Reconfigurable Dielectric Resonator Antennas

Desjardins, Jason

January 2011

With the increasing demand for high performance communication networks and the proliferation of mobile devices, significant advances in antenna design are essential. In recent years the rising demands of the mobile wireless communication industry have forced antennas to have increased performance while being limited to an ever decreasing footprint. Such design constraints have forced antenna designers to consider frequency agile antennas so that their behavior can adapt with changing system requirements or environmental conditions. Frequency agile antennas used for mobile handset applications must also be inexpensive, robust, and make use of electronic switching with reasonable DC power consumption. Previous works have addressed a number of these requirements but relatively little work has been performed on frequency agile dielectric resonator antennas (DRAs). The objective of this thesis is to investigate the use of DRAs for frequency reconfigurability. DRAs are an attractive option due to their compactness, very low losses leading to high radiation efficiencies (better than 95%) and fairly wide bandwidths compared to alternatives. DRA’s are also well suited for mobile communications since they can be placed on a ground plane and are by nature low gain antennas whose radiation patterns typically resemble those of short electric or magnetic dipoles. One way to electronically reconfigure a DRA, in the sense of altering the frequency band over which the input reflection coefficient of the antenna is below some threshold, is to partially load one face of the DRA with a conducting surface. By altering the way in which this surface connects to the groundplane on which the DRA is mounted, the DRA can be reconfigured due to changes in its mode structure. This connection was first made using several conducting tabs which resulted in a tuning range of 69% while having poor cross polarization performance. In order to address the poor cross polarization performance a second conducting surface was placed on the opposing DRA wall. This technique significantly reduced the cross polarization levels while obtaining a tuning range of 83%. The dual-wall conductively loaded DRA was then extended to include a full electronic implementation using PIN diodes and varactor diodes in order to achieve discrete and continuous tuning respectively. The two techniques both achieved discrete tuning ranges of 95% while the varactor implementation also had a continuous tuning range of 59% while both maintaining an acceptable cross polarization level.

Antenna

Continuous Tuning

Dielectric Resonator Antenna

Electrically Small Antenna

Frequency Agile

Multiband Antenna

Design of Frequency Reconfigurable Multiband Compact Antenna using two PIN diodes for WLAN/WiMAX Applications

Abdulraheem, Yasir I., Oguntala, George A., Abdullah, Abdulkareem S., Mohammed, Husham J., Ali, R.A., Abd-Alhameed, Raed, Noras, James M.

21 February 2017

Yes / In this paper, we present a simple reconfigurable multiband antenna with two PIN diode switches for WiMAX/WLAN applications. The antenna permits reconfigurable switching in up to ten frequency bands between 2.2 GHz and 6 GHz, with relative impedance bandwidths of around 2.5% and 8%. The proposed antenna has been simulated using CST microwave studio software and fabricated on an FR-4 substrate. It is compact, with an area of 50 × 45 mm2, and has a slotted ground substrate. Both measured and simulated return loss characteristics of the optimized antenna show that it satisfies the requirement of 2.4/5.8 GHz WLAN and 3.5 GHz WiMAX antenna applications. Moreover, there is good agreement between the measured and simulated result in terms of radiation pattern and gain. / Engineering and Physical Science Research Council through Grant EP/E022936A.

A novel meander bowtie-shaped antenna with multi-resonant and rejection bands for modern 5G communications

Faouri, Y.S., Ahmad, S., Ojaroudi Parchin, Naser, See, C.H., Abd-Alhameed, Raed

27 March 2022

Yes / To support various fifth generation (5G) wireless applications, a small, printed bowtie-shaped microstrip antenna with meandered arms is reported in this article. Because it spans the broad legal range, the developed antenna can serve or reject a variety of applications such as wireless fidelity (Wi-Fi), sub-6 GHz, and ultra-wideband (UWB) 5G communications due to its multiband characterization and optimized rejection bands. The antenna is built on an FR-4 substrate and powered via a 50-Ω microstrip feed line linked to the right bowtie’s side. The bowtie’s left side is coupled via a shorting pin to a partial ground at the antenna’s back side. A gradually increasing meandering microstrip line is connected to both sides of the bowtie to enhance the rejection and operating bands. The designed antenna has seven operating frequency bands of (2.43–3.03) GHz, (3.71–4.23) GHz, (4.76–5.38) GHz, (5.83–6.54) GHz, (6.85–7.44) GHz, (7.56–8.01) GHz, and (9.27–13.88) GHz. The simulated scattering parameter S11 reveals six rejection bands with percentage bandwidths of 33.87%, 15.73%, 11.71, 7.63%, 6.99%, and 12.22%, respectively. The maximum gain of the proposed antenna is 4.46 dB. The suggested antenna has been built, and the simulation and measurement results are very similar. The reported antenna is expanded to a four-element design to investigate its MIMO characteristics. / Partially funded by British Council “2019 UK-China-BRI Countries Partnership Initiative” program, with project titled “Adapting to Industry 4.0 oriented International Education and Research Collaboration.

Multi-band

UWB

5G communications

Sub-6 GHz

Notches

Bowtie-shaped

Multiband

MIMO

Time-domain analysis

A miniaturized triple-band antenna based on square split ring for IoT applications

Abdulzahra, D.H., Alnahwi, F., Abdullah, A.S., Al-Yasir, Yasir I.A., Abd-Alhameed, Raed

07 October 