Graphene Devices for Beyond-CMOS Heterogeneous Integration

Darwish, Mohamed

01 September 2017

Semiconductor manufacturing is the workhorse for a wide range of industries. It lies at the heart of consumer electronics, telecommunication equipment and medical devices. Most semiconductor electronics are made from Silicon, and are fabricated using CMOS technology. The versatility of semiconductor electronics stems from the ever-reducing cost of integrating more computing and memory functions on chip. The small cost for adding extra functions has been maintained in the past 50 years through transistor scaling. Transistor scaling focuses on shrinking the size of transistors integrated on chip. This reduction in transistor size, while keeping the overall cost of the chip fixed allowed us to reduce the cost per function with scaling, and is what is celebrated as Moore’s law. Scaling has been working gracefully up to the last decade, where the exponential rise in manufacturing cost and diminishing gains of scaling on device performance reduce its economic benefit. To revive the cost reduction trend, different techniques were proposed such as augmenting CMOS manufacturing with new materials (Beyond-CMOS), 3D integration, and integrating more non-transistor elements on-chip (More than Moore). In this work, we focus on the efficient implementation of several circuit functions using an allotropy of carbon known as graphene. Graphene, a single layer of carbon atoms arranged in a hexagonal lattice, has unique electronic properties that has been taken the solid-state electronics community by a storm since its first experimental conception in 2004. Despite its promising electronic properties, namely the very high charge-carrier mobility and reduced scattering by impurities, graphene circuits has been held back by a plethora of nonidealities and technological roadblocks that hamper its use in traditional transistor-based circuits. In this work, we attempt to leverage the unique physical properties of graphene to implement non von-Neumann neuromorphic computing architectures, low-loss diodes and evaluate the behavior of diffusive-transport graphene couplers. We focus on the the design, fabrication and characterization of graphene devices in the presence of the current performance-limiting technological nonidealities in heterogeneous graphene-CMOS systems. We present the design, fabrication and characterization of all-graphene resistive data converters devices and diodes, discussing their performance and application as building elements of all-graphene brain-inspired computing architectures. We evaluate the performance of graphene couplers operating in the diffusive transport regime, which serve as a method to analyze the cross-coupling between adjacent graphene interconnects. We also discuss the current technological limitations hampering the performance of graphene devices, and the roles of different processing non-idealities on the characteristics of graphene devices.

Beyond-CMOS

Graphene

Heterogeneous Integration

DESIGN OF A CMOS BASED IMAGE SENSOR USING COMPRESSIVE IMAGE SENSING

Pattnaik, Abhijeet

01 September 2021

This work optimizes a CMOS image pixel sensor circuit for being used in a compressive sensing (CS) image sensor. The CS image sensor sums neighbor pixel outputs and hence reduces analog to digital conversions. Efforts are also made to improve the circuit that performs such pixel summation. With the optimized design, a CMOS image sensor circuit with a compression ratio of 4 is designed using a 130 nm CMOS technology from Global foundries. The design pixel sensor has a 256X256 pixel array. Simulation shows that the developed image sensors can achieve peak signal to noise ratio (PSNR) of 28 dB and 37.8 dB for benchmark images Cameraman and Lenna, respectively.

CMOS IMAGE SENSORS

ELECTRONICS

VLSI

Exploring the Performance Impacts of Harmful FPGA Configurations

Gaskin, Tanner

17 May 2021

In this work a new technique for accelerating the aging of FPGA devices is proposed and demonstrated. The proposed technique uses harmful configurations (short circuits) to accelerate the aging process on targeted portions of an FPGA chip. A testbed is developed for the purpose of measuring FPGA degradation. Using this testbed it is shown that implementing thousands of short circuits in FPGA fabric generates enough heat to cause significant damage to the chip, reducing switching speeds by up to 8%. It is also demonstrated that different parts of the FPGA fabric can be aged at different rates, with some parts of the chip only slowing down 2% while other parts slowdown as much as 8%.

fpga

cmos aging

security

Engineering

Circuit Techniques on Improving Timing and Noise in Dynamic CMOS

Vaidyanadeswaran, Arvind

07 April 2011

No description available.

