Highly Miniaturized Bandpass Filters for Wireless System-in-Package Applications

Chen, Chien-Hsun

14 March 2012

This dissertation studies and implements highly miniaturized bandpass filter designs for wireless System-in-Package (SiP) applications. Based on the coupling matrix synthesis method, the external quality factors and coupling coefficients can be extracted by selecting the proper tapped-line feeding position and coupling spacing in geometrical configuration. Despite their high performance, most conventional microstrip bandpass filter designs require a bulky area for achieving, making them difficult to implement SiP applications. This dissertation first develops a stacked LC resonator and a stacked spiral resonator (SSR) in an embedded passive substrate (EPS) for realizing miniature single- and multi-band bandpass filters. Moreover, multiple transmission zeros created on both sides of each passband provide high stopband roll-off rates. The designed performance and size are comparable to those of low-temperature co-fired ceramic (LTCC) bandpass filters. As another conventional means of implementing RF passive components, the integrated passive device (IPD) process can produce large-value inductors and high-density capacitors, simultaneously. This dissertation fully utilizes the advantages of IPD technology to implement very compact bandpass filter designs with multiple transmission-zero frequencies at stopband by using a high-density wiring planar transformer configuration. Furthermore, due to the fully symmetric geometry, the transformer-coupled bandpass filter can be easily converted into a balun bandpass filter, capable of providing a superior balance performance with a significantly higher common mode rejection ratio (CMRR) level. The electromagnetic (EM) simulation results, as obtained by using Ansys-Ansoft HFSS, agree with the measurement results for all of the proposed designs in this dissertation.

Embedded Passive Substrate

Bandpass Filters

Integrated Passive Devices

Planar Transformer

Transmission Zeros

Étude et minimisation du facteur de qualité des antennes pour de petits objets communicants / Study an optimization of the quality factor of small antennas

Diop, Oumy

27 September 2013

Actuellement, les objets communicants sans fils occupent une place prépondérante. Pour faciliter leur utilisation, ces objets sont de plus en plus petits et nécessitent de très petites antennes. Cette miniaturisation d’antennes implique forcément une détérioration de leurs performances. La conception d’antennes électriquement petites (AEP) nécessite une très bonne compréhension théorique des mécanismes électromagnétiques mis en jeu notamment quelles limites précises peut-on atteindre pour une AEP étant circonscrive dans un volume donné. Un des paramètres essentiels d’une AEP est son facteur de qualité intrinsèque qui est inversement proportionnel à sa bande passante en impédance. Ainsi, maximiser la bande passante en impédance d’une antenne consiste à minimiser son facteur de qualité. Face à ce problème, de nombreux travaux ont été développés pour déterminer les limites possibles pour des AEP. C’est dans ce cadre que s’inscrit le premier axe de recherche de la thèse : étudier le facteur de qualité d’AEP, afin de déterminer s’il existe des dimensions optimales permettant de s’approcher de ces limites. Le second axe de recherche a consisté à étudier des AEP fonctionnant à 2,45 GHz pour des implants biomédicaux. Celles-ci sont imprimées sur de nouveaux types de substrat pour avoir une meilleure résolution de trace métallique favorisant une réduction de l’encombrement, et une intégration facilitant ainsi les interconnexions avec les frontaux RF. Le challenge consiste à maximiser les performances de ces antennes. Plusieurs prototypes ont été réalisés pour valider les simulations. / Currently, wireless devices play an important role in everyday life. For ease-of-use, these devices are becoming smaller and require very small antennas. However, the size reduction of these antennas necessarily implies a degradation of their performance. Consequently, the design of electrically small antennas (ESA) requires a very good theoretical understanding of the electromagnetic phenomenon that takes place, especially in terms of accurate performance that can be expected for an ESA with given dimensions. An important parameter of an ESA is its intrinsic quality factor since it is inversely proportional to its impedance bandwidth. Indeed, maximizing the matching bandwidth of an antenna consists in minimizing its quality factor. Facing this problem, many researches have been developed to determine the possible limits of the quality factor of ESA. The first research axis of this thesis is to study the quality factor of ESA to determine whether optimal dimensions exist to approach the fundamental quality factor limits. The second part of the thesis studies miniature antennas for biomedical implants operating at 2.45 GHz. These antennas are printed on a specific microelectronic substrate to ensure a better resolution in terms of metallic traces in order to reduce the size and allow easier integration to facilitate interconnections with RF front-end. The challenge consists in maximizing the performance of these antennas. The presented results are supported by means of electromagnetic models and simulations on one hand. Also, several prototypes are fabricated to validate these simulations.

Antenne

Miniaturisation

Facteur de qualité

Limite de Gustafsson

Symétriseur

Antenna

Miniaturization

Quality factor

Gustafsson Limit

Integrated Passive Devices

Balun

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