted SOI MOSFETs, which are very promising candidates for next generation MOSFETs. Their electrical properties have been analyzed by systematic measurements and clarified by analytical models and/or simulations. Ultimately, appropriate applications have been proposed based on their beneficial features.In the first chapter, we briefly addressed the short-channel effects and the diverse technologies to improve device performance. The second chapter was dedicated to the detailed characterization and interesting properties of SOI devices. We have demonstrated excellent gate control and high performance in ultra-thin FD SOI MOSFET. The SCEs are efficiently suppressed by decreasing the body thickness below 7 nm. We have investigated the transport and electrostatic properties as well as the coupling mechanisms. The strong impact of body thickness and temperature range has been outlined. A similar approach was used to investigate and compare vertical double-gate and triple-gate FinFETs. DG FinFETs show enhanced coupling to back-gate bias which is applicable and suitable for dynamic threshold voltage tuning. We have proposed original models explaining the 3D coupling effect in FinFETs and the mobility behavior in ZnO TFTs. Our results pointed on the similarities and differences in SOI and ZnO transistors. According to our low-temperature measurements and new promoted extraction methods, the mobility in ZnO and the quality of ZnO/SiO2 interface are respectable, enabling innovating applications in flexible, transparent and power electronics. In the third chapter, we focused on the mobility behavior in planar SOI and FinFET devices by performing low-temperature magnetoresistance measurements. Unusual mobility curve with multi-branch aspect were obtained when two or more channels coexist and interplay. Another original result in the existence of the geometrical magnetoresistance in triple-gate and even double-gate FinFETs.The operation of a flash memory in FinFETs with ONO buried layer was explored in the forth chapter. Two charge injection mechanisms were proposed and systematically investigated. We have discussed the role of device geometry and temperature. Our novel ONO FinFlash concept has several distinct advantages: double-bit operation, separation of storage medium and reading interface, reliability and scalability. In the final chapter, we explored the avenue of unified memory, by combining nonvolatile and 1T-DRAM operations in a single transistor. The key result is that the transient current, relevant for 1T-DRAM operation, depends on the nonvolatile charges stored in the nitride buried layer. On the other hand, the trapped charges are not disturbed by the 1T-DRAM operation. Our experimental data offers the proof-of-concept for such advanced memory. The performance of the unified/multi-bit memory is already decent but will greatly improve in the coming years by processing dedicated devices.SAVOIE-SCD - Bib.électronique (730659901) / SudocGRENOBLE1/INP-Bib.électronique (384210012) / SudocGRENOBLE2/3-Bib.électronique (384219901) / SudocSudocFranceF

Intelligent Circuits and Systems

ICICS-2020 is the third conference initiated by the School of Electronics and Electrical Engineering at Lovely Professional University that explored recent innovations of researchers working for the development of smart and green technologies in the fields of Energy, Electronics, Communications, Computers, and Control. ICICS provides innovators to identify new opportunities for the social and economic benefits of society.　 This conference bridges the gap between academics and R&D institutions, social visionaries, and experts from all strata of society to present their ongoing research activities and foster research relations between them. It provides opportunities for the exchange of new ideas, applications, and experiences in the field of smart technologies and finding global partners for future collaboration. The ICICS-2020 was conducted in two broad categories, Intelligent Circuits & Intelligent Systems and Emerging Technologies in Electrical Engineering

NASA patent abstracts bibliography: A continuing bibliography. Section 2: Indexes (supplement 45)

A subject index is provided for over 5600 patents and patent applications for the period May 1969 through June 1994. Additional indexes list personal authors, corporate authors, contract numbers, NASA case numbers, U.S. patent class numbers, U.S. patent numbers, and NASA accession numbers

NASA patent abstracts bibliography: A continuing bibliography. Section 2: Indexes (supplement 46)

A subject index is provided for over 5600 patents and patent applications for the period May 1969 through December 1994. Additional indexes list personal authors, corporate authors, contract numbers, NASA case numbers, U.S. patent class numbers, U.S. patent numbers, and NASA accession numbers