Electrical Engineering

CMOS

circuit techniques

Two-Stage Operational Amplifier Design by Using Direct and Indirect Feedback Compensations

Zhang, Jiayuan

21 June 2021

This paper states the stability requirements of the amplifier system, and then presents, and summarizes, the classic two stage CMOS Op-Amp design by employing several popular frequency compensation techniques including traditional Miller compensation, nulling resistor, voltage buffer, and current buffer. The advantages and disadvantages of all these compensation strategies are evaluated based on a standard performance which has a 70dB DC gain, a 60◦ phase margin, a 25MHz gain bandwidth, and a slew rate of 20 V/us requirements. All the designs and simulation results are based on a 180mm 1.8 V standard TSMC CMOS technology. Ultimately, the traditional Miller compensated Op-Amp (a single compensation capacitor amplifier) cannot meet all the requirements but all other techniques could with also a boost of performance in various aspects. / Master of Science / Two-stage CMOS operational amplifier has two input pins and one output pin. it is used to amplify the differential inputs signal and transfer it to the output side. Usually the input signals are too weak to be processed by the rest of the system units. So the Op-Amp can amplify the weak input signals which then can either be further modified for some specific applications by the rest units of the system or be the final output of this entire system. The role of the Op-Amp in analog and digital systems is as the role of transformers in the power system. So the output signal is required to have fast and stable responses to the inputs. This paper states some standard requirements of the Op-Amp in aspects of gain, stability, and operating frequency. Due to the classic design of two-stage Op-Amp has poor performance of stability and operating frequency, some compensation techniques are applied as the feedback networks to improve its performance. These techniques include traditional Miller compensation, nulling resistor, voltage buffer, and current buffer. The advantages and disadvantages of all these compensation strategies are evaluated based on a 180mm 1.8 V standard TSMC CMOS technology.

Op-Amp

CMOS

Miller Compensation

Projeto de um bloco LNA-misturador para radiofrequência em tecnologia CMOS. / A merged RF-CMOS LNA-mixer design in CMOS technology.

Ayala Pabón, Armando

15 December 2009

Este trabalho apresenta o projeto de um bloco LNA-Misturador dentro de um mesmo circuito integrado para aplicações em um receptor Bluetooth 2;45GHz. Uma estratégia de projeto bem clara, concisa e com uma boa base física e matemática foi desenvolvida para auxiliar o processo de projeto de um bloco LNA-Misturador, composto por um LNA cascode em cascata com um misturador de chaveamento de corrente com entradas simples e degeneração indutiva nas fontes dos estágios de transcondutância. Esta estratégia foi adaptada de trabalhos apresentados na literatura. A estratégia de projeto proposta considera o compromisso entre ruído, linearidade, ganho, dissipação de potência, casamento de impedâncias e isolamento de portas, usando as dimensões dos dispositivos e condições de polarização como variáveis de projeto. Com base nesta estratégia se obteve um bloco LNA-Misturador que atinge algumas especificações propostas. Um bloco LNA-Misturador foi projetado e fabricado em uma tecnologia CMOS 0;35µm para validar a estratégia de projeto proposta. Além disso, para atingir os objetivos, durante o desenvolvimento deste trabalho foi dada atenção especial no projeto dos indutores. Foi projetado, fabricado e medido um chip de teste. Para tal fim foram aplicadas técnicas e estruturas de de-embedding nas medidas para conseguir resultados mais confiáveis. Os resultados experimentais obtidos para os indutores e os resultados preliminares do bloco LNA-Misturador s~ao satisfatórios de acordo com as especificações e os esperados das simulações. No entanto, os indutores integrados degradam significativamente o desempenho do bloco LNA-Misturador. Se forem usados processos de fabricação nos quais os indutores apresentem melhor desempenho, os resultados do bloco LNA-Misturador aplicando a estratégia de projeto desenvolvida neste trabalho podem ser melhorados. Finalmente, é importante ressaltar que a estratégia de projeto proposta neste trabalho já está sendo usada e adaptada em outros projetos com o propósito de melhorar os resultados obtidos, e conseguir auxiliar o processo de projeto deste tipo de blocos. / This work presents a fully integrated LNA-Mixer design for a Bluetooth receiver application at 2:45GHz. A concise design strategy with good physics and mathematics basis was developed to assist the design process of a LNA-Mixer block, formed by a cascode LNA in cascade to a single balanced current commutation Mixer with inductive degeneration. This strategy was adapted from literature and considers the trade-offs between noise, linearity, gain, power dissipation, impedance matching and ports isolation, using the device dimensions and bias conditions as design variables. Based on this strategy, the proposed LNA-Mixer design specifications were achieved. To validate the proposed design strategy, the LNA-Mixer were fabricated in a 0:35µm CMOS process. Furthermore, to achieve the specifications, during the development of this work a special attention to the RF CMOS inductors was given. A test chip was designed, fabricated and measured applying de-embedding structures to obtain more reliable results. The experimental results obtained for the inductors and the preliminary results for the LNA-Mixer are satisfactory compared to the specifications and as expected from simulations. However, the integrated inductors degrade the performance of the block significantly and if a manufacturing process in which the inductor has better performance is used, the resulting LNA-Mixer design applying the strategy developed in this work can be improved. Finally, it is important to highlight that the design strategy proposed in this work is already being used and adapted in other designs in order to improve the results, and to assist the design process of such blocks.

