NFC Sensors Based on Energy Harvesting for IoT Applications

The availability of low-cost near-field communication (NFC) devices, the incorporation of NFC readers into most current mobile phones, and the inclusion of energy-harvesting (EH) capabilities in NFC chips make NFC a key technology for the development of green Internet of Things (IoT) applications. In this chapter, an overview of recent advances in the field of battery-less NFC sensors at 13.56 MHz is provided, and a comparison to other short-range RFID technologies is given. After reviewing power transfer in NFC, recommendations for the practical design of NFC-based sensor tags and NFC readers are made. A list of commercial NFC integrated circuits with energy-harvesting capabilities is also provided. A survey of recent battery-less NFC sensors developed by the group including soil moisture, water content, pH, color, and implanted NFC sensors is done

Development and characterization of subsystems for a 2.45 GHz RFID research environment

Nowadays, the Radio Frequency IDentification (RFID) technology is a very fast emerging and developing technology with a wide range of applications in different fields. Due to the technological progress, the number of applications has increased enormously, leading to the creation of many different standards in several distinct frequency bands for supporting these applications. The majority of this standards are not compatible with each other and moreover, there is not an unique UHF band standard worldwide. For this reason, a possible solution to achieve a compatible RFID system around the world is by means of the 2.45 GHz microwave ISM band. More and more this 2.45 GHz RFID band is considered and currently there are systems working at this frequency. This thesis describes the design and the implementation of a frontend for a 2.45 GHz RFID testbed. Inside the document, relevant RFID basics and the assumed regulations are discussed. The system concept designed is explained and selected elements are tested and optimized. The development of the transmitter and receiver board is described and finally for both boards the characterization and the measurements results are shown

Non-linear shunt regulator based on a PWM RF power detector for RFID applications

