Global ETD Search

301	Allocation conjointe des canaux de fréquence et des créneaux de temps et routage avec QdS dans les réseaux de capteurs sans fil denses et étendus / Joint allocation of channels of frequency and time slots with QoS routing for large-scale Wireless Sensor Networks Ben Slimane, Jamila 12 March 2013 (has links) Le thème général du sujet tourne autour de l'optimisation inter-couche des réseaux de capteurs basés sur la technologie ultra large bande ULB (UWB, Ultra Wide Band) moyennant des solutions protocolaires permettant d'un côté de répondre au besoin de qualité de service QdS à critères multiples dans les réseaux de capteurs sans fil et d'autre côté d'assurer le partage et l'allocation efficace les ressources disponibles (spectrale et temporelle) ainsi que l'optimisation de la consommation d'énergie dans des tels réseaux. Le domaine d'application cible choisi dans le présent travail est les systèmes de suivi des patients au sein d'un réseau de capteurs déployé en hôpital intelligent (WHSN, Large-scale Wireless Hospital Sensor Network). Dans ce contexte, nous avons proposé le modèle UWBCAS pour assurer le partage des ressources spectrales entre les PANs. Puis, nous avons conçu et implémenté un protocole MAC multi-canal multi-créneau de temps avec support de qualité de service, PMCMTP, pour assurer une allocation conjointe des canaux de fréquence et des créneaux de temps au sein de chaque réseau PAN. Enfin nous avons proposé l'algorithme JSAR qui traite à la fois les problèmes d'ordonnancement des cycles d'activités des membres du réseau dans le but d'optimiser la consommation d'énergie, d'allocation efficace des canaux de fréquence et des créneaux de temps afin d'améliorer le taux d'utilisation des ressources et les performances du réseau et de routage avec support de QdS à critères multiples afin de répondre aux besoins des applications supportées / The general context of the present memory is about the cross-layer optimization of wireless sensors networks based on ultra wide band technology UWB. The proposed solutions ensure the share and the efficient allocation of spectral and temporal resources, the optimization of the energy consumption and the support of multi-constraints quality of services QoS. The most challenging issue is providing a tradeoff between the resource efficiency and the multiconstrained QoS support. For this purpose, we proposed a new Wireless Hospital Sensor Network (WHSN) three-tiered architecture in order to support large-scale deployment and to improve the network performance. Then we designed a channel allocation scheme (UWBCAS,)and a prioritized multi-channel multi-time slot MAC protocol (PMCMTP) to enhance network performance and maximize the resource utilization. Finally, we proposed a joint duty cycle scheduling, resource allocation and multi-constrained QoS routing algorithm (JSAR) which simultaneously combines, a duty cycle scheduling scheme for energy saving, a resource allocation scheme for efficient use of frequency channels and time slots, and an heuristic for multi-constrained routing protocol Réseau de capteurs Technologie ULB WHSN Allocation des ressources QdS à critères multiples Optimisation inter-couche WSN UWB technology WHSN Resource allocation Multi-constrained routing Cross-layer optimization 621.382 1 004.6
302	UWB Motion and Micro-Gesture Detection -Applications to interactive electronic gaming and remote sensing Zang, Yuzhang 03 May 2016 (has links) The ultra-wideband (UWB) technology has a vast unlicensed frequency spectrum, which can support precise indoor positioning in orders of centimeters. The features of UWB signals can be utilized for variety of applications. In this project first we present an empirical channel models to analyze the localization accuracy of the UWB technology for interactive electronic gaming (Ping-Pong) in Line-of-Sight (LOS) and Obstructed LOS (OLOS) scenarios. Then we introduce a new concept that we refer to as micro-gesture detection to handle the more refined motions of the hand, such as rotation, while one antenna is held by the user using features of UWB signal. We use four specific features of the UWB signals: time of arrival, power of the first peak, total power, and the Root-Mean Square (RMS) of the delay spread, for this purpose. As the hand rotates the position of the antenna in the hand and the external antenna changes from LOS to OLOS. We demonstrate that features of the UWB signals are more useful than the RSS signal of the Wi-Fi to detect this class of micro-gestures. We foresee this micro-gesture detection capabilities become helpful for the people with limited ability or visually impaired for implementation of simplified sign language to communication with electronic devices located away from a person. We compare gesture detection using multiple features of the UWB signal with traditional gesture detection using the received signal strength (RSS) of the Wi-Fi signal. ultra wideband (UWB) motion gaming gesture detection indoor localization line of sight (LOS) obstructed line of sight (OLOS) time of arrival (TOA) received signal strength (RSS) medical application
303	Wireless electrocardiogram based on ultra-wideband communications Toll, Maria January 2019 (has links) The goal for this master thesis is to develop a prototype that uses ultra-wideband (UWB) communications to wirelessly transfer electrocardiogram (ECG) data from an ECG measurement unit to an Android device (smartphone or similar) which is used to process and display the ECG signals. The prototype should consist of two hardware nodes; (1) Node one having a ECG measurement unit (an AD8232 single lead heart rate monitor), an UWB communication module (a Decawave DWM1000 module) and a microcontroller (an Arduino DUE); and (2) Node two having an Android device (an Android smartphone), an UWB communication module (a Decawave DWM1000 module) and a microcontroller (an Arduino DUE). On Node one the AD8232 monitor for ECG measurements is connected to an analog input (with an analog to digital converter (ADC)) on the Arduino and the DWM1000 module is connected to the Arduino via serial peripheral interface (SPI). On Node two the DWM1000 is connected to the Arduino via SPI to receive ECG data from Node one, and the Arduino is connected to the smartphone through a serial USB cable with an USB on-the-go adapter to send the ECG data to the smartphone, where it is filtered and displayed with an Android application. The application has the potential to add, for example, ECG analysis for diagnosing heart activities with artificial intelligence (AI) and further transmit the ECG data for remote medical care. The Arduino is programmed in Arduino IDE (integrated development environment) to handle ECG measurements and UWB communications (transmitting and receiving ECG data), which is limited to a single UWB channel because of limitations of the DWM1000 module. The Android application is created using Android studio, and it can process (with a notch filter) and display 1-12 channel ECG. The prototype has been built and tested. The results show that a single lead ECG measurement can be sent via UWB communication to a smartphone to display in real time. Multiple data channels (1-12 analog inputs on the Arduino) can be multiplexed, transmitted and displayed in real time. This thesis concludes that UWB has huge development potential, and will likely be used for various wireless devices in the future. UWB ECG EKG ultra-wideband electrocardiogram ultra wideband radio communication Decawave DW1000 IoT internet of things Android IEEE 802.15.4-2011 Elektroteknik och elektronik
304	Evaluation des performances d'un système de localisation de véhicules de transports guidés fondé sur l'association d'une technique radio ULB et d'une technique de retournement temporel. / Performance evaluation of a location system guided transport vehicles based on the combination of UWB radio technology and a time reversal technique Fall, Bouna 14 November 2013 (has links) En transports guidés, la localisation précise des trains s’avère vitale pour une exploitation nominale du système de transport. Dans un environnement de propagation tel que celui d’une emprise ferroviaire, un capteur de localisation efficace est complexe à concevoir et à valider lorsqu’il doit opérer en présence de nombreux obstacles fixes et mobiles constitués par l’infrastructure et les trains. Afin de concevoir un tel capteur, nous proposons dans ce travail de thèse l’emploi de techniques innovantes dites de diversité spectrale que l’on retrouve également sous la dénomination de radio Ultra Large Bande (ULB). Dans ce travail, cette dernière est également associée à la technique de Retournement Temporel (RT) afin de tirer partie de cet environnement de propagation complexe. L’objectif visé est d’obtenir une localisation fiable et robuste des véhicules ferroviaires par focalisation de signaux ULB en direction des antennes sol ou trains. Des études théoriques alliées à des simulations ont été effectuées portant sur les propriétés de focalisation d’énergie de la technique de retournement temporel en tenant compte de plusieurs paramètres liés aux configurations antennaires, aux canaux de propagation rencontrés et à l’électronique utilisée. L’apport du retournement temporel sur la précision du système de localisation Ultra Large Bande a été quantifié en comparant le système de localisation ULB conventionnel, sans retournement temporel puis, en associant le RT. Les résultats théoriques et de simulations de la solution proposée ont été validés par des expérimentations menées en chambre anéchoïque ainsi qu’en environnement indoor. / In guided transport, the precise location of trains is vital for nominal operation of the transport system. In a propagation environment such as a railway line, an effective location sensor is complex to design and validate since it must operate in the presence of many fixed and mobile obstacles constituted by the infrastructure and the trains. In this thesis, to design such a sensor, we propose the use of so-called spectral diversity techniques also found under the name of Ultra Wideband radio (UWB). In this work, the latter is also associated with the Time Reversal (TR) technique to take advantage of the complex propagation environment. The objective is to obtain a reliable and robust location of rail vehicles by focusing UWB signals to antennas or ground trains. Theoretical studies combined with simulations were performed on the properties of energy focusing of TR technique taking into account several parameters related to antennal configurations, propagation channels and the railway environment. The contribution of TR on the accuracy of the positioning system was quantified by comparing the conventional UWB positioning system alone and then, combining it with TR. The theoretical results and simulations of the proposed solution have been validated by experiments carried out in an anechoic chamber and in indoor environment. Ulb Retournement temporel Localisation Focalisation temporelle Focalisationspatiale Gain de focalisation Modèles de canaux de propagation Tdoa Uwb Time reversal Location Temporal focusing Spatial focusing Focusing gain Channel propagation models Tdoa
305	Caractérisation et modélisation du canal de propagation radio en contexte Ultra Large Bande Pagani, Pascal 28 November 2005 (has links) (PDF) L'Ultra Wide Band (UWB) est une technique de communication radio à haut débit et courte portée qui utilise des bandes de fréquence de 500 MHz à plusieurs GHz. Cette thèse présente une caractérisation expérimentale du canal de propagation UWB afin de proposer des modèles pour le développement de ces systèmes.<br />Les deux techniques de sondage proposées permettent la mesure du canal statique dans la bande 3,1 – 11,1 GHz et le sondage en temps réel dans la bande 4 – 5 GHz. Plusieurs campagnes de mesure réalisées en environnement intérieur de bureau sont détaillées. Leur analyse permet de dégager les paramètres grande échelle et les évanouissements rapides du canal statique, avec une étude particulière de l'influence de la fréquence. Des études spécifiques sont dédiées aux variations du canal UWB dues au mouvement des antennes et au passage de personnes. Un modèle statistique est proposé, permettant de reproduire les effets du canal de propagation UWB, en configurations statique et dynamique. [SPI:OTHER] Engineering Sciences/Other Ultra Large Bande Ultra Wide Band UWB Canal de propagation Sondage de canal Modélisation statistique Environnement intérieur Effet des personnes
306	The Impulse-Radiating Antenna Rosenlind, Johanna January 2009 (has links) <p>As the interest in intentional electromagnetic interference (IEMI) increases, so does the need of a suitable antenna which endures those demanding conditions. The ultrawideband (UWB) technology provides an elegant way of generating high-voltage UWB pulses which can be used for IEMI. One UWB antenna, invented solely for the purpose of radiating pulses, is the impulse radiating antenna (IRA). In the course of this master thesis work, a suitable geometry of the IRA is suggested, and modelled, for the high-voltage application of 90 kV.</p> Broadband antenna IRA time domain simulations impedance matching electrical breakdown CST Microstripes intentional electromagnetic interference IEMI ultrawide band UWB high-voltage pulses Other engineering physics Övrig teknisk fysik
307	Design of Active CMOS Multiband Ultra-Wideband Receiver Front-End Reja, Md Mahbub 06 1900 (has links) Inductors are extensively used in the design of radio-frequency circuits. In the last decade, the integration of passive components, especially inductors on silicon chips, has led to the widespread development and implementation of Radio Frequency Integrated Circuits (RFICs) in CMOS technologies. However, on-chip passive inductors occupy a large silicon chip area and hardly scale down with technology scaling. Therefore, on-chip passive inductors become formidable obstacles to the realization of highly dense RFICs to be integrated with other highly dense digital circuits on a single chip using a common fabrication process. In recent years, researchers have focused on replacing passive inductors with transistor-only active circuits, namely active inductors. Active inductors can be realized with only a few transistors, which scale down with technology scaling. Therefore, they occupy a fraction of the chip area of their passive counterparts, and can be implemented densely in CMOS processes. Unlike passive inductors, bias dependent operations of active inductors allow for the tuning of their inductance and quality factor Q, and in turn, tuning the performance parameters of RFICs. This thesis focuses on the design and development of passive inductorless CMOS RFICs for ultra-wideband (UWB) receiver front-ends using active inductors. A new Q-enhanced and a new bandwidth-extended tunable active inductors are designed. Using the Q-enhanced active inductor, two tunable UWB low-noise amplifiers (LNAs) (two-stage and three-stage UWB LNAs), a UWB mixer and a wideband local-oscillator (LO) driver are designed. Active inductors are utilized to develop a novel wideband active shunt-peaking technique that decreases high-frequency losses to yield a flat gain over a wide bandwidth. A tunable multiband-UWB front-end integrating a two-stage UWB LNA, and a pair of UWB mixers driven by a pair of wideband LO drivers, is fabricated in a 90nm digital CMOS process. The passive inductorless two-stage UWB LNA, three-stage UWB LNA and UWB front-end occupy chip areas of only 0.0114mm2, 0.0227mm2, and 0.1485mm2, respectively. The active CMOS UWB front-end exhibits a measured flat gain of 22.5dB over 2.5-8.8 GHz bandwidth, and its tunability allows for varying the gain and bandwidth. / Integrated Circuits and Systems CMOS Multiband Ultra-Wideband (UWB) Radio-Frequency (RF) Integrated-Circuit (IC) Receiver Front-End Active Inductor Q-Enhanced Bandwidth-Extended LNA Mixer Oscillator
308	Analog and Digital Approaches to UWB Narrowband Interference Cancellation Omid, Abedi 02 October 2012 (has links) Ultra wide band (UWB) is an extremely promising wireless technology for researchers and industrials. One of the most interesting is its high data rate and fading robustness due to selective frequency fading. However, beside such advantages, UWB system performance is highly affected by existing narrowband interference (NBI), undesired UWB signals and tone/multi-tone noises. For this reason, research about NBI cancellation is still a challenge to improve the system performance vs. receiver complexity, power consumption, linearity, etc. In this work, the two major receiver sections, i.e., analog (radiofrequency or RF) and digital (digital signal processing or DSP), were considered and new techniques proposed to reduce circuit complexity and power consumption, while improving signal parameters. In the RF section, different multiband UWB low-noise amplifier key design parameters were investigated like circuit configuration, input matching and desired/undesired frequency band filtering, highlighting the most suitable filtering package for efficient UWB NBI cancellation. In the DSP section, due to pulse transmitter signals, different issues like modulation type and level, pulse variety, shape and color noise/tone noise assumptions, were addressed for efficient NBI cancelation. A comparison was performed in terms of bit-error rate, signal-to-interference ratio, signal-to-noise ratio, and channel capacity to highlight the most suitable parameters for efficient DSP design. The optimum number of filters that allows the filter bandwidth to be reduced by following the required low sampling rate and thus improving the system bit error rate was also investigated. Passive Filter ZigZag GPS LNA UWB WLAN NBI RF CG CS Gm boosting PAM PPM RAKE receiver BER data rate Channel Capacity PSD Pulse shape Hermite Filter bank
309	The Impulse-Radiating Antenna Rosenlind, Johanna January 2009 (has links) As the interest in intentional electromagnetic interference (IEMI) increases, so does the need of a suitable antenna which endures those demanding conditions. The ultrawideband (UWB) technology provides an elegant way of generating high-voltage UWB pulses which can be used for IEMI. One UWB antenna, invented solely for the purpose of radiating pulses, is the impulse radiating antenna (IRA). In the course of this master thesis work, a suitable geometry of the IRA is suggested, and modelled, for the high-voltage application of 90 kV. Broadband antenna IRA time domain simulations impedance matching electrical breakdown CST Microstripes intentional electromagnetic interference IEMI ultrawide band UWB high-voltage pulses Other engineering physics Övrig teknisk fysik
310	The Feasibility, Reliable Communication And Networking Aspects Of Passive Wireless Sensor Networks Yagli, Mehmet 01 September 2006 (has links) (PDF) The primary challenge in wireless sensor network (WSN) deployment is the limited network lifetime due to the finite-capacity batteries. In accordance with this challenge, the vast majority of research efforts thus far have focused on the development of energy-efficient communication and computing mechanisms for WSNs. In this thesis, a fundamentally different approach and hence completely new WSN paradigm, i.e., the Passive Wireless Sensor Network (PWSN), is introduced. The objective of PWSN is to eliminate the limitation on the system lifetime of the WSNs. In PWSN, power is externally supplied to the sensor network node via an external RF source. Hence, the lifetime of the system is no longer determined by the lifetime of the batteries. An alternative communication scheme, modulated backscattering, is also discussed to be utilized in PWSN. The feasibility of the proposed system is investigated along with the open research challenges for reliable communication and networking in PWSN. Additionally, a new medium access schemee for PWSN, Ultra-Wideband PWSN Medium Access Control (UWB PWSN MAC), is presented.

Search results