Amplificadores

Circuitos integrados

CMOS low noise amplifiers

CMOS mixers

De-embedding structures

Integrated circuits

LNA-Mixer

Misturadores de sinal CMOS

Entwurf und Modellierung von Multikanal-CMOS-Farbsensoren

Henker, Stephan

27 September 2006

Color image acquisition and image processing have become a key in modern data application. In order to provide high quality images, the field of accurate acquisition is most important in respect to all further processing steps. But a whole variety of current image sensors possess incorrect color rendition due to insufficient accuracy of optical sensor parameters. This is detrimental especially for color sensors, because in these cases specific color information will be incorrectly acquired. Further, traditional color correction methods do not use information on the specific sensor spectral sensitivity, thus losing substantial information for color correction. The problem is investigated by introducing an algorithmic correction method which is capable of correcting dysfunctional sensor properties. The correction method is based on an enhancement of the CIE color perception model. According to this, color perception is modelled as a special integral transformation, where the spectral sensitivities of the photo receptors represent the base functions of the transformation. It is shown that different sets of photo receptors show the same perception, when their spectral sensitivities are linear dependent. On the other hand, photo receptors with no linear dependency show different perception and there is no analytical transformation between them. Thus, a perfect color correction is only possible if photo sensor and human perception show a linear dependency. In case of dissentient sensor characteristics, the correction method of spectral reconstruction can determine an optimal solution using a least square error optimization. Applying sensors with more than three color channels, this correction method can show improved results due to a better approximation. For implementation of the color correction scheme, different sensor designs have been developed. Compared with currently dominating CCD (Charge Coupled Device) technology, a realisation of image sensors based on CMOS technology show a high potential. CMOS technology allow the integration of the sensor together with control and image processing on the same chip, thus enabling the design of sensor systems at low cost. But modern sub-100nm technologies show also substantial disadvantages, such as increased leakage currents. Special circuit designs have been developed to especially reduce the influence of leakage currents. For application of the color correction method, new multi-channel photo sensors using vertically stacked photo diodes have been developed. The work further shows different concepts of multi-channel sensors capable of high quality color rendition. This approach is demonstrated on several new CMOS sensor designs with examples, implemented in a 90nm Infineon technology.