Radio Frequency Identification (RFID) is utilized in a variety of applications, includ ing tagging animals and objects to make their identification (ID) easier to read and man age, similar to a bar code or QR code. In this regard, the goal of this research is to improve RFID transponder power regulation in order to increase reader distance. This thesis de scribes a non-linear shunt regulator that employs a Radio Frequency (RF) power detector based on the Pulse Width Modulation (PWM) technique to aim magnetically coupled RFID transponders. A quick voltage-clamp loop and a slow-accurate power detector loop are used in the proposed regulator architecture. The first loop ensures over-voltage pro tection, while the second loop gradually corrects the first loop’s imprecision based on the measured input power. To contextualize the issues and improvements of the new design, the state-of-the-art in RFID power management and RF power detector are covered first. The new architecture is specified after theoretical development, electrical simulations, and the design of the new architecture is implemented. The entire regulator design was prototyped as part of a commercial low-frequency (134 kHz) RFID transponder in a 180 nm CMOS process. The regulator deal with a sinusoidal voltage at its input generated by the LC tank that extracts energy from the reader to supply its circuitry. The use of a 3.3V standard process for the analog circuitry in order to decrease the fabrication cost by not using the high voltage module (5 V for example) complicates the system design. Even though the proposed solution aims to regulate the input voltage precisely at 3.6 V maximum, the maximum voltage supported by 3.3 V standard module using two feedback is achieved. The total RFID transponder area of 870x870 µm² was obtained, with 130x230 µm² related to the regulator circuit area only. Both resonant and supply capacitors are imple mented on the chip. The complete system consumes a maximum current of 4.5 µA, over a wide RF input power range that is modulated by the distance between the reader and the transponder. As the power detector corrects the imprecision of the shunt regulator com posed by simple diodes due to its process, voltage and temperature (PVT), the transponder performance was measured with and without the shunt regulator enabled. Results show an improvement of 16.7 % in the communication distance between the transponder and the reader.Identificação por Rádio Frequência (RFID) é usada em muitas aplicações, colocando etiquetas eletrônicas em animais e objetos para facilitar a leitura a fim de melhorar o gerenciamento destes. Nesse contexto, essa dissertação tem como objetivo melhorar a regulação de potência em chips de RFID a fim de aumentar a distância de leitura. Essa dissertação apresenta um nova arquitetura de regulador paralelo, não linear, que usa um detector de potência de Rádio Frequência (RF) baseado em uma técnica de modulação de pulso (PWM) para aplicação de RFID que usam o princípio de comunicação por acopla mento magnético. A arquitetura de regulador proposto é composta de duas realimen tações: uma realimentação usa um limitador de tensão rápido e a outra usa um detector de potência lento porém preciso. O primeiro garante a proteção contra sobre tensão e o segundo corrige a imprecisão do primeiro de acordo com a potência do sinal de entrada. Primeiramente, o estado da arte em regulação de sitemas de RFID bem como em detectores de potência RF são feitos para contextualizar os problemas e melhorias da nova arquitetura. Um desenvolvimento teórico seguido por simulações elétricas e o projeto do circuito da nova arquitetura de regulador paralelo são abordadas em detalhes. A circuito foi implementado em um processo CMOS de 180 nm como parte de um Chip de RFID de baixa frequência (134 kHz). O regulador lida com uma tensão senoidal (134 kHz) na sua entrada, gerada por um tanque LC que extrai energia provinda do leitor e que é usada alimentar todo o chip. Devido ao uso de um processo padrão 3.3 V CMOS para implementação do circuitos analógicos a fim de diminuir o custo de fabricação com o não uso do modulo de alta tensão (Ex. 5 V), impondo dificuldades no projeto do sistema, mesmo assim a solução proposta regula a tensão de entrada do chip em 3.6 V, máxima suportada pela tecnologia, com o uso das duas malhas de realimentação. A área total do Chip de RFID é de 870x870 µm², com 130x230 µm² para apenas o circuito de regulação. Os capacitores de ressonância e de alimentação foram integrados no Chip. O sistema completo consome 4.5 µA, sobre uma ampla gama de potência de entrada que é modulada pela distância entre o leitor e a tag. Como o detector de potência corrige a imprecisão do limitador de tensão composto de diodos devido a variação em processo, tensão e temperatura (PVT), a distância de leitura foi medida com e sem o detector de potência habilitado. Os resultados mostraram uma melhoria de 16.7 % na distância de comunicação

Battery-less near field communications (nfc) sensors for internet of things (iot) applications

