Development of CMOS-Compatible, Microwave-Assisted Solution Processing of Nanostructured Zine Ferrite Films for Gigahertz Circuits

Sai, Ranajit

January 2013

The development of radio frequency integrated circuits (RFICs), especially the dream of integrating analog, digital and radio frequency (RF) components on the same chip that is commonly known as System-on-a-Chip (SoC), is crucial to mobile communications of the future. Such SoC approach offers enhanced performance, greater reliability, and substantially less power consumption of integrated circuits while reducing overall physical size and thus manufacturing cost. However, the progress has been stalled by the lack of miniaturized inductor elements. Rise of unwanted parasitic effects limits down-scaling of the inductor structures and leaves the use of magnetic coating as a viable and attractive option to enhance the inductance and thus inductance density. It is also essential to shift from perm alloy and other amorphous alloys to ferrites and hex ferrites as the core material because of their very high electrical resistivity so as to keep losses in check, a criterion that cannot be compromised on in GHz frequency applications. This is viable, however, only if the integration of the magnetic core (film), particularly a ferrite film, is fully compatible with the CMOS fabrication process. Various approaches have been taken to meet this requirement, including investigations of employing layers of ferrite materials to envelop the inductor loop. However, the deposition of thin films of ferrites, whether by PVD or CVD, usually calls for the deposited ferrite layer to be annealed at an elevated temperature to crystallize the layer so that its magnetic characteristics are appropriate for the optimum performance of the circuit element. Such annealing is incompatible with CMOS process flow required for aggressive device geometries, as the inductor element is added after the active semiconductor circuit is processed, and any exposure of the processed circuit to elevated temperatures risks disturbing precise doping profiles employed and the integrity of the inter-layer dielectrics. What is called for is a low-temperature process for the deposition of a ferrite layer on top of the patterned inductor element – a layer of thickness such that most of the fringe field is encapsulated – while ensuring that the layer comprises crystallites of uniform size that leads to uniform magnetic behaviour. Recognizing the difficulty of meeting the various stringent requirements, it has recently been remarked that such a goal is a formidable challenge. In an attempt to address this challenge, in this work, we have adopted a counter-intuitive approach - the deposition of the desired ferrite composition on a processed die (that contains the inductor structures along with active semiconductor circuits) by immersing it into a chemical (reactant) solution, followed by a brief irradiation of microwave frequency. However, to identify the desired ferrite composition and the appropriate recipe to deposit them, a systematic effort had to be made first, to understand the inter-relationship between synthesis process, structure of resulting material, and its physical and chemical properties. Therefore, at the beginning, a general introduction in which key concepts related to the magnetic-core inductors, the microwave-irradiation-assisted synthesis of nanostructures, the ‗state of the art‘ in the field of integration of appropriate magnetic material to the RFICs, are all outlined. As a proof of concept, microwave-irradiation-assisted solution-based deposition of zinc ferrite thin films on the technologically important Si (100) substrate is demonstrated. The highlight of the process is the use of only non-toxic metal organic precursors and aqua-alcoholic solvents for the synthesis, which is complete in 10 minutes @< 100 °C, without any poisonous by-products. Effects of various process parameters such as solute concentrations, surfactant types, and their concentrations are investigated. A wide range of deposition rates (10 - 2000 nm/min) has been achieved by tweaking the process parameters. The simultaneous formation of zinc ferrite nanocrystallites (ZFNC) along with deposition of thin film is the hallmark of this synthesis technique. Unlike its bulk counterpart, both film and powder are found upon investigation to be rich in magnetic behavior– owing to plausible cationic