CMOS-Bildsensor

Farbkorrektur

CMOS image sensor

color correction

ddc:620

rvk:ST 330

Bildsensor

Farbbildverarbeitung

CMOS

Schaltungsentwurf

Nanotechnologie

Bildverbesserung

Commande optique intégrée en technologie CMOS pour les transistors de puissance / CMOS integrated optical gate driver for power transistors

Colin, Davy

14 December 2017

Le mémoire de thèse est structuré en 3 chapitres. Le 1er chapitre présente le contexte de forte vitesse de commutation et de forte intégration en électronique de puissance, dans lequel s’inscrit cette thèse. Les fonctions et les enjeux de l’organe de commande rapprochée (« gate driver ») sont présentés. L’intégration du gate driver en technologie CMOS AMS 0.18 µm HV est présentée puis, plus particulièrement, l’intégration des fonctions optiques. Le 2e chapitre concerne l’étude de la transmission et de la modulation des charges à travers la barrière d’isolation optique. Un amplificateur en courant configurable a été dimensionné afin de pouvoir faire varier la résistance de grille. Une alimentation optique est intégrée en technologie AMS H18, comprenant une cellule PV et un convertisseur DC/DC à capacités commutées. Dans le 3e chapitre, 2 approches ont été développées pour la transmission du signal, la transmission dite en bande de base où les ordres de commande optiques sont l’image directe de la modulation en largeur d’impulsion (MLI), et la transmission dite numérique série où les changements d’état sont envoyés avec une trame haute fréquence. Un circuit de gestion logique et une horloge interne ont été conçus. La transmission numérique permet l’envoi d’information telle que la configuration de la résistance de grille. Le dimensionnement des circuits prend en compte une large plage de température de fonctionnement (-40°C à 140 °C), ainsi que les contraintes dues à l’alimentation optique (variation de la tension d’alimentation) et à l’alignement optique (variation du photo-courant généré). / The thesis dissertation is composed of 3 chapters. The 1st chapter introduces the thesis context of fast switching transients and highly integrated power electronics circuits. The functions and the issues of the close gate driver are presented. The gate driver is integrated in the AMS 0.18 µm technology with its optical functions. The second chapter deals with the transmission and modulation of the gate driver charge through the optical isolation barrier. A configurable buffer is designed in order to modulate the gate resistance value. An optical supply including a PV cell and a switched capacitors DC/DC converter is integrated. In the third chapter, two approaches are developed for the gate signal transfer. For the baseband analog transmission, the optical signal is a direct image of the pulse width modulation (PWM) signal whereas in the digital series transmission, only the commutation orders are transmitted in a high frequency frame. A logic circuit and an integrated clock are designed. The digital transmission allowed the transfer of information such as the gate resistance configuration. Large temperature range (-40°C to 140°C), optical supply constraints (supply voltage deviation) and optical alignment (photocurrent value deviation) are considered for the integrated circuits design.

Électronique de puissance

Gate driver

Isolation galvanique

Driver optique

Cmos

Power electronics

Gate driver

Galvanic isolation

Optical driver

Cmos

Cmos

620

Projeto de células e circuitos VLSI digitais CMOS para operação em baixa tensão / CMOS digital cells and VLSI circuits design for ultra-low voltage operation