L’ implementació de la tecnologia de comunicació de camp proper (NFC) en els telèfons intel·ligents no para de créixer degut a l’ús d’aquesta per fer pagaments, això, junt amb el fet de poder aprofitar l’energia generada pel mòbil no només per la comunicació, sinó també per transmetre energia, el baix cost dels xips NFC, i el fet de que els telèfons tinguin connectivitat amb internet, possibilita i fa molt interesant el disseny d’etiquetes sense bateria incorporant-hi sensors i poder enviar la informació al núvol, dins del creixent escenari de l’internet de les coses (IoT). La present Tesi estudia la viabilitat d’aquests sensors, analitzant la màxima distància entre lector i sensor per proveir la potència necessària, presenta tècniques per augmentar el rang d’operació, i analitza els efectes de certs materials quan aquests estan propers a les antenes. Diversos sensors han estat dissenyats i analitzats i son presentats en aquest treball. Aquests son: Una etiqueta que mesura la humitat de la terra, la temperatura i la humitat relativa de l’aire per controlar les condicions de plantes. Un sensor per detectar la humitat en bolquers, imprès en material flexible que s’adapta a la forma del bolquer. Dues aplicacions, una per estimació de pH i una altre per avaluar el grau de maduració de fruites, basats en un sensor de color. I, per últim, s’estudia la viabilitat de sensors en implants per aplicacions mèdiques, analitzant l’efecte del cos i proposant un sistema per augmentar la profunditat a la que aquests es poden llegir utilitzant un telèfon mòbil. Tots aquests sensors poden ser alimentats i llegits per qualsevol dispositiu que disposin de connexió NFC.La implementación de la tecnología de comunicaciones de campo cercano (NFC) en los teléfonos inteligentes no para de crecer debido al uso de esta para llevar a cabo pagos, esto, junto con el hecho de poder aprovechar la energía generada por el móvil no sólo para la comunicación, sino también para transmitir energía, el bajo coste de los chips NFC, i el hecho que los teléfonos tengan conectividad a internet, posibilita y hace muy interesante el diseño de etiquetas sin batería que incorporen sensores i poder enviar la información a la nube, enmarcado en el creciente escenario del internet de las cosas (IoT). La presente Tesis estudia la viabilidad de estos sensores, analizando la máxima distancia entre lector i sensor para proveer la potencia necesaria, presenta técnicas para aumentar el rango de operación, y analiza los efectos de ciertos materiales cuando estos están cerca de las antenas. Varios sensores han sido diseñados y analizados y son presentados en este trabajo. Estos son: Una etiqueta que mide la humedad de la tierra, la temperatura y la humedad relativa del aire para controlar las condiciones de plantas. Un sensor para detectar la humedad en pañales, impreso en material flexible que se adapta a la forma del pañal. Dos aplicaciones, una para estimación de pH y otra para evaluar el grado de maduración de frutas, basados en un sensor de color. Y, por último, se estudia la viabilidad de sensores en implantes para aplicaciones médicas, analizando el efecto del cuerpo y proponiendo un sistema para aumentar la profundidad a la que estos se pueden leer usando un teléfono móvil. Todos estos sensores pueden ser alimentados y leídos por cualquier dispositivo que disponga de conexión NFC.The implementation of near field communication (NFC) technology into smartphones grows rapidly due the use of this technology as a payment system. This, altogether with the fact that the energy generated by the phone can be used not only to communicate but for power transfer as well, the low-cost of the NFC chips, and the fact that the smartphones have connectivity to internet, makes possible and very interesting the design of battery-less sensing tags which information can be sent to the cloud, within the growing internet of things (IoT) scenario. This Thesis studies the feasibility of these sensors, analysing the maximum distance between reader and sensor to provide the necessary power, presents techniques to increase the range of operation, and analyses the effects of certain materials when they are near to the antennas. Several sensors have been designed and analysed and are presented in this work. These are: a tag that measures the soil moisture, the temperature and the relative humidity of the air to control the conditions of plants. A moisture sensor for diapers, printed on flexible material that adapts to the diaper shape. Two applications, one for pH estimation and another for assessing the degree of fruit ripening, based on a colour sensor. And finally, the feasibility of sensors in implants for medical applications is studied, analysing the effect of the body and proposing a system to increase the depth at which they can be read using a mobile phone. All of these sensors can be powered and read by any NFC enabled device

