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Design of Low-Voltage Wide Tuning Range CMOS Multipass Voltage-Controlled Ring OscillatorRen, Jie 23 March 2011 (has links)
This thesis introduces a multipass loop voltage controlled ring oscillator. The proposed structure uses cross-coupled PMOS transistors and replica bias with coarse/fine control signal. The design implemented in TSMC 90 nm CMOS technology, 0.9V power supply with frequency tuning range 481MHz to 4.08GHz and -94.17dBc/Hz at 1MHz offset from 4.08GHz with 26.15mW power consumption.
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Impedance Spectroscopy Systems Suitable for Biomedical Cell Impedance MeasurementHuang, Hao 16 December 2013 (has links)
Impedance spectroscopy (IS) is an important technique for monitoring and detection of biomaterials. In order to enable point-of-care systems, low-cost IS systems capable of rapidly measuring a wide range of biomaterials are required. This thesis presents two IS systems, one in Printed Circuit Board level and the other in Integrated Circuit level.
The board level system is built for preliminary experimental data collection; it is capable of measuring impedance from 1KHz to 100KHz with 200mV signal injection into cell sample. Experimental results show that magnitude and phase error are less than 6.6% and 2.2%, respectively.
An IC level IS front-end is also proposed which utilizes a time-to-digital converter (TDC) and a peak detector circuit (PDC) for quick measurement of both impedance phase and magnitude, respectively. Designed in a 0.18μm CMOS process, the front-end is capable of performing impedance measurements in 6μs at frequencies ranging from 100Hz-10MHz and with a 100Ω-1MΩ dynamic range. Simulation results with cell impedance models show that the system achieves <2.5% magnitude and <2.2 degree phase error. The front-end consumes 28mW total power and occupies 0.4mm^2 area.
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Stochastic Computational Approaches for the Reliability Evaluation of Nanoelectronic CircuitsChen, Hao Unknown Date
No description available.
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Selektive Epitaxie für Quantenbauelemente /Schindler, Markus. January 2006 (has links) (PDF)
Univ. der Bundeswehr, Diss.--München, 2006.
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Orthogonal fluxgate type magnetic microsensors with wide linear operation rangeZorlu, Özge January 2008 (has links)
Zugl.: Lausanne, Ecole Polytechnique Féd., Diss., 2008
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Simulation und Visualisierung elektrischer und optischer Eigenschaften von HalbleiterbauelementenSchneider, Peter. January 1999 (has links)
Heidelberg, Univ., Diplomarbeit, 1998.
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Rotary switch and current monitor by hall-based microsystems /Steiner Vanha, Ralph. January 1999 (has links)
Diss. no. 13135 nat. sc. SFIT Zurich. / Im Buchh.: Zürich : Physical Electronics Laboratory, Swiss Federal Institute of Technology. Literaturverz.
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Analyse und Verhaltensmodellierung des HF-Frontends von passiven CMOS-Transpondern für UHF-RFID-AnwendungenSeemann, Kay. January 2007 (has links) (PDF)
Erlangen, Nürnberg, Univ., Diss., 2007.
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CMOS auf hochohmigem Silizium für integrierte Mikrowellenschaltungen (MMIC)Beck, Dietmar. Unknown Date (has links) (PDF)
Universiẗat, Diss., 1999--Stuttgart.
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Simulation and design methodology for hybrid SET-CMOS logic at room temperature operation / Simulation et méthodologie de conception de circuits logiques hybrides SET-CMOS opérants à température ambianteParekh, Rutu January 2012 (has links)
The purpose of this thesis is to research the possibility of realizing hardware support for hybrid single electron transistor (SET)-CMOS circuits by a systematic approach of design, analysis and simulation. The metallic SET transistors considered in this work are fabricated within the chip interconnect layers using CMOS back-end-of-line (BEOL)-compatible processing. The CMOS process integration can be divided into front-end-of-line (FEOL) and BEOL processes. The FEOL includes processes required to form isolated CMOS transistors whereas BEOL is the second portion of the IC fabrication where the devices get interconnected through the wiring using multiple layers of dielectrics and metals. Therefore, metallic SET circuits can be easily stacked above the CMOS platform presenting a low cost, low thermal budget, improving the overall yield at high-volume production of highly integrated systems. This considerably decreases the interconnect parasitics and increases the density of functions while maintaining the overall acceptable performance. Many problems such as low current drivability, delay and small voltage gain that hinder SET technology for its implementation in integrated circuits can be alleviated by intelligent circuit design. Although a complete replacement of CMOS by SETs is unlikely in the near future, an augmentation of CMOS with SETs is desirable if interfacing from and to CMOS works well. Interfacing from CMOS to SET circuitry is simple as the current and voltage levels are small and in accessible range. But interfacing CMOS from SET circuits is delicate due to SET logic's low current driving capability for CMOS and its interconnect. There is no concrete research on the interface issue wherein a SET-only circuitry drives a CMOS and its interconnects. For such hybridization to become possible, it is necessary to demonstrate the SET logic driving capability for CMOS with sufficient current drive and output voltage. The core SET logic can be designed to operate at low voltage, but at the interface the output of the SET logic must be in a voltage range that can be fed to a CMOS input for proper logic functionality. It is hence necessary to develop and adopt a systematic design methodology for such hybrid circuits at a specific technology node for room temperature operation. In this thesis we will look at a generalized design methodology that can be applied to (a) develop a fabrication model with parasitic effect of a hybrid SET-CMOS and SET-only circuits, (b) design and analyze the SET based fundamental building block in hybrid SET-CMOS or SET-only circuit and (c) simulate such a circuitry to assess its merits. More specifically, we will address the interfacing issue of such hybrid circuits in which we exploit the maximum capability of a SET logic in terms of driving capability, voltage response and power for a room temperature operation. The result of this research motivates the application of SET logic in 2 stages realizing some properties beyond those of CMOS devices. The first stage is the heterogeneous integration at chip level around a CMOS core. In such a circuitry, the SET introduces new functionalities such as reconfigurable logic, random number-based circuits, and multiband filtering circuits that can be combined with CMOS based general purpose processors or I/O signal restoration. The second stage of application is to use a new information processing technology focussed on a "new switch" exploiting a new state variable to provide functional scaling substantially beyond that attainable solely with ultimately scaled CMOS.
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