Rosa, André Luís Rodeghiero

January 2015

Este trabalho propõe uma estratégia para projeto de circuitos VLSI operando em amplo ajuste de tensão e frequência (VFS), desde o regime em Near-threshold, onde uma tensão de VDD caracteriza-se por permitir o funcionamento do circuito com o mínimo dispêndio de energia por operação (MEP), até tensões nominais, dependendo da carga de trabalho exigida pela aplicação. Nesta dissertação é proposto o dimensionamento de transistores para três bibliotecas de células utilizando MOSFETs com tensões de limiar distintas: Regular-VT (RVT), High-VT (HVT) e Low-VT (LVT). Tais bibliotecas possuem cinco células combinacionais: INV, NAND, NOR, OAI21 e AOI22 em múltiplos strengths. A regra para dimensionamento dos transistores das células lógicas foi adaptada de trabalhos relacionados, e fundamenta-se na equalização dos tempos de subida e descida na saída de cada célula, objetivando à redução dos efeitos de variabilidade em baixas tensões de operação. Dois registradores também foram incluídos na biblioteca RVT e sua caracterização foi realizada considerando os parâmetros de processo CMOS 65 nm typical, fast e slow; nas temperaturas de operação de -40°C, 25°C e 125°C, e para tensões variando de 200 mV até 1,2V, para incluir a região de interesse, próxima ao MEP. Os experimentos foram realizados utilizando dez circuitos VLSI de teste: filtro digital notch, um núcleo compatível com o micro-controlador 8051, quatro circuitos combinacionais e quatro sequenciais do benchmark ISCAS. Em termos de economia de energia, operar no MEP resulta em uma redução média de 54,46% em relação ao regime de sub-limiar e até 99,01% quando comparado com a tensão nominal, para a temperatura de 25°C e processo típico. Em relação ao desempenho, operar em regime de VFS muito amplo propicia frequências máximas que variam de centenas de kHz até a faixa de centenas de MHz a GHz, para as temperaturas de -40°C e 25°C, e de MHz até GHz em 125°C. Os resultados desta dissertação, quando comparados a trabalhos relacionados, demonstraram, em média, redução de energia e ganho de desempenho de 24,1% e 152,68%, respectivamente, considerando os mesmos circuitos de teste, operando no ponto de mínima energia (MEP). / This work proposes a strategy for designing VLSI circuits to operate in a very-wide Voltage-Frequency Scaling (VFS) range , from the supply voltage at which the minimum energy per operation (MEP) is achieved, at the Near-Threshold regime, up to the nominal supply voltage for the processes, if so demanded by applications workload. This master thesis proposes the sizing of transistors for three library cells using MOSFETs with different threshold voltages: Regular-VT (RVT), High-VT (HVT), and Low-VT (LVT). These libraries have five combinational cells: INV, NAND, NOR, OAI21, and AOI22 with multiple strengths. The sizing rule for the transistors of the digital cells was an adapted version from related works and it is directly driven by requiring equal rise and fall times at the output for each cell in order to attenuate variability effects in the low supply voltage regime. Two registers were also included in the RVT library cell. This library cell was characterized for typical, fast, and slow processes conditions of a CMOS 65nm technology; for operation at -40ºC, 25ºC, and 125ºC temperatures, and for supply voltages varying from 200 mV up to 1.2V, to include the region of interest, for VDD near the MEP. Experiments were performed with ten VLSI circuit benchmarks: notch filter, 8051 compatible core, four combinational and four sequential ISCAS benchmark circuits. From the energy savings point of view, to operate in MEP results on average reduction of 54.46% and 99.01% when compared with the sub-threshold and nominal supply voltages, respectively. This analysis was performed for 25⁰C and typical process. When considered the performance, the very-wide VFS regime enables maximum operating frequencies varying from hundreds of kHz up to MHz/GHz at -40ºC and 25ºC, and from MHz up to GHz at 125ºC. This master thesis results, when compared with related works, showed on average an energy reduction and performance gain of 24.1% and 152.68%, respectively, for the same circuit benchmarks operating with VDD at the minimum energy point (MEP).

Microeletrônica

Cmos

Vlsi

Digital CMOS

Voltage-frequency scaling

CMOS energy-efficiency

Near-threshold

Multi-VT MOSFET transistors

Projeto de células e circuitos VLSI digitais CMOS para operação em baixa tensão / CMOS digital cells and VLSI circuits design for ultra-low voltage operation