distribution in the crystal lattice, induced by the inherently quick and far-from-equilibrium nature of the process. The accurate estimation of magnetic characteristics in film is, however, found to be difficult due to the high substrate-to-film mass ratio. The simultaneously prepared ZFNC is examined to arrive at the optimized process recipe that imparts the desired magnetic properties to the zinc ferrite system. The crystallographic cationic distribution in zinc ferrite powder is, however, difficult to study due to the nanoscale dimension of the as prepared material. To enable crystal growth, slow and rapid annealing in air at two different temperatures are employed. The effects of these annealing schemes on various attributes (magnetic properties in particular) are studied. Rapid annealing turns out to be an interesting pathway to promote rapid grain-growth without disturbing the crystallographic site occupancies. The presence of inversion, i.e., the amount of Fe3+ in the ‗A‘-sites in the spinel structure that ideally is zero in normal spinel structure of zinc ferrite, is evident in all annealed ZFNC, as determined by Riveted analysis. Such partially inverted ZFNC exhibits soft magnetic behavior with high saturation magnetization, which can easily be ―tuned‖ by choosing appropriate annealing conditions. However, a few unique strategic modifications to the same microwave-irradiation-assisted solution-based synthesis technique are tried for the formation of nanocrystalline powder with desired sizes and properties without the necessity of anneal. The approach eventually appears to pave a way for the formation of oriented structures of zinc ferrite. The effects of anneal, nevertheless, are studied with the help of neutron powder diffractometry and magnetic measurements. The magnetic ordering at various temperatures is analyzed and connected to the magnetic measurements. The study shows that long-range magnetic ordering, present even at room temperate, originates from the distribution of cations in the partially inverted spinel structures, induced by the rapid and kinetically driven microwave synthesis. Keeping the mild nature (<200 °C) of the processing in mind, a large degree of inversion (~0.5) is a surprise and results in a very high saturation magnetization, as much as 30 emu/g at room temperature (paramagnetic in bulk), in the ZFNC system. Based on the knowledge of process-structure-property interrelationship, a recipe for the deposition of ferrite thin films by the microwave-assisted deposition technique is optimized. Successful deposition of smooth and uniform zinc ferrite thin films on various substrates is, then, demonstrated. The mystery behind the strong adherence of the film to the substrate - an unexpected outcome of a low-temperature process - is probed by XPS and the formation of silicates at the interface is identified as the probable reason. The uniformity and consistency of film composition is also examined in this chapter. Another salient feature of the process is its capability to coat any complex geometry conformally, allowing the possibility of depositing the material in a way to ―wrap around‖ the three-dimensional inductor structures of RF-CMOS. Integration of nanostructure zinc ferrite thin films onto on-chip spiral inductor structures has been demonstrated successfully. The magnetic-core inductors so obtained exhibit the highest inductance density (700 nH/mm2) and the highest Q factor (~20), reported to date, operate at 5 GHz and above, by far the highest reported to date. An increase in inductance density of as much as 20% was achieved with the use of just 1 µm thick film of zinc ferrite covering only the ―top‖ of the spiral structure, i.e., up to 20% of chip real estate can potentially be freed to provide additional functionality. The microwave-assisted solution-based deposition process described in this thesis is meant for ‗post-CMOS‘ processing, wherein the film deposited on some specific electronic components can add desired functionality to or improve the performance of a component (circuit) underneath. However, the effect of such ‗post-CMOS‘ processing on the active MOS devices, interconnects, and even inter-layer-dielectrics fabricated prior to the deposition has to be mild enough to leave the performance of delicate MOS characteristics intact. Such CMOS-compatibility of the present deposition process has been tested with a satisfactorily positive result.

