Development of a Universal MOSFET Gate Impedance Model

Scaling of CMOS technology to 100 nm & below and the endless pursuit of higher operating frequencies drive the need to accurately model effects that dominate at those feature sizes and frequencies. Current modeling techniques are frequency limited and require different models for different frequency ranges in order to achieve accuracy goals. In the foundry world, high frequency models are typically empirical in nature and significantly lag their low frequency counterparts in terms of availability. This tends to slow the adoption of new foundry technologies for high performance applications such as extremely high data rate serializer/deserializer transceiver cores. However, design cycle time and time to market while transitioning between technology nodes can be reduced by incorporating a reusable, industry-standard model. This work proposes such a model for device gate impedance that is simulator-friendly, compact, frequencyindependent, and relatively portable across technology nodes. This semi-empirical gate impedance model is based on depletion in the poly-silicon gate electrode. The effect of device length and single-leg width on the input impedance is studied with the aid of extensive measured data obtained from devices built in 110 nm and 180 nm technologies in the 1-20GHz frequency range. The measured data illustrates that the device input impedance has a non-linear frequency dependency. This variation in input impedance is the result of gate poly-silicon depletion, which can be modeled by an external RC network connected at the gate of the device. Excellent agreement between the simulation results and the measured data validates the model in the device active region for 1-20GHz frequency range. The gate impedance model is further modified by incorporating parasitic effects, extending its range to 200MHz-20GHz. This model performs accurately for 180 run, 110 nm and 90 nm technologies at different bias conditions and dimensions. The model and model parameter behavior are consistent across technology nodes thereby enabling re-usability and portability. The accuracy of this new gate impedance model is demonstrated in various applications: to validate the model extraction techniques for different device configurations, to assess the input data run-length variations on CML buffer performance and to estimate the jitter in ring oscillators

Rainfall over the Netherlands & beyond: a remote sensing perspective

Earthlings like to measure everything (especially now that we are undergoing the era of big-data revolution) maybe because it is such a nice hobby... although a more serious school of thought believes that when measuring our environment we get to understand physics and ourselves. This thesis explores the uncertainties in rainfall measurements from state-of-the-art technologies like commercial microwave links (CML) and meteorological satellites. Rainfall has been measured by rain gauges since quite some time ago; and by weather radars since the end of WWII. Here we evaluate the performance of gridded-rainfall products for the land surface of the Netherlands. These gridded-rainfall products are CML-rainfall maps produced by the Royal Netherlands Meteorology Institute (KNMI), and the IMERG product developed by Global Precipitation Measurement mission (GPM). Overall, this thesis shows that CML-rainfall products are very reliable sources with regards to rainfall estimates for the land surface of the Netherlands... even better than the satellite products for rainfall estimation. We are also confident in the promising potential these technologies hold for places around the world where conventional technologies like gauges or radars are not scarce or not affordable. </p

High-performance and hardware-aware computing: proceedings of the second International Workshop on New Frontiers in High-performance and Hardware-aware Computing (HipHaC\u2711), San Antonio, Texas, USA, February 2011 ; (in conjunction with HPCA-17)

High-performance system architectures are increasingly exploiting heterogeneity. The HipHaC workshop aims at combining new aspects of parallel, heterogeneous, and reconfigurable microprocessor technologies with concepts of high-performance computing and, particularly, numerical solution methods. Compute- and memory-intensive applications can only benefit from the full hardware potential if all features on all levels are taken into account in a holistic approach