Analyse et exploitation des non linéarités dans les systèmes RFID UHF passifs

Powered by the exploding popularity of the Internet-of-Things (IoT), the demand for tagged devices with labels capable to ensure a reliable communication with added functions beyond the identification, such as sensing, location, health-care, among others, is growing rapidly. Certainly this growing is headed by the well-established Radio Frequency Identification (RFID) technology, and the use of wireless low-cost self-powered tags, in other words passive RFID tags, is the most widespread used alternative. In the constant evolution on this field, usually new software treatments are offered at the application layer with the objective to processing data to produce some new information. Further works aimed at improving the physical layer around the tag antenna miniaturization and matching techniques. So far, little or no work had been done on the exploitation of the communication channel, and certainly none has been done on the exploitation of the non-linear behavior of RFID chips.After presenting the RFID technology and phenomena produced by Radio Frequency (RF) non-linear devices, and leaning in some nearby works on the field, the core of this thesis starts by exposing two characterization platforms for the evaluation of non-linear phenomena presented during the reader-tag communication. One is specialized in radiating measurements considering the whole tag (antenna and chip) under test. The other is specialized in conducted measurements directly over RFID chips, allowing performing different parametric studies (power dependency, impedance, harmonic production, sensitivity). The characterization results show that harmonic signals generated from the passive RFID chip carry information.By exploiting the characterization results and to verify the hypothesis of exploitation of non-linearities in RFID, i.e. the use of harmonic signals, the research is pursued by designing, fabricating, and measuring four different configurations of RFID tags. The new RFID tags operate at the fundamental frequency in the UHF band and at its 3^{rd} harmonic in the microwave band. Antenna design policies, fabrication details, and parametric studies on the performance of the new prototypes are presented. The parametric study takes special care in the antenna structure, kind of chip used, received power, and read range.Finally, some alternatives approaches for the exploitation of non-linear effects generated by rectifying devices are presented. Some theoretical aspects and experimental results are discussed linking the passive RFID technology to the theories of Wireless Power Transfer (WPT) and Electromagnetic Energy Harvesting (EEH). The solution takes advantage of the non-linear nature of rectifying elements in order to maximize the RF-to-DC conversion efficiency of EEH devices and increase the read range of passive RFID tags. The solution triggers on the design of a RF multi-device system. The design procedure and tests consider three non-linear phenomena: (1) the impedance power dependency, (2) the harmonic production, and (3) the rectifying dependence on the RF waveform.Avec l'explosion de l'Internet des Objets (IoT), de nouveaux dispositifs permettant de tagguer les objets sont nécessaires afin de permettre non seulement leur identification mais aussi d'assurer des communications fiables et de nouvelles fonctionnalités comme la détection, la localisation ou la capture d'informations. Cette tendance s'appuie sur la technologie bien établie qu'est la radiofréquence par identification (RFID) et donc l'utilisation d'étiquettes (ou tags) faibles coûts et télé-alimentés. Dans ce contexte, de nombreux travaux au niveau de la couche d'application se tournent vers la mise au point de traitements logiciels complémentaires visant à produire de nouveaux types d'information. D'autres travaux visent à améliorer la couche physique avec l'objectif de miniaturiser encore le tag mais aussi de le doter de nouvelles capacités. Jusqu'à présent, il n'existe quasiment pas de travaux concernant la transmission du signal et aucun sur l'exploitation du comportement non-linéaire des puces RFID. Cette thèse vise à étudier les phénomènes non-linéaires produits lors d'une communication RFID.Dans la première partie, deux plateformes de mesure et de caractérisation spécifiques ont été développées : la première vise à observer les signaux au cours d'une communication RFID, et alors caractériser et analyser les effets liés aux phénomènes non linéaires ; la seconde permet d'effectuer différentes mesures directement sur les puces et les caractériser en termes d'impédance, production d'harmoniques et sensibilité. Ces plateformes ont permis : 1) de mettre en évidence que les fréquences harmoniques sont porteuses d'informations qui peuvent être exploitées et même offrir de nouvelles fonctionnalités ; 2) d'obtenir de nombreuses informations sur les propriétés des puces et d'en établir un modèle électrique précis ; 3) de déterminer des critères permettant d'évaluer la performance des tags dans le contexte étudié.Dans la deuxième partie, plusieurs nouveaux tags RFID ont été conçus, fabriqués, mesurés et évalués. Ces nouveaux tags fonctionnent non seulement dans la bande UHF mais aussi sont adaptés à la troisième harmonique dans la bande des microondes. Une méthodologie et des lignes directives d'aide à la conception de ce type de tags ont été établies et s'appuient sur les deux plateformes développées afin de caractériser les différents éléments. Dans un même temps, les effets liés à la fabrication ont aussi été étudiés et des études paramétriques ont permis de mettre en évidence l'effet sur les performances de la géométrie de l'antenne et du type de puce utilisée.Dans une troisième partie, les études se sont focalisées à exploiter les effets non-linéaires des dispositifs de redressement. L'idée générale est de coupler la RFID passive avec les dispositifs de transferts de puissance et de récupération d'énergie avec pour objectifs 1) de maximiser l'efficacité de conversion RF – continu 2) et d'augmenter la distance de lecture des tags passifs. Plusieurs prototypes ont été réalisés et leurs performances ont été démontrées.L'ensemble de ces travaux a mis en évidence un nouveau concept de communication RFID exploitant les non-linéarités générées par les puces RFID. Ce concept ouvre la voie à de nouvelles applications. et a fait l'objet d'une demande de brevet international