Radio Frequency Inductors

Nanostructured Zinc Ferrite Thin Films

Gigahertz Circuits

Nanocrystalline Zinc Ferrite

Zinc Ferrite Thin Film

ZnFe2O4

Zinc Ferrite Nanocrystals

Integrated Circuits

Zinc Ferrite Films

Nanotechnology

Study of Low-Temperature Effects in Silicon-Germanium Heterojunction Bipolar Transistor Technology

Ahmed, Adnan

19 July 2005

This thesis investigates the effects of low temperatures on Silicon Germanium (SiGe) Hterojunction Bipolar Transistors (HBT) BiCMOS technology. A comprehensive set of dc measurements were taken on first, second, third and fourth generation IBM SiGe technology over a range of temperatures (room temperature to 43K for first generation, and room temperature to 15K for the rest). This work is unique in the sense that this sort of comprehensive study of dc characteristics on four SiGe HBT technology generations over a wide range of temperatures has never been done before to the best of the authors knowledge.

Heterojunction

HBT

Low-temperature

DC characteristics

SiGe

Silicon-germanium

Technology generation

Static characteristics

Cryogenic

Scaling

Silicon alloys Effect of temperature on

Germanium Effect of temperature on

Heterojunctions Effect of temperature on

Low temperature engineering

Systematic Analysis of the Small-Signal and Broadband Noise Performance of Highly Scaled Silicon-Based Field-Effect Transistors

Venkataraman, Sunitha

17 May 2007

The objective of this work is to provide a comprehensive analysis of the small-signal and broadband noise performance of highly scaled silicon-based field-effect transistors (FETs), and develop high-frequency noise models for robust radio frequency (RF) circuit design. An analytical RF noise model is developed and implemented for scaled Si-CMOS devices, using a direct extraction procedure based on the linear two-port noise theory. This research also focuses on investigating the applicability of modern CMOS technologies for extreme environment electronics. A thorough analysis of the DC, small-signal AC, and broadband noise performance of 0.18 um and 130 nm Si-CMOS devices operating at cryogenic temperatures is presented. The room temperature RF noise model is extended to model the high-frequency noise performance of scaled MOSFETs at temperatures down to 77 K and 10 K. Significant performance enhancement at cryogenic temperatures is demonstrated, indicating the suitability of scaled CMOS technologies for low temperature electronics. The hot-carrier reliability of MOSFETs at cryogenic temperatures is investigated and the worst-case gate voltage stress condition is determined. The degradation due to hot-carrier-induced interface-state creation is identified as the dominant degradation mechanism at room temperature down to 77 K. The effect of high-energy proton radiation on the DC, AC, and RF noise performance of 130 nm CMOS devices is studied. The performance degradation is investigated up to an equivalent total dose of 1 Mrad, which represents the worst case condition for many earth-orbiting and planetary missions. The geometric scaling of MOSFETs has been augmented by the introduction of novel FET designs, such as the Si/SiGe MODFETs. A comprehensive characterization and modeling of the small-signal and high-frequency noise performance of highly scaled Si/SiGe n-MODFETs is presented. The effect of gate shot noise is incorporated in the broadband noise model. SiGe MODFETs offer the potential for high-speed and low-voltage operation at high frequencies and hence are attractive devices for future RF and mixed-signal applications. This work advances the state-of-the-art in the understanding and analysis of the RF performance of highly scaled Si-CMOS devices as well as emerging technologies, such as Si/SiGe MODFETs. The key contribution of this dissertation is to provide a robust framework for the systematic characterization, analysis and modeling of the small-signal and RF noise performance of scaled Si-MOSFETs and Si/SiGe MODFETs both for mainstream and extreme-environment applications.

