Comparing the impact of power supply voltage on CMOS-and FinFET-based SRAMs in the presence of resistive defects

CMOS technology scaling has reached its limit at the 22 nm technology node due to several factors including Process Variations (PV), increased leakage current, Random Dopant Fluctuation (RDF), and mainly the Short-Channel Effect (SCE). In order to continue the miniaturization process via technology down-scaling while preserving system reliability and performance, Fin Field-Effect Transistors (FinFETs) arise as an alternative to CMOS transistors. In parallel, Static Random-Access Memories (SRAMs) increasingly occupy great part of Systems-on-Chips’ (SoCs) silicon area, making their reliability an important issue. SRAMs are designed to reach densities at the limit of the manufacturing process, making this component susceptible to manufacturing defects, including the resistive ones. Such defects may cause dynamic faults during the circuits’ lifetime, an important cause of test escape. Thus, the identification of the proper faulty behavior taking different operating conditions into account is considered crucial to guarantee the development of more suitable test methodologies. In this context, a comparison between the behavior of a 22 nm CMOS-based and a 20 nm FinFET-based SRAM in the presence of resistive defects is carried out considering different power supply voltages. In more detail, the behavior of defective cells operating under different power supply voltages has been investigated performing SPICE simulations. Results show that the power supply voltage plays an important role in the faulty behavior of both CMOS- and FinFET-based SRAM cells in the presence of resistive defects but demonstrate to be more expressive when considering the FinFET-based memories. Studying different operating temperatures, the results show an expressively higher occurrence of dynamic faults in FinFET-based SRAMs when compared to CMOS technology

A novel optimization framework for controlling stabilization issue in design principle of FinFET based SRAM

The conventional design principle of the finFET offers various constraints that act as an impediment towards improving ther performance of finFET SRAM. After reviewing existing approaches, it has been found that there are not enough work found to be emphasizing on cost-effective optimization by addressing the stability problems in finFET design.Therefore, the proposed system introduces a novel optimization mechanism considering some essential design attributes e.g. area, thickness of fin, and number of components. The contribution of the proposed technique is to determine the better form of thickness of fin and its related aspect that can act as a solution to minimize various other asscoiated problems in finFET SRAM. Implemented using soft-computational approach, the proposed system exhibits that it offers better energy retention, lower delay, and potential capability to offer higher throughput irrespective of presence of uncertain amount of noise within the component

A Process Variation Tolerant Self-Compensation Sense Amplifier Design

As we move under the aegis of the Moore\u27s law, we have to deal with its darker side with problems like leakage and short channel effects. Once we go beyond 45nm regime process variations also have emerged as a significant design concern.Embedded memories uses sense amplifier for fast sensing and typically, sense amplifiers uses pair of matched transistors in a positive feedback environment. A small difference in voltage level of applied input signals to these matched transistors is amplified and the resulting logic signals are latched. Intra die variation causes mismatch between the sense transistors that should ideally be identical structures. Yield loss due to device and process variations has never been so critical to cause failure in circuits. Due to growth in size of embedded SRAMs as well as usage of sense amplifier based signaling techniques, process variations in sense amplifiers leads to significant loss of yield for that we need to come up with process variation tolerant circuit styles and new devices. In this work impact of transistor mismatch due to process variations on sense amplifier is evaluated and this problem is stated. For the solution of the problem a novel self compensation scheme on sense amplifiers is presented on different technology nodes up to 32nm on conventional bulk MOSFET technology. Our results show that the self compensation technique in the conventional bulk MOSFET latch type sense amplifier not just gives improvement in the yield but also leads to improvement in performance for latch type sense amplifiers. Lithography related CD variations, fluctuations in dopant density, oxide thickness and parametric variations of devices are identified as a major challenge to the classical bulk type MOSFET. With the emerging nanoscale devices, SIA roadmap identifies FinFETs as a candidate for post-planar end-of-roadmap CMOS device. With current technology scaling issues and with conventional bulk type MOSFET on 32nm node our technique can easily be applied to Double Gate devices. In this work, we also develop the model of Double Gate MOSFET through 3D Device Simulator Damocles and TCAD simulator. We propose a FinFET based process variation tolerant sense amplifier design that exploits the back gate of FinFET devices for dynamic compensation against process variations. Results from statistical simulation show that the proposed dynamic compensation is highly effective in restoring yield at a level comparable to that of sense amplifiers without process variations. We created the 32nm double gate models generated from Damocles 3-D device simulations [25] and Taurus Device Simulator available commercially from Synopsys [47] and use them in the nominal latch type sense amplifier design and on the Independent Gate Self Compensation Sense Amplifier Design (IGSSA) to compare the yield and performance benefits of sense amplifier design on FinFET technology over the conventional bulk type CMOS based sense amplifier on 32nm technology node effective in restoring yield at a level comparable to that of sense amplifiers without process variations. We created the 32nm double gate models generated from Damocles 3-D device simulations [25] and Taurus Device Simulator available commercially from Synopsys [47] and use them in the nominal latch type sense amplifier design and on the Independent Gate Self Compensation Sense Amplifier Design (IGSSA) to compare the yield and performance benefits of sense amplifier design on FinFET technology over the conventional bulk type CMOS based sense amplifier on 32nm technology node