Chipless RFID sensor tag system with microstrip transmissionline based ID generation schemes

This dissertation presents a chipless radio frequency identification (RFID) sensor tag system consisting of passive chipless RFID sensor tags and specialized reader. The chipless sensor tags are fabricated on a flexible substrate and contain an ID generation circuit, a sensor, and a microstrip antenna. The ID generation circuit consists of meandered microstrip transmission lines and uses a novel reflection and delay based ID generation scheme. The scheme, using an input RF pulse, constructs an on-off keying (OOK) or pulse position modulated (PPM) signal pattern representing a unique ID code. Two transmission lines and OOK representation are used and the generation of ten different ID codes are demonstrated. The integrated ID generation circuit, sensor, and antenna use a single transmission line and PPM representation, and demonstrate the generation of eight different ID codes. However, the presented schemes allow the generation of higher combinations of bits. A practical method to measure radar cross section (RCS) parameters of antennas that provides complete and more accurate information on scattering properties of antennas, essential for chipless sensor tag design, is presented. The new method uses minimum mean square error estimation solution of a derived received backscattered signal power equation and provides load independent structural-mode RCS, antenna-mode RCS, and relative phase factor of the measured antenna. Two configurations of the chipless sensor tags configuration-I (conf-I) and configuration-II (conf-II) are presented. In conf-I tags, sensors are connected as a load to the antenna and the sensor information is amplitude modulated in the backscattered signal. The testing with conf-I temperature sensor tag resulted in a 28% amplitude change when the temperature at the tag changes from 27°C to 140°C. In conf-II tags, sensors are connected as load to the ID generation circuit and the sensor information is phase modulated in the antenna-mode scattered signal. With the conf-II ethylene sensor tag, a phase change of 33° is observed when the ethylene concentration at the tag changes from 0 to 100 ppm. The specialized reader system is comprised of an analog reader that wirelessly communicates with the sensor tags and a single board computer that computes the sensor information from the received signal. The reader system constructs a 96 bit serialized global trade item number (SGTIN-96) electronic product code (EPC) format unique RFID tag data frame, including 16 bit sensor information, and makes the information available on a secure web interface accessible from cyberspace. The presented sensor tag system has the advantages of passive and chipless sensor tag operation, while offering a wide range of sensors types for integration. Moreover, it offers a viable alternative solution to existing active as well as passive RFID sensor tag systems (eg. SAW based RFID sensor tag systems)

DESIGN, OPTIMIZATION AND IMPLEMENTATION OF AN ORTHO-TAG RFID SYSTEM

There are two major problems with traditional methods of operating an RFID tag embedded on orthopedic implants by wireless transmission: (1) interference with metallic orthopedic implants causes significant signal attenuation around the RFID tag; (2) interference with other medical devices may lead to the failure of their functionality. The creation of a feasible solution to the above two problems is critical to the success of operation of implanted RFID devices embedded on or near metallic implants and in any other situation where wireless interference may occur. The solution proposed in this dissertation is the Ortho-tag RFID system which uses the conductivity of human tissue at radio frequencies for energy and signal transmission. With the viability experiments proving the feasibility of using volume conduction in this research, two present issues have been addressed: (1) the lack of availability of a matching technique between tissue/saline and the RFID device; (2) the lack of an efficiency study on the operation of RFID through tissue/saline with variable thickness. This fundamental work then details the development of a general solution for the above two issues, in a power and communication platform technology for implanted RFID devices. The platform is developed using equipment in the RFID Center of Excellence in which pig skin and saline are used as a medium for in vivo environment as human tissue surrogates. The selection and design of the volume conduction electrodes are discussed and optimized using ANSYS/HFSS. The system optimization focuses on matching the RFID reader and the tag to the tissue/saline based on an equivalent 2-port network model for tissue using Z parameters. Matching networks are designed and optimized so that the tag is matched to the tissue from the internal side, and the tissue is matched to the RFID reader from the external side. For high data rate considerations, two RFID frequencies are utilized for the Ortho-tag RFID system. The frequencies are HF at 13.56 MHz and UHF at 915 MHz. The system is finally prototyped and demonstrated as the proof of concept