Rosa, André Luís Rodeghiero

January 2015

Este trabalho propõe uma estratégia para projeto de circuitos VLSI operando em amplo ajuste de tensão e frequência (VFS), desde o regime em Near-threshold, onde uma tensão de VDD caracteriza-se por permitir o funcionamento do circuito com o mínimo dispêndio de energia por operação (MEP), até tensões nominais, dependendo da carga de trabalho exigida pela aplicação. Nesta dissertação é proposto o dimensionamento de transistores para três bibliotecas de células utilizando MOSFETs com tensões de limiar distintas: Regular-VT (RVT), High-VT (HVT) e Low-VT (LVT). Tais bibliotecas possuem cinco células combinacionais: INV, NAND, NOR, OAI21 e AOI22 em múltiplos strengths. A regra para dimensionamento dos transistores das células lógicas foi adaptada de trabalhos relacionados, e fundamenta-se na equalização dos tempos de subida e descida na saída de cada célula, objetivando à redução dos efeitos de variabilidade em baixas tensões de operação. Dois registradores também foram incluídos na biblioteca RVT e sua caracterização foi realizada considerando os parâmetros de processo CMOS 65 nm typical, fast e slow; nas temperaturas de operação de -40°C, 25°C e 125°C, e para tensões variando de 200 mV até 1,2V, para incluir a região de interesse, próxima ao MEP. Os experimentos foram realizados utilizando dez circuitos VLSI de teste: filtro digital notch, um núcleo compatível com o micro-controlador 8051, quatro circuitos combinacionais e quatro sequenciais do benchmark ISCAS. Em termos de economia de energia, operar no MEP resulta em uma redução média de 54,46% em relação ao regime de sub-limiar e até 99,01% quando comparado com a tensão nominal, para a temperatura de 25°C e processo típico. Em relação ao desempenho, operar em regime de VFS muito amplo propicia frequências máximas que variam de centenas de kHz até a faixa de centenas de MHz a GHz, para as temperaturas de -40°C e 25°C, e de MHz até GHz em 125°C. Os resultados desta dissertação, quando comparados a trabalhos relacionados, demonstraram, em média, redução de energia e ganho de desempenho de 24,1% e 152,68%, respectivamente, considerando os mesmos circuitos de teste, operando no ponto de mínima energia (MEP). / This work proposes a strategy for designing VLSI circuits to operate in a very-wide Voltage-Frequency Scaling (VFS) range , from the supply voltage at which the minimum energy per operation (MEP) is achieved, at the Near-Threshold regime, up to the nominal supply voltage for the processes, if so demanded by applications workload. This master thesis proposes the sizing of transistors for three library cells using MOSFETs with different threshold voltages: Regular-VT (RVT), High-VT (HVT), and Low-VT (LVT). These libraries have five combinational cells: INV, NAND, NOR, OAI21, and AOI22 with multiple strengths. The sizing rule for the transistors of the digital cells was an adapted version from related works and it is directly driven by requiring equal rise and fall times at the output for each cell in order to attenuate variability effects in the low supply voltage regime. Two registers were also included in the RVT library cell. This library cell was characterized for typical, fast, and slow processes conditions of a CMOS 65nm technology; for operation at -40ºC, 25ºC, and 125ºC temperatures, and for supply voltages varying from 200 mV up to 1.2V, to include the region of interest, for VDD near the MEP. Experiments were performed with ten VLSI circuit benchmarks: notch filter, 8051 compatible core, four combinational and four sequential ISCAS benchmark circuits. From the energy savings point of view, to operate in MEP results on average reduction of 54.46% and 99.01% when compared with the sub-threshold and nominal supply voltages, respectively. This analysis was performed for 25⁰C and typical process. When considered the performance, the very-wide VFS regime enables maximum operating frequencies varying from hundreds of kHz up to MHz/GHz at -40ºC and 25ºC, and from MHz up to GHz at 125ºC. This master thesis results, when compared with related works, showed on average an energy reduction and performance gain of 24.1% and 152.68%, respectively, for the same circuit benchmarks operating with VDD at the minimum energy point (MEP).

Microeletrônica

Cmos

Vlsi

Digital CMOS

Voltage-frequency scaling

CMOS energy-efficiency

Near-threshold

Multi-VT MOSFET transistors