RF measurements

Extreme environment electronics

Proton radiation tolerance

Silicon

Scaled CMOS

Modeling

Sub-circuit model

Hot-carrier degradation

Cryogenic performance

SiGe MODFET

Short-channel FETs

RF noise

Field-effect transistors

Radio frequency

Extreme environments

Low-cost SiGe circuits for frequency synthesis in millimeter-wave devices

Lauterbach, Adam Peter

January 2010

"2009" / Thesis (MSc (Hons))--Macquarie University, Faculty of Science, Dept. of Physics and Engineering, 2010. / Bibliography: p. 163-166. / Introduction -- Design theory and process technology -- 15GHz oscillator implementations -- 24GHz oscillator implementation -- Frequency prescaler implementation -- MMIC fabrication and measurement -- Conclusion. / Advances in Silicon Germanium (SiGe) Bipolar Complementary Metal Oxide Semiconductor (BiCMOS) technology has caused a recent revolution in low-cost Monolithic Microwave Integrated Circuit (MMIC) design. -- This thesis presents the design, fabrication and measurement of four MMICs for frequency synthesis, manufactured in a commercially available IBM 0.18μm SiGe BiCMOS technology with ft = 60GHz. The high speed and low-cost features of SiGe Heterojunction Bipolar Transistors (HBTs) were exploited to successfully develop two single-ended injection-lockable 15GHz Voltage Controlled Oscillators (VCOs) for application in an active Ka-Band antenna beam-forming network, and a 24GHz differential cross-coupled VCO and 1/6 synchronous static frequency prescaler for emerging Ultra Wideband (UWB) automotive Short Range Radar (SRR) applications. -- On-wafer measurement techniques were used to precisely characterise the performance of each circuit and compare against expected simulation results and state-of-the-art performance reported in the literature. -- The original contributions of this thesis include the application of negative resistance theory to single-ended and differential SiGe VCO design at 15-24GHz, consideration of manufacturing process variation on 24GHz VCO and prescaler performance, implementation of a fully static multi-stage synchronous divider topology at 24GHz and the use of differential on-wafer measurement techniques. -- Finally, this thesis has llustrated the excellent practicability of SiGe BiCMOS technology in the engineering of high performance, low-cost MMICs for frequency synthesis in millimeterwave (mm-wave) devices. / Mode of access: World Wide Web. / xxii, 166 p. : ill (some col.)

Frequency synthesizers

Millimeter wave devices

Semiconductors

Silicon compounds

Germanium compounds

Bipolar transistor

Metal oxide semiconductors

SiGe

BiCMOS

Voltage Controlled Oscillator (VCO)

Millimeter-wave (mm-wave)

Short Range Radar (SRR)

frequency prescaler

Desenvolvimento e implementação de chips dedicados para um novo decodificador de códigos corretores de erros baseado em conjuntos de informação

França, Sibilla Batista da Luz

22 August 2013

CAPES / Códigos corretores de erros estão presentes em quase todos os sistemas modernos de comunicação e armazenamento de dados. Erros durante essas operações são praticamente inevitáveis devido a ruído e interferências nos meios de comunicação e degradação dos meios de armazenamento. Quando um sistema exige alto desempenho, os correspondentes algoritmos (codificador e decodificador) são implementados em hardware. O projeto de pesquisa apresentado nesta tese, um chip dedicado para uma nova família de decodificadores baseados em conjuntos de informação, é parte de um amplo projeto que visa obter um decodificador com desempenho semelhante à decodificação de máxima verossimilhança (MLD), porém com hardware muito mais simples, demonstrando assim que o uso dessa técnica (decodificação por conjuntos de informação), até então proibitiva devido à complexidade do hardware, poderia tornar-se viável. Visando simplificar o hardware, o primeiro passo foi modificar o algoritmo original de Dorsch para reduzir o número de ciclos de clock necessários para decodificar uma mensagem. As principais modificações realizadas foram na redução de Gauss-Jordan e no número de palavras-código candidatas, consideravelmente reduzidas em relação ao algoritmo original de Dorsch. Este algoritmo modificado foi primeiramente implementado utilizando linguagem de descrição de hardware e avaliado em diferentes famílias de FPGAs, onde demonstrou-se o mesmo ser viável, mesmo para grandes códigos. O algoritmo foi implementado posteriormente em um chip dedicado (ASIC), utilizando tecnologia CMOS, a fim de completar a demonstração da viabilidade de sua implementação e uso efetivo. / Error-correcting codes are present in almost all modern data communications and data storage systems. Errors during these operations are practically inevitable because of noise and interference in communication channels and degradation of storage media. When topperformance is required, the corresponding algorithms (encoder and decoder) are implemented in hardware. The research project presented in this dissertation, a dedicated chip for a new family of decoders based on information sets, is part of a broad project targeting the development of a new decoder capable of achieving near maximum likelihood decoding (MLD) performance, however with a much simpler hardware, thus demonstrating that the use of this technique (decoding based on information sets), previously prohibitive due to the complexity of the hardware, could now be feasible. Aiming to simplify the hardware, the first step was to modify the original Dorsch algorithm to reduce the number of clock cycles needed to decode a message. The main modifications performed were in the Gauss Jordan elimination procedure and in the number of candidate codewords, which was highly reduced with respect to original Dorsch algorithm. This modified algorithm was first implemented using a hardware description language and evaluated in different FPGA families, where the viability was demonstrated. The algorithm was later implemented in a dedicated chip (ASIC) using CMOS technology in order to complete the demonstration of the feasibility of their implementation, and effective use.