Passive und aktive Radio Frequency Identification Tags im 60-GHz-Band

Die Einführung des millimeter-Wellen-Bandes eröffnet neue Perspektiven für die Radio Frequency Identification (RFID) Kommunikationssysteme. Der Enwurf des Systems im 60-GHz-Band ermöglicht die Implementierung der On-Chip Antenne und darüber hinaus die Implementierung eines RFID-Tags auf einem einzigen Chip. Dennoch ist es aufgrund der gesetzlichen Beschränkung der effektiven isotropen Strahlungsleistung (EIRP) des Lesegeräts und der erhöhten Freiraum-Dielektrikumsverluste eine Herausforderung, eine zuverlässige Kommunikationsreichweite von mehreren Millimetern zu erreichen. Neue Lösungen sind für jeden Block sowohl im Lesegerät als auch im Single-Chip-Tag erforderlich. Obwohl das Lesegerät batteriebetrieben ist, ist es immer noch eine Herausforderung, die maximal zulässigen 20 dBm IERP des Lesersenders energieeffizient zu erzeugen. Darüber hinaus sollte der Empfänger einen ausreichenden Dynamikbereich haben, um das vom Tag kommende Signal zu erkennen. Auf der Tag-Seite sind die Hauptherausforderungen das Co-Design der effizienten On-Chip-Antennen-Implementierung, die hochempfindliche Gleichrichter-Implementierung und das Rückkommunikationskonzept. Diese Arbeit konzentriert sich auf die Machbarkeitsstudie des Single-Chip-RFID-Tags und die Implementierung im Millimeterwellenbereich. Es werden zwei Rückkommunikationskonzepte untersucht - Backscattering-Rückkommunikation und eine Kommunikation unter Verwendung von Ultra-Low-Power (ULP) Radios. Beide werden in einem 22 nm FDSOI Prozess auf einem Substrat mit geringem Widerstand implementiert. Beide Tags arbeiten mit einer Versorgungsspannung von 0,4 V, um die Kommunikationsreichweite zu maximieren. Die Link-Budgets sind so ausgelegt, dass sie die regulatorischen Beschränkungen einhalten. Die Auswahl des Technologieknotens wird begründet. Verschiedene Aspekte im Zusammenhang mit der Technologie werden diskutiert, wie z. B. Geräteleistung, passiver Qualitätsfaktor, Leistungsdichte der Kondensatoren. Der Backscattering RFID-Tag wird zuerst entworfen, da er eine relativ einfachere Topologie hat. Die Probleme der Gleichrichterempfindlichkeit im Rahmen des analogen Frontends, der On-Chip-Antenneneffizienz und der konjugierten Anpassung beider werden untersucht. Eine Kommunikationsreichweite von 5 mm wird angestrebt und realisiert. Um die Kommunikationsreichweite weiter zu erhöhen, wird in der zweiten Phase ein Tag mit einer aktiven Rückkommunikation implementiert. Hier wird die Gleichrichterempfindlichkeit weiter verbessert. Es wird ein 0,4V ULP Radio entworfen, das sich die Antenne mit dem Gleichrichter über einen Single-Pole- Double-Through (SPDT) Schalter teilt. Ein Abstand von 2 cm erwies sich als realisierbar, wobei die gesetzlichen Bestimmungen eingehalten und der dynamische Bereich des Leseempfängers nicht überschritten wurde. Es wird die höchste normalisierte Kommunikationsreichweite pro Leser-EIRP erreicht. Weitere Verbesserungsmöglichkeiten werden diskutiert

