Schottky Field Effect Transistors and Schottky CMOS Circuitry

It was the primary goal (and result) of the presented work to empirically demonstrate CMOS operation (i.e., inverter transfer characteristics) using metallic/Schottky source/drain MOSFETs (SFETs - Schottky Field Effect Transistors) fabricated on silicon-on-insulator (SOI) substrates - a first-ever in the history of SFET research. Due to its candidacy for present and future CMOS technology, many different research groups have explored different SFET architectures in an effort to maximize performance. In the presented work, an architecture known as a bulk switching SFET was fabricated using an implant-to-silicide (ITS) technique, which facilitates a high degree of Schottky barrier lowering and therefore an increase in current injection with minimal process complexity. The different switching mechanism realized with this technique also reduces the ambipolar leakage current that has so often plagued SFETs of more conventional design. In addition, these devices have been utilized in a patent pending approach that may facilitate an increase in circuit density for devices of a given size. In other words, for example, it may be possible to achieve circuit density equivalent to 65 nm technology using a 90 nm process, while at the same time preserving or reducing local interconnect density for enhanced overall system speed. Fabrication details and electrical results will be discussed, as well as some initial modeling efforts toward gaining insight into the details of current injection at the metal-semiconductor (M-S) interface. The challenges faced using the ITS approach at aggressive scales will be discussed, as will the potential advantages and disadvantages of other approaches to SFET technology

BiCMOS Millimetre-wave low-noise amplifier

Abstract: Please refer to full text to view abstract.D.Phil. (Electrical and Electronic Engineering

Nonlinear mechanisms in passive microwave devices

Premi extraordinari doctorat curs 2010-2011, àmbit d’Enginyeria de les TICThe telecommunications industry follows a tendency towards smaller devices, higher power and higher frequency, which imply an increase on the complexity of the electronics involved. Moreover, there is a need for extended capabilities like frequency tunable devices, ultra-low losses or high power handling, which make use of advanced materials for these purposes. In addition, increasingly demanding communication standards and regulations push the limits of the acceptable performance degrading indicators. This is the case of nonlinearities, whose effects, like increased Adjacent Channel Power Ratio (ACPR), harmonics, or intermodulation distortion among others, are being included in the performance requirements, as maximum tolerable levels. In this context, proper modeling of the devices at the design stage is of crucial importance in predicting not only the device performance but also the global system indicators and to make sure that the requirements are fulfilled. In accordance with that, this work proposes the necessary steps for circuit models implementation of different passive microwave devices, from the linear and nonlinear measurements to the simulations to validate them. Bulk acoustic wave resonators and transmission lines made of high temperature superconductors, ferroelectrics or regular metals and dielectrics are the subject of this work. Both phenomenological and physical approaches are considered and circuit models are proposed and compared with measurements. The nonlinear observables, being harmonics, intermodulation distortion, and saturation or detuning, are properly related to the material properties that originate them. The obtained models can be used in circuit simulators to predict the performance of these microwave devices under complex modulated signals, or even be used to predict their performance when integrated into more complex systems. A key step to achieve this goal is an accurate characterization of materials and devices, which is faced by making use of advanced measurement techniques. Therefore, considerations on special measurement setups are being made along this thesis.Award-winningPostprint (published version

A 32 mV/69 mV input voltage booster based on a piezoelectric transformer for energy harvesting applications

This paper presents a novel method for battery-less circuit start-up from ultra-low voltage energy harvesting sources. The approach proposes for the first time the use of a Piezoelectric Transformer (PT) as the key component of a step-up oscillator. The proposed oscillator circuit is first modelled from a theoretical point of view and then validated experimentally with a commercial PT. The minimum achieved start-up voltage is about 69 mV, with no need for any external magnetic component. Hence, the presented system is compatible with the typical output voltages of thermoelectric generators (TEGs). Oscillation is achieved through a positive feedback coupling the PT with an inverter stage made up of JFETs. All the used components are in perspective compatible with microelectronic and MEMS technologies. In addition, in case the use of a ∼40 μH inductor is acceptable, the minimum start-up voltage becomes as low as about 32 mV