Decodificadores (Eletrônica)

Decoders (Electronics)

Field programmable gate arrays

Desenvolvimento e implementação de chips dedicados para um novo decodificador de códigos corretores de erros baseado em conjuntos de informação

França, Sibilla Batista da Luz

22 August 2013

CAPES / Códigos corretores de erros estão presentes em quase todos os sistemas modernos de comunicação e armazenamento de dados. Erros durante essas operações são praticamente inevitáveis devido a ruído e interferências nos meios de comunicação e degradação dos meios de armazenamento. Quando um sistema exige alto desempenho, os correspondentes algoritmos (codificador e decodificador) são implementados em hardware. O projeto de pesquisa apresentado nesta tese, um chip dedicado para uma nova família de decodificadores baseados em conjuntos de informação, é parte de um amplo projeto que visa obter um decodificador com desempenho semelhante à decodificação de máxima verossimilhança (MLD), porém com hardware muito mais simples, demonstrando assim que o uso dessa técnica (decodificação por conjuntos de informação), até então proibitiva devido à complexidade do hardware, poderia tornar-se viável. Visando simplificar o hardware, o primeiro passo foi modificar o algoritmo original de Dorsch para reduzir o número de ciclos de clock necessários para decodificar uma mensagem. As principais modificações realizadas foram na redução de Gauss-Jordan e no número de palavras-código candidatas, consideravelmente reduzidas em relação ao algoritmo original de Dorsch. Este algoritmo modificado foi primeiramente implementado utilizando linguagem de descrição de hardware e avaliado em diferentes famílias de FPGAs, onde demonstrou-se o mesmo ser viável, mesmo para grandes códigos. O algoritmo foi implementado posteriormente em um chip dedicado (ASIC), utilizando tecnologia CMOS, a fim de completar a demonstração da viabilidade de sua implementação e uso efetivo. / Error-correcting codes are present in almost all modern data communications and data storage systems. Errors during these operations are practically inevitable because of noise and interference in communication channels and degradation of storage media. When topperformance is required, the corresponding algorithms (encoder and decoder) are implemented in hardware. The research project presented in this dissertation, a dedicated chip for a new family of decoders based on information sets, is part of a broad project targeting the development of a new decoder capable of achieving near maximum likelihood decoding (MLD) performance, however with a much simpler hardware, thus demonstrating that the use of this technique (decoding based on information sets), previously prohibitive due to the complexity of the hardware, could now be feasible. Aiming to simplify the hardware, the first step was to modify the original Dorsch algorithm to reduce the number of clock cycles needed to decode a message. The main modifications performed were in the Gauss Jordan elimination procedure and in the number of candidate codewords, which was highly reduced with respect to original Dorsch algorithm. This modified algorithm was first implemented using a hardware description language and evaluated in different FPGA families, where the viability was demonstrated. The algorithm was later implemented in a dedicated chip (ASIC) using CMOS technology in order to complete the demonstration of the feasibility of their implementation, and effective use.