Application of Ultra-Wideband Technology to RFID and Wireless Sensors

Aquesta Tesi Doctoral estudia l'ús de tecnologia de ràdio banda ultraampla (UWB) per sistemes de identificació per radiofreqüència (RFID) i sensors sense fils. Les xarxes de sensors sense fils (WSNs), ciutats i llars intel•ligents, i, en general, l'Internet de les coses (IoT) requereixen interfícies de ràdio simples i de baix consum i cost per un número molt ampli de sensors disseminats. UWB en el domini temporal es proposa aquí com una tecnologia de radio habilitant per aquestes aplicacions. Un model circuital s'estudia per RFID d'UWB codificat en el temps. Es proposen lectors basats en ràdars polsats comercials amb tècniques de processat de senyal. Tags RFID sense xip (chipless) codificats en el temps son dissenyats i caracterizats en termes de número d'identificacions possible, distància màxima de lectura, polarització, influència de materials adherits, comportament angular i corbatura del tag. Es proposen sensors chipless de temperatura i composició de ciment (mitjançant detecció de permitivitat). Dos plataformes semipassives codificades en temps (amb un enllaç paral•lel de banda estreta per despertar el sensor i estalviar energia) es proposen com solucions més complexes i robustes, amb una distància de lectura major. Es dissenya un sensor de temperatura (alimentat per energia solar) i un sensor de diòxid de nitrogen (mitjançant nanotubs de carboni i alimentat per una petita bateria), ambdòs semipassius amb circuiteria analògica. Es dissenya un multi-sensor semipassiu capaç de mesurar temperatura, humitat, pressió i acceleració, fent servir un microcontrolador de baix consum digital. Combinant els tags RFID UWB codificats en temps amb tecnologia de ràdar de penetració del terra (GPR), es deriva una aplicació per localització en interiors amb terra intel•ligent. Finalment, dos sistemes actius RFID UWB codificats en el temps s'estudien per aplicacions de localització de molt llarg abast.Esta Tesis Doctoral estudia el uso de tecnología de radio de banda ultraancha (UWB) para sistemas de identificación por radiofrecuencia (RFID) y sensores inalámbricos. Las redes de sensores inalámbricas (WSNs), ciudades y casas inteligentes, y, en general, el Internet de las cosas (IoT) requieren de interfaces de radio simples y de bajo consumo y coste para un número muy amplio de sensores diseminados. UWB en el dominio temporal se propone aquí como una tecnología de radio habilitante para dichas aplicaciones. Un modelo circuital se estudia para RFID de UWB codificado en tiempo. Configuraciones de lector, basadas en rádar pulsados comerciales, son propuestas, además de técnicas de procesado de señal. Tags RFID sin chip (chipless) codificados en tiempo son diseñados y caracterizados en términos de número de identificaciones posible, distancia máxima de lectura, polarización, influencia de materiales adheridos, comportamiento angular y curvatura del tag. Se proponen sensores chipless de temperatura y composición de cemento (mediante detección de permitividad). Dos plataformas semipasivas codificadas en tiempo (con un enlace paralelo de banda estrecha para despertar el sensor y ahorrar energía) se proponen como soluciones más complejas y robustas, con una distancia de lectura mayor. Se diseña un sensor de temperatura (alimentado por energía solar) y un sensor de dióxido de nitrógeno (mediante nanotubos de carbono y alimentado por una batería pequeña), ambos semipasivos con circuitería analógica. Se diseña un multi-sensor semipasivo capaz de medir temperatura, humedad, presión y aceleración, usando un microcontrolador digital de bajo consumo. Combinando los tags RFID UWB codificados en tiempo y tecnología de radar de penetración de suelo (GPR), se deriva una aplicación para localización en interiores con suelo inteligente. Finalmente, dos sistemas activos RFID UWB codificados en tiempo se estudian para aplicaciones de localización de muy largo alcance.This Doctoral Thesis studies the use of ultra-wideband (UWB) radio technology for radio-frequency identification (RFID) and wireless sensors. Wireless sensor networks (WSNs) for smart cities, smart homes and, in general, Internet of Things (IoT) applications require low-power, low-cost and simple radio interfaces for an expected very large number of scattered sensors. UWB in time domain is proposed here as an enabling radio technology. A circuit model is studied for time-coded UWB RFID. Reader setups based on commercial impulse radars are proposed, in addition to signal processing techniques. Chipless time-coded RFID tags are designed and characterized in terms of number of possible IDs, maximum reading distance, polarization, influence of attached materials, angular behaviour and bending. Chipless wireless temperature sensors and chipless concrete composition sensors (enabled by permittivity sensing) are proposed. Two semi-passive time-coded RFID sensing platforms are proposed as more complex, more robust, and longer read-range solutions. A wake-up link is used to save energy when the sensor is not being read. A semi-passive wireless temperature sensor (powered by solar energy) and a wireless nitrogen dioxide sensor (enabled with carbon nanotubes and powered by a small battery) are developed, using analog circuitry. A semi-passive multi-sensor tag capable of measuring temperature, humidity, pressure and acceleration is proposed, using a digital low-power microcontroller. Combining time-coded UWB RFID tags and ground penetrating radar, a smart floor application for indoor localization is derived. Finally, as another approach, two active time-coded RFID systems are developed for very long-range applications