Analysis and Design of High Speed Serial Interfaces for Automotive Applications

The demand for an enriched end-user experience and increased performance in next generation electronic applications is never ending, and it is a common trend for a wide spectrum of applications owing to different markets, like computing, mobile communication and automotive. For this reason High Speed Serial Interface have become widespread components for nowadays electronics with a constant demand for power reduction and data rate increase. In the frame of gigabit serial systems, the work discussed in this thesis develops in two directions: on one hand, the aim is to support the continuous data rate increase with the development of novel link modeling approaches that will be employed for system level evaluation and as support in the design and characterization phases. On the other hand, the design considerations and challenges in the implementation of the transmitter, one of the most delicate blocks for the signal integrity performance of the link, are central. The first part of the activity regarding link performance predictions lead to the development of an enhanced statistical simulation approach, capable to account for the transmitter waveform shape in the ISI analysis, a characteristic that is missed by the available state-ofthe- art simulation approaches. The proposed approach has been extensively tested by comparison with traditional simulation approaches (Spice-like simulators) and validated against experimental characterization of a test system, with satisfactory results. The second part of the activity consists in the design of a high speed transmitter in a deeply scaled CMOS technology, spanning from the concept of the circuit, its implementation and characterization. Targets of the design are to achieve a data rate of 5 Gb/s with a minimum voltage swing of 800 mV, thus doubling the data rate of the current transmitter implementation, and reduce the power dissipation adopting a voltage mode architecture. The experimental characterization of the fabricated lot draws a twofold picture, with some of the performance figures showing a very good qualitative and quantitative agreement with pre-silicon simulations, and others revealing a poor performance level, especially for the eye diagram. Investigation of the root causes by the analysis of the physical silicon design, of the bonding scheme of the prototypes and of the pre-silicon simulations is reported. Guidelines for the redesign of the circuit are also given.Nel panorama delle applicazioni elettroniche il miglioramento delle performance di un prodotto da una generazione alla successiva ha lo scopo di offrire all\u2019utilizzatore finale nuove funzioni e migliorare quelle esistenti. Negli ultimi anni grazie al costante avanzamento della tecnologia integrata, si \ue8 assistito ad un enorme sviluppo della capacit\ue0 computazionale dei dispositivi in tutti i segmenti di mercato, quali ad esempio l\u2019information technology, la comunicazione mobile e l\u2019automotive. La conseguente necessit\ue0 di mettere in comunicazione dispostivi diversi all\u2019interno della stessa applicazione e di traferire grosse quantit\ue0 di dati ha provocato una capillare diffusione delle interfacce seriali ad alta velocit\ue0, o High Speed Serial Interfaces (HSSIs). La necessit\ue0 di ridurre il consumo di potenza e aumentare il bit rate per questo tipo di applicazioni \ue8 diventata dunque un ambito di ricerca di estremo interesse. Il lavoro discusso in questa tesi si colloca nell\u2019ambito della trasmissione di dati seriali a bit rate superiori ad 1Gb/s e si sviluppa in due direzioni: da un lato, a sostegno del continuo aumento del bit rate nelle nuove generazioni di interfacce, \ue8 stato affrontato lo sviluppo di nuovi approcci di modellazione del sistema, che possano essere impiegati nella valutazione delle prestazioni dell\u2019interfaccia e a supporto delle fasi di progettazione e di caratterizzazione. Dall\u2019altro lato, si \ue8 focalizzata l\u2019attenzione sulle sfide e sulle problematiche inerenti il progetto di uno dei blocchi pi\uf9 delicati per le prestazioni del sistema, il trasmettitore. La prima parte della tesi ha come oggetto lo sviluppo di un approccio di simulazione statistico innovativo, in grado di includere nell\u2019analisi degli effetti dell\u2019interferenza di intersimbolo anche la forma d\u2019onda prodotta all\u2019uscita del trasmettitore, una caratteristica che non \ue8 presente in altri approcci di simulazione proposti in letteratura. La tecnica proposta \ue8 ampiamente testata mediante il confronto con approcci di simulazione tradizionali (di tipo Spice) e mediante il confronto con la caratterizzazione sperimentale di un sistema di test, con risultati pienamente soddisfacenti. La seconda parte dell\u2019attivit\ue0 riguarda il progetto di un trasmettitore integrato high speed in tecnologia CMOS a 40nm e si estende dallo studio di fattibilit\ue0 del circuito fino alla sua realizzazione e caratterizzazione. Gli obiettivi riguardano il raggiungimento di un bit rate pari a 5 Gb/s, raddoppiando cos\uec il bit rate dell\u2019attuale implementazione, e di una tensione differenziale di uscita minima di 800mV (picco-picco) riducendo allo stesso tempo la potenza dissipata mediante l\u2019adozione di una architettura Voltage Mode. I risultati sperimentali ottenuti dal primo lotto fabbricato non delineano un quadro univoco: alcune performance mostrano un ottimo accordo qualitativo e quantitativo con le simulazioni pre-fabbricazione, mentre prestazioni non soddisfacenti sono state ottenute in particolare per il diagramma ad occhio. Grazie all\u2019analisi del layout del prototipo, del bonding tra silicio e package e delle simulazioni pre-fabbricazione \ue8 stato possibile risalire ai fattori responsabili del degrado delle prestazioni rispetto alla previsioni pre-fabbricazione, permettendo inoltre di delineare le linee guida da seguire nella futura progettazione di un nuovo prototipo

Characterization of process variability and robust optimization of analog circuits

