Progetto e realizzazione di riferimenti in tensione simmetrici in tecnologia CMOS

La tesi tratta del progetto e della realizzazione di un riferimento in tensione simmetrico e stabile in temperatura, realizzato in tecnologia CMOS. Nella progettazione analogica ad alta precisione ha assunto sempre più importanza il problema della realizzazione di riferimenti in tensione stabili in temperatura. Nella maggior parte dei casi vengono presentati Bandgap, ovvero riferimenti in tensione che sfruttano l'andamento in temperatura dell'energy gap del silicio al fine di ottenere una tensione costante in un ampio range di temperatura. Tale architettura risulta utile nei sistemi ad alimentazione singola compresa fra 0 e Vdd essendo in grado di generare una singola tensione di riferimento del valore tipico di 1.2V. Nella tesi viene presentato un riferimento in tensione in grado di offrire le stesse prestazioni di un Bandgap per quanto riguarda la variazione in temperatura ma in grado di lavorare sia in sistemi ad alimentazione singola che ad alimentazione duale. Il circuito proposto e' in grado di generare due tensioni, simmetriche rispetto a un riferimento dato, del valore nominale di ±450mV. All'interno della tesi viene descritto il progetto di due diverse architetture, entrambe in grado di generare le tensioni con le specifiche richieste. Le due architetture sono poi state confrontate analizzando in particolare la stabilità in temperatura, la potenza dissipata, il PSRR (Power Supply Rejection Ratio) e la simmetria delle tensioni generate. Al termine dell'analisi è stato poi implementato su silicio il circuito che garantiva le prestazioni migliori. In sede di disegno del layout su silicio sono stati affrontati i problemi derivanti dall'adattamento dei componenti al fine di ottenere una maggiore insensibilità del circuito stesso alle incertezze legate al processo di realizzazione. Infine sono state effettuate le misurazioni attraverso una probe station a 4 sonde per verificare il corretto funzionamento del circuito e le sue prestazioni.

Sensori resistivi per un microsistema di monitoraggio ambientale

Panoramica sui sensori resistivi, scelta di alcuni di essi per un progetto di monitoraggio ambientale, e poi realizzazione del PCB con i sensori.

Implementation of a VLSI amplifier interfaced with biomedical sensors for ultra wide band data transmission

This thesis presents a CMOS Amplifier with High Common Mode rejection designed in UMC 130nm technology. The goal is to achieve a high amplification factor for a wide range of biological signals (with frequencies in the range of 10Hz-1KHz) and to reject the common-mode noise signal. It is here presented a Data Acquisition System, composed of a Delta-Sigma-like Modulator and an antenna, that is the core of a portable low-complexity radio system; the amplifier is designed in order to interface the data acquisition system with a sensor that acquires the electrical signal. The Modulator asynchronously acquires and samples human muscle activity, by sending a Quasi-Digital pattern that encodes the acquired signal. There is only a minor loss of information translating the muscle activity using this pattern, compared to an encoding technique which uses astandard digital signal via Impulse-Radio Ultra-Wide Band (IR-UWB). The biological signals, needed for Electromyographic analysis, have an amplitude of 10-100μV and need to be highly amplified and separated from the overwhelming 50mV common mode noise signal. Various tests of the firmness of the concept are presented, as well the proof that the design works even with different sensors, such as Radiation measurement for Dosimetry studies.

Modeling multiple state electrostatically formed nanowire transistors

The present thesis work proposes a new physical equivalent circuit model for a recently proposed semiconductor transistor, a 2-drain MSET (Multiple State Electrostatically Formed Nanowire Transistor). It presents a new software-based experimental setup that has been developed for carrying out numerical simulations on the device and on equivalent circuits. As of 2015, we have already approached the scaling limits of the ubiquitous CMOS technology that has been in the forefront of mainstream technological advancement, so many researchers are exploring different ideas in the realm of electrical devices for logical applications, among them MSET transistors. The idea that underlies MSETs is that a single multiple-terminal device could replace many traditional transistors. In particular a 2-drain MSET is akin to a silicon multiplexer, consisting in a Junction FET with independent gates, but with a split drain, so that a voltage-controlled conductive path can connect either of the drains to the source. The first chapter of this work presents the theory of classical JFETs and its common equivalent circuit models. The physical model and its derivation are presented, the current state of equivalent circuits for the JFET is discussed. A physical model of a JFET with two independent gates has been developed, deriving it from previous results, and is presented at the end of the chapter. A review of the characteristics of MSET device is shown in chapter 2. In this chapter, the proposed physical model and its formulation are presented. A listing for the SPICE model was attached as an appendix at the end of this document. Chapter 3 concerns the results of the numerical simulations on the device. At first the research for a suitable geometry is discussed and then comparisons between results from finite-elements simulations and equivalent circuit runs are made. Where points of challenging divergence were found between the two numerical results, the relevant physical processes are discussed. In the fourth chapter the experimental setup is discussed. The GUI-based environments that allow to explore the four-dimensional solution space and to analyze the physical variables inside the device are described. It is shown how this software project has been structured to overcome technical challenges in structuring multiple simulations in sequence, and to provide for a flexible platform for future research in the field.