Cross-Layer Resiliency Modeling and Optimization: A Device to Circuit Approach

The never ending demand for higher performance and lower power consumption pushes the VLSI industry to further scale the technology down. However, further downscaling of technology at nano-scale leads to major challenges. Reduced reliability is one of them, arising from multiple sources e.g. runtime variations, process variation, and transient errors. The objective of this thesis is to tackle unreliability with a cross layer approach from device up to circuit level

プレーナーガタオヨビフィンフェットガタエスラムニオケルチジョウホウシャセンキインシングルイベントアップセットニカンスルジッケンテキケンキュウ

T. Kato et al., "Muon-Induced Single-Event Upsets in 20-nm SRAMs: Comparative Characterization With Neutrons and Alpha Particles," in IEEE Transactions on Nuclear Science, vol. 68, no. 7, pp. 1436-1444, July 2021, doi: 10.1109/TNS.2021.3082559

Cache memory design in the FinFET era

The major problem in the future technology scaling is the variations in process parameters that are interpreted as imperfections in the development process. Moreover, devices are more sensitive to the environmental changes of temperature and supply volt- age as well as to ageing. All these influences are manifested in the integrated circuits as increased power consumption, reduced maximal operating frequency and increased number of failures. These effects have been partially overcome with the introduction of the FinFET technology which have solved the problem of variability caused by Random Dopant Fluctuations. However, in the next ten years channel length is projected to shrink to 10nm where the variability source generated by Line Edge Roughness will dominate, and its effects on the threshold voltage variations will become critical. The embedded memories with their cells as the basic building unit are the most prone to these effects due to their the smallest dimensions. Because of that, memories should be designed with particular care in order to make possible further technology scaling. This thesis explores upcoming 10nm FinFETs and the existing issues in the cache memory design with this technology. More- over, it tries to present some original and novel techniques on the different level of design abstraction for mitigating the effects of process and environmental variability. At first original method for simulating variability of Tri-Gate Fin- FETs is presented using conventional HSPICE simulation environment and BSIM-CMG model cards. When that is accomplished, thorough characterisation of traditional SRAM cell circuits (6T and 8T) is performed. Possibility of using Independent Gate FinFETs for increasing cell stability has been explored, also. Gain Cells appeared in the recent past as an attractive alternative for in the cache memory design. This thesis partially explores this idea by presenting and performing detailed circuit analysis of the dynamic 3T gain cell for 10nm FinFETs. At the top of this work, thesis shows one micro-architecture optimisation of high-speed cache when it is implemented by 3T gain cells. We show how the cache coherency states can be used in order to reduce refresh energy of the memory as well as reduce memory ageing.El principal problema de l'escalat la tecnologia són les variacions en els paràmetres de disseny (imperfeccions) durant procés de fabricació. D'altra banda, els dispositius també són més sensibles als canvis ambientals de temperatura, la tensió d'alimentació, així com l'envelliment. Totes aquestes influències es manifesten en els circuits integrats com l'augment de consum d'energia, la reducció de la freqüència d'operació màxima i l'augment del nombre de xips descartats. Aquests efectes s'han superat parcialment amb la introducció de la tecnologia FinFET que ha resolt el problema de la variabilitat causada per les fluctuacions de dopants aleatòries. No obstant això, en els propers deu anys, l'ample del canal es preveu que es reduirà a 10nm, on la font de la variabilitat generada per les rugositats de les línies de material dominarà, i els seu efecte en les variacions de voltatge llindar augmentarà. Les memòries encastades amb les seves cel·les com la unitat bàsica de construcció són les més propenses a sofrir aquests efectes a causa de les seves dimensions més petites. A causa d'això, cal dissenyar les memòries amb una especial cura per tal de fer possible l'escalat de la tecnologia. Aquesta tesi explora la tecnologia de FinFETs de 10nm i els problemes existents en el disseny de memòries amb aquesta tecnologia. A més a més, presentem noves tècniques originals sobre diferents nivells d'abstracció del disseny per a la mitigació dels efectes les variacions tan de procés com ambientals. En primer lloc, presentem un mètode original per a la simulació de la variabilitat de Tri-Gate FinFETs usant entorn de simulació HSPICE convencional i models de tecnologia BSIMCMG. Després, es realitza la caracterització completa dels circuits de cel·les SRAM tradicionals (6T i 8T) conjuntament amb l'ús de Gate-independent FinFETs per augmentar l'estabilitat de la cèl·lula