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2008.Includes bibliographical references (p. 161-174).Continuous scaling of CMOS technology has enabled dramatic performance enhancement of CMOS devices and has provided speed, power, and density improvement in both digital and analog circuits. CMOS millimeter-wave applications operating at more than 50GHz frequencies has become viable in sub-100nm CMOS technologies, providing advantages in cost and high density integration compared to other heterogeneous technologies such as SiGe and III-V compound semiconductors. However, as the operating frequency of CMOS circuits increases, it becomes more difficult to obtain sufficiently wide operating ranges for robust operation in essential analog building blocks such as voltage-controlled oscillators (VCOs) and frequency dividers. The fluctuations of circuit parameters caused by the random and systematic variations in key manufacturing steps become more significant in nano-scale technologies. The process variation of circuit performance is quickly becoming one of the main concerns in high performance analog design. In this thesis, we show design and analysis of a VCO and frequency divider operating beyond 70GHz in a 65nm SOI CMOS technology. The VCO and frequency divider employ design techniques enlarging frequency operating ranges to improve the robustness of circuit operation. Circuit performance is measured from a number of die samples to identify the statistical properties of performance variation. A back-propagation of variation (BPV) scheme based on sensitivity analysis of circuit performance is proposed to extract critical circuit parameter variation using statistical measurement results of the frequency divider. We analyze functional failure caused by performance variability, and propose dynamic and static optimization methods to improve parametric yield. An external bias control is utilized to dynamically tune the divider operating range and to compensate for performance variation. A novel time delay model of a differential CML buffer is proposed to functionally approximate the maximum operating frequency of the frequency divider, which dramatically reduces computational cost of parametric yield estimation. The functional approximation enables the optimization of the VCO and frequency divider parametric yield with a reasonable amount of simulation time.by Daihyun Lim.Ph.D

Applications in Electronics Pervading Industry, Environment and Society

This book features the manuscripts accepted for the Special Issue “Applications in Electronics Pervading Industry, Environment and Society—Sensing Systems and Pervasive Intelligence” of the MDPI journal Sensors. Most of the papers come from a selection of the best papers of the 2019 edition of the “Applications in Electronics Pervading Industry, Environment and Society” (APPLEPIES) Conference, which was held in November 2019. All these papers have been significantly enhanced with novel experimental results. The papers give an overview of the trends in research and development activities concerning the pervasive application of electronics in industry, the environment, and society. The focus of these papers is on cyber physical systems (CPS), with research proposals for new sensor acquisition and ADC (analog to digital converter) methods, high-speed communication systems, cybersecurity, big data management, and data processing including emerging machine learning techniques. Physical implementation aspects are discussed as well as the trade-off found between functional performance and hardware/system costs

Phase Noise in CMOS Phase-Locked Loop Circuits

Phase-locked loops (PLLs) have been widely used in mixed-signal integrated circuits. With the continuously increasing demand of market for high speed, low noise devices, PLLs are playing a more important role in communications. In this dissertation, phase noise and jitter performances are investigated in different types of PLL designs. Hot carrier and negative bias temperature instability effects are analyzed from simulations and experiments. Phase noise of a CMOS phase-locked loop as a frequency synthesizer circuit is modeled from the superposition of noises from its building blocks: voltage-controlled oscillator, frequency divider, phase-frequency detector, loop filter and auxiliary input reference clock. A linear time invariant model with additive noise sources in frequency domain is presented to analyze the phase noise. The modeled phase noise results are compared with the corresponding experimentally measured results on phase-locked loop chips fabricated in 0.5 m n-well CMOS process. With the scaling of CMOS technology and the increase of electrical field, MOS transistors have become very sensitive to hot carrier effect (HCE) and negative bias temperature instability (NBTI). These two reliability issues pose challenges to designers for designing of chips in deep submicron CMOS technologies. A new strategy of switchable CMOS phase-locked loop frequency synthesizer is proposed to increase its tuning range. The switchable PLL which integrates two phase-locked loops with different tuning frequencies are designed and fabricated in 0.5 µm CMOS process to analyze the effects under HCE and NBTI. A 3V 1.2 GHz programmable phase-locked loop frequency synthesizer is designed in 0.5 μm CMOS technology. The frequency synthesizer is implemented using LC voltage-controlled oscillator (VCO) and a low power dual-modulus prescaler. The LC VCO working range is from 900MHz to 1.4GHz. Current mode logic (CML) is used in designing high speed D flip-flop in the dual-modulus prescaler circuits for low power consumption. The power consumption of the PLL chip is under 30mW. Fully differential LC VCO is used to provide high oscillation frequency. A new design of LC VCO using carbon nanotube (CNT) wire inductor has been proposed. The PLL design using CNT-LC VCO shows significant improvement in phase noise due to high-Q LC circuit