Decodificadores (Eletrônica)

Decoders (Electronics)

Field programmable gate arrays

Optimization of HfO2 Thin Films for Gate Dielectric Applications in 2-D Layered Materials

Ganapathi, K Lakshmi

January 2014

Recently, high-κ materials have become the focus of research and been extensively utilized as the gate dielectric layer in aggressive scaled complementary metal-oxide-semiconductor (CMOS) technology. Hafnium dioxide (HfO2) is the most promising high-κ material because of its excellent chemical, thermal, mechanical and dielectric properties and also possesses good thermodynamic stability and better band offsets with silicon. Hence, HfO2 has already been used as gate dielectric in modern CMOS devices. For future technologies, it is very difficult to scale the silicon transistor gate length, so it is a necessary requirement of replacing the channel material from silicon to some high mobility material. Two-dimensional layered materials such as graphene and molybdenum disulfide (MoS2) are potential candidates to replace silicon. Due to its planar structure and atomically thin nature, they suit well with the conventional MOSFET technology and are very stable mechanically as well as chemically. HfO2 plays a vital role as a gate dielectric, not only in silicon CMOS technology but also in future nano-electronic devices such as graphene/MoS2 based devices, since high-κ media is expected to screen the charged impurities located in the vicinity of channel material, which results in enhancement of carrier mobility. So, for sustenance and enhancement of new technology, extensive study of the functional materials and its processing is required. In the present work, optimization of HfO2 thin films for gate dielectric applications in Nano-electronic devices using electron beam evaporation is discussed. HfO2 thin films have been optimized in two different thickness regimes, (i) about 35 nm physical thicknesses for back gate oxide graphene/MoS2 transistors and (ii) about 5 nm physical thickness to get Equivalent Oxide Thickness (EOT) less than 1 nm for top gate applications. Optical, chemical, compositional, structural and electrical characterizations of these films have been done using Ellipsometry, X-ray Photoelectron Spectroscopy (XPS), Rutherford Back Scattering (RBS), X-ray Diffraction (XRD), Capacitance-Voltage and Current-Voltage characterization techniques. The amount of O2 flow rate, during evaporation is optimized for 35 nm thick HfO2 films, to achieve the best optical, chemical and electrical properties. It has been observed that with increasing oxygen flow rate, thickness of the films increased and refractive index decreased due to increase in porosity resulting from the scattering of the evaporant. The films deposited at low O2 flow rates (1 and 3 SCCM) show better optical and compositional properties. The effects of post deposition annealing (PDA) and post metallization annealing (PMA) in forming gas ambient (FGA) on the optical and electrical properties of the films have been analyzed. The film deposited at 3 SCCM O2 flow rate shows the best properties as measured on MOS capacitors. A high density film (ρ=8.2 gram/cm3, 85% of bulk density) with high dielectric constant of κ=19 and leakage current density of J=2.0×10-6 A/cm2 at -1 MV/cm has been achieved at optimized deposition conditions. Bilayer graphene on HfO2/Si substrate has been successfully identified and also transistor has been fabricated with HfO2 (35 nm) as a back gate. High transconductance compared to other back gated devices such as SiO2/Si and Al2O3/Si and high mobility have been achieved. The performance of back gated bilayer graphene transistors on HfO2 films deposited at two O2 flow rates of 3 SCCM and 20 SCCM has been evaluated. It is found that the device on the film deposited at 3 SCCM O2 flow rate shows better properties. This suggests that an optimum oxygen pressure is necessary to get good quality films for high performance devices. MoS2 layers on the optimized HfO2/Si substrate have been successfully identified and transistor has been fabricated with HfO2 (32 nm) as a back gate. The device is switching at lower voltages compared to SiO2 back gated devices with high ION/IOFF ratio (>106). The effect of film thickness on optical, structural, compositional and electrical properties for top gate applications has been studied. Also the effect of gate electrode material and its processing on electrical properties of MOS capacitors have been studied. EOT of 1.2 nm with leakage current density of 1×10-4 A/cm2 at -1V has been achieved.