Low Power Autonomous Microsystem for Oil Well Logging Applications

Downhole environmental monitoring can provide significant benefits to the petroleum industry. The rapid development of semiconductor technology enables autonomous sensing microsystems to operate at extreme environments. By injecting these microsystems into the boreholes and retrieving them after deployment, the geophysical conditions in the area of interest can be obtained. Challenges include high temperature, high pressure, miniaturized system size and packaging. This dissertation describes three generations of the environmental logging microsystem (ELM) for downhole geophysical logging applications. The first generation of the microsystem, ELM1.0, is designed for temperature logging in downhole environments. Each system consists of a power management circuit, a microcontroller with an integrated temperature sensor, and optical indicators. The system electronics are integrated on a flexible printed circuit board and packaged in a steel shell. The ELM1.0 has a packaged size of 8.9×8.9×6.85 mm3. It was tested at up to 125°C, 50 MPa in high salinity condition. The second generation (ELM2.0 & ELM2.1) is upgraded from ELM1.0 by adding a micromachined capacitive pressure sensor for pressure sensing up to 50 MPa. The ELM2.0 & ELM2.1 systems are packaged in steel shells filled with transparent polymer for pressure transfer. The packaged systems have a dimension of 9.5×9.5×6.5 mm3. The third generation (ELM3.0) is upgraded from ELM2.0 with a power switch and a low-cost polyimide pressure sensor for coarse pressure measurement up to 50 MPa. Both ELM2.0 and ELM3.0 systems were successfully tested at up to 125°C, 50 MPa in corrosive environments using laboratory instruments, and in a brine well at a depth up to 1235 m. A progressive polynomial calibration method was used for interpretation of the pressure sensor data from these tests. In addition, a high power micromachined RF switch for radio transceiver applications was designed, fabricated and tested. The RF switch can potentially be used to establish antenna networks for RF communication in the ELM. The switch consists of a bridge structure for electrostatic actuation and capacitive contact. The switch was fabricated with a 7-mask process. The fabricated device showed limited RF performance because of challenges related to the control of residual stress in suspended elements.PHDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttps://deepblue.lib.umich.edu/bitstream/2027.42/138647/1/sui_1.pd