Reliability and Data Analysis of Wearout Mechanisms for Circuits

The objective of this research is to develop methodologies for the failure analysis of circuits, as well as investigate the factors for accelerating testing for front-end-of-line time-dependent dielectric breakdown (FEOL TDDB). The separation of wearout mechanisms for circuits will be investigated, and the identification of failure modes for the failure samples will be analyzed. SRAMs and ring oscillators will be used to study the failure modes. The systematic and random errors for online monitoring of SRAMS will also be examined. Furthermore, the testing plans for acceleration testing will also be explored for ring oscillators. Error reduction through sampling will also be used to find the best testing conditions for accelerated testing. This work provides a way for engineers to better understand aging monitoring of circuits, and to design better testing to collect failure data.Ph.D

Fault Modeling in Controllable Polarity Silicon Nanowire Circuits

Controllable polarity silicon nanowire transistors are among the promising candidates to replace current CMOS in the near future owing to their superior electrostatic characteristics and advanced functionalities. From a circuit testing point of view, it is unclear if the current CMOS and Fin-FET fault models are comprehensive enough to model all defects of controllable polarity nanowires. In this paper, we deal with the above problem using inductive fault analysis on three-independent-gate silicon nanowire FETs. Simulations revealed that the current fault models, i.e. stuck-open faults, are insufficient to cover all modes of operation. The newly introduced test algorithm for stuck open can adequately capture the malfunction behavior of controllable polarity logic gates in the presence of nanowire break and bridge on polarity terminals

From Defect Analysis to Gate-Level Fault Modeling of Controllable-Polarity Silicon Nanowires

Controllable-Polarity Silicon Nanowire Transistors (CP-SiNWFETs) are among the promising candidates to complement or even replace the current CMOS technology in the near future. Polarity control is a desirable property that allows the on-line configuration of the device polarity. CP-SiNWFETs result in smaller and faster logic gates unachievable with conventional CMOS implementations. From a circuit testing point of view, it is unclear if the current CMOS and FinFET fault models are comprehensive enough to model all the defects of CP-SiNWFETs. In this paper, we explore the possible manufacturing defects of this technology through analyzing the fabrication steps and the layout structure of logic gates. Using the obtained defects, we then evaluate their impacts on the performance and the functionality of CP-SiNWFET logic gates. Out of the results, we extend the current fault model to a new a hybrid model, including stuck-at ptype and stuck-at n-type, which can be efficiently used to test the logic circuits in this technology. The newly introduced fault model can be utilized to adequately capture the malfunction behavior of CP logic gates in the presence of nanowire break, bridge and float defects. Moreover, the simulations revealed that the current CMOS test methods are insufficient to cover all faults, i.e., stuck- Open. We proposed an appropriate test method to capture such faults as well