Hafnium Dioxide Thin Films

High-K Materials

Gate Dielectric

High-K Gate Dielectric

HfO2 Gate Dielectrics

Dielectric Thin Films

HfO2 Back Gated Graphene Transistors

HfO2 Back Gated MoS2 Transistors

Dielectrics

Metal-Oxide Semiconductor Transistors

HfO2 Thin Films

2-D lLyered Materials

Instrumentation and Applied Physics

Exploration of Displacement Detection Mechanisms in MEMS Sensors

Thejas, *

January 2015

MEMS Sensors are widely used for sensing inertial displacements. The displacements arising out of acceleration /Coriolis effect are typically in the range of 1 nm-1 m. This work investigates the realization of high resolution MEMS inertial sensors using novel displacement sensing mechanisms. Capacitance sensing ASIC is developed as part of conventional electronics interface with MEMS sensor under the conventional CMOS-MEMS integration strategy. The capacitance sense ASIC based on Continuous Time Voltage scheme with coherent and non-coherent demodulation is prototyped on AMS 0.35 m technology. The ASIC was tested to sense C = 3.125 fF over a base of 2 pF using on-chip built-in test capacitors. Dynamic performance of this ASIC was validated by interfacing with a DaCM MEMS accelerometer. 200milli-g of acceleration (equivalent to a C = 2.8 fF) over an input frequency of 20Hz is measurable using the developed ASIC. The observed sensitivity is 90mV/g. The ASIC has several programmable features such as variation in trim capacitance (3.125 fF-12.5 pF), bandwidth selection (500 Hz-20 kHz) and variable gain options (2-100). Capacitance detection, a dominant sensing principle in MEMs sensors, experiences inherent limitation due to the role of parasitics when the displacements of interest are below 5 nm range. The capacitive equivalence ( C) for the range of displacements of the order of 5 nm and below would vary in the range atto-to-zepto farad. Hence there is a need to explore alternative sensing schemes which preferably yield higher sensitivity (than those offered by the conventional integration schemes) and are based on the principle of built-in transduction to help overcome the influence of parasitics on sensitivity. In this regard, 3 non-conventional architectures are explored which fall under the direct integration classification namely: (a) Sub-threshold based sensing (b) Fringe field based sensing and (c) Tunneling current based sensing. a) In Sub-threshold based sensing, FET with a suspended gate is used for displacement sensing. The FET is biased in the sub-threshold region of operation. The exponential modulation of drain current for a change in displacement of 1 nm is evaluated using TCAD, and the in uence of initial air-gap variation on the sensitivity factor ( ID=ID) is brought out. For 1% change in air gap displacement (i.e., TGap/TGap, the gap variation resulting due to the inertial force / mass loading) nearly 1050% change in drain current( ID=ID) is observed (considering initial air gaps of the order 100 nm). This validates the high sensitivity offered by the device in this regime of operation. A comparison of sensitivity estimate using the capacitive equivalence model and TCAD simulated model for different initial air-gaps in a FD-SOI FET is brought out. The influence of FDSOI FET device parameters on sensitivity, namely the variation of TSi, TBox, NA and TGap are explored. CMOS compatibility and fabrication feasibility of this architecture was looked into by resorting to the post processing approach used for validating the sub-threshold bias concept. The IMD layers of the Bulk FETs fabricated through AMS 0.35 technology were etched using BHF and IPA mixture to result in a free standing metal (Al) layers acting as the suspended gate. The performance estimate is carried out considering specific Equivalent Gap Thickness (EGT) of 573 nm and 235 nm, to help overcome the role of coupled electrostatics in influencing the sensitivity metric. The sensitivity observed by biasing this post processed bulk FET in sub-threshold is 114% ( ID=ID change) for a 59% ( d/d change). The equivalent C in this case is 370 aF. b) In Fringe eld based sensing approach, a JunctionLess FET (JLFET) is used as a depletion mode device and an out-of-plane gate displacement would help modulate the device pinch-o voltage due to fringe field coupling. The resulting change in the gate fringe field due to this displacement modulates the drain current of the JunctionLess FET. The displacement induced fringe field change (relative to the FET channel) brings about a distinct shift in the ID-VG characteristics of the JLFET. For displacement d = 2 nm, the JLFET with a channel doping of ND = 8X1018cm 3 and a bias point of VG = -47.7 V, 98% enhancement in sensitivity is observed in 3D TCAD simulations. The equivalent C in this case is 29 zF. The role of ground-planes in the device operation is explored. c) In the tunneling current based sensing approach, the beams fabricated using the SOI-MUMPS process are FIB milled so as to create very ne air gaps of the order of nearly 85 nm. Under high electric fields of the order > 8 MV/cm, the lateral displacement based tunneling sensor offers enhanced change in sensitivity for an induced external force at a fixed DC bias. When integrated as an array with varying electrode overlap, this technique can track displacements over a wide range. With the initial beam overlap as 1.2 m, for a lateral displacement of 1.2 m, a 100% change in sensitivity ( ID=ID) is observed. The effect of fringe field can be completely neglected here unlike its capacitive beam equivalent.

