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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Discrete-Time Implementation, Antenna Design, and MIMO for Near-Field Magnetic Induction Communications

Gottula, Ronald Brett 05 July 2012 (has links) (PDF)
Near-field magnetic induction (NFMI) is a short range wireless technology that uses loop antennas coupled by a magnetic field. NFMI antennas are electrically small and thus extremely inefficient and narrow band, making system design for multi-user and high-bitrate applications challenging. The goals of this thesis are to develop a test platform suitable for NFMI antenna testing, to model, design and test NFMI antennas that have high bandwidth-efficiency, and to explore the possibility of using MIMO (multiple-input multiple-output) to increase the capacity of the NFMI channel. This thesis provides system implementations, test results, and channel modeling to aid in the design of future NFMI systems. Implementation of a multi-channel discrete-time wireless system are provided for PC-based software and FPGA-based firmware as a platform for antenna testing. Optimized antenna designs in terms of efficiency and bandwidth are presented, achieving the theoretical bandwidth-efficiency bound for small antennas. Preliminary modeling and simulation results for the NFMI-MIMO channel are included, which show that the information-theoretic capacity of the NFMI-MIMO channel is approximately double the standard single-antenna NFMI capacity at 10 bits/s/Hz.
2

Conception d'antennes de communication à travers le corps humain pour le suivi thérapeutique / Design of communication antennas throught the human body for the therapeutic monitoring

El Hatmi, Fatiha 21 March 2013 (has links)
Avec le développement rapide des technologies sans fil modernes et la miniaturisation des antennes et des systèmes électriques, l'emploi des antennes à l'intérieur du corps humain pour le suivi thérapeutique est devenu possible. Des batteries permettent d'alimenter ces antennes ; la réduction de la consommation de puissance implique l'augmentation de la durée de vie de circuits ingérables. Le corps humain, qui a une conductivité non nulle, n'est pas un milieu idéal pour la transmission des ondes RF à cause de l'atténuation liée aux propriétés diélectriques des tissus biologiques. Cependant, les tissus humains ne perturbent pas le champ magnétique car celui-ci dépend de la perméabilité du milieu qui est égale à un dans le corps humain. Bien que la puissance du champ magnétique décroisse avec l'exposant six de la distance, la technique utilisant les communications par induction magnétique en champ proche a été adoptée dans cette étude pour concevoir une liaison sans fil à faible portée à travers le corps humain. Durant ces travaux de thèse, après une caractérisation détaillée de la bobine d'émission située à l'intérieur du corps humain et de la bobine de réception localisée à sa surface, nous avons mis en place un bilan de liaison pour contribuer à l'amélioration du transfert de puissance dans ce milieu dissipatif. Un modèle analytique, déterminant les facteurs qui peuvent affecter le bilan de liaison par induction magnétique, a été vérifié à travers les simulations et les mesures. La variation de la position et de l'orientation de l'antenne ingérable ont été prises en compte pour évaluer la réponse de couplage entre la bobine émettrice et la bobine réceptrice. Les résultats obtenus constituent un pas en avant vers de futures recherches sur la conception de antennes dans les milieux dissipatifs et en particulier le corps humain / With the rapid growth of wireless technology and the miniaturization of modern antennas and electrical systems, the use of antennas inside the human body for therapeutic monitoring became possible. Batteries are used to supply these antennas; reducing the power consumption allows to increase the lifetime of ingestible systems. The human body, which has non-zero conductivity, is not an ideal environment for the transmission of RF waves because of the attenuation due to the dielectric properties of biological tissues. However, the human tissues do not disrupt the magnetic field as it depends on the permeability of the medium which is equal to one in the human body. Although the magnetic field power decreases with the distance exponent six, the technique using near-field magnetic induction communications was adopted in this study to design a short range wireless link through the human body. In this thesis, after a detailed characterization of the transmitting coil antenna located inside the human body and the receiving coil placed on its surface, we have implemented a link budget to contribute to the improvement of power transfer in the dissipative medium. An analytical model, identifying factors that can affect the link budget by magnetic induction, has been verified through simulations and measurements. The variation of the position and the orientation of the ingestible antenna were taken into account to evaluate the coupling response between the transmitting coil and the receiving coil. The results are a step toward future research on the design of antennas in dissipative media, in particular the human body

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