Micro Eletro Mechanical Systems Sensors

Inertial Sensors

Interface Circuits

Fringe Field Sensors

Capacitive Sensors

Electromechanical Sensing

Sub-threshold Field Effect Transistors

Gyro Field Effect Transistors

Displacement Sensing

Tunneling Sensors

MEMS Sensors

GyroFET

Displacement Sensor

FET Sensor

Capacitance Sensor

Electrical Communication Engineering

Low-power ASIC design with integrated multiple sensor system

Jafarian, Hossein

08 1900

Indiana University-Purdue University Indianapolis (IUPUI) / A novel method of power management and sequential monitoring of several sensors is proposed in this work. Application specific integrated circuits (ASICs) consisting of analog and digital sub-systems forming a system on chip (SoC) has been designed using complementary metal-oxide-semiconductor (CMOS) technology. The analog sub-system comprises the sensor-drivers that convert the input voltage variations to output pulse-frequency. The digital sub-system includes the system management unit (SMU), counter, and shift register modules. This performs the power-usagemanagement, sensor-sequence-control, and output-data-frame-generation functions. The SMU is the key unit within the digital sub-system is that enables or disables a sensor. It captures the pulse waves from a sensor for 3 clocks out of a 16-clock cycle, and transmits the signal to the counter modules. As a result, the analog sub-system is at on-state for only 3/16th fraction (18 %) of the time, leading to reduced power consumption. Three cycles is an optimal number selected for the presented design as the system is unstable with less than 3 cycles and higher clock cycles results in increased power consumption. However, the system can achieve both higher sensitivity and better stability with increased on-state clock cycles. A current-starved-ring-oscillator generates pulse waves that depend on the sensor input parameter. By counting the number of pulses of a sensor-driver in one clock cycle, a sensor input parameter is converted to digital. The digital sub-system constructs a 16-bit frame consisting of 8-bit sensor data, start and stop bits, and a parity bit. Ring oscillators that drive capacitance and resistance-based sensors use an arrangement of delay elements with two levels of control voltages. A bias unit which provides these two levels of control voltages consists of CMOS cascade current mirror to maximize voltage swing for control voltage level swings which give the oscillator wider tuning range and lower temperature induced variations. The ring oscillator was simulated separately for 250 nm and 180 nm CMOS technologies. The simulation results show that when the input voltage of the oscillator is changed by 1 V, the output frequency changes linearly by 440 MHz for 180 nm technology and 206 MHz for 250 nm technology. In a separate design, a temperature sensitive ring oscillator with symmetrical load and temperature dependent input voltage was implemented. When the temperature in the simulation model was varied from -50C to 100C the oscillator output frequency reduced by 510 MHz for the 250 nm and by 810 MHz for 180 nm CMOS technologies, respectively. The presented system does not include memory unit, thus, the captured sensor data has to be instantaneously transmitted to a remote station, e.g. end user interface. This may result in a loss of sensor data in an event of loss of communication link with the remote station. In addition, the presented design does not include transmitter and receiver modules, and thus necessitates the use of separate modules for the transfer of the data.

Low-power

Asic design.

Multiple sensor system

Digital electronics

Sensor networks

Voltage-controlled oscillators

Integrated circuits

Analog-to-digital converters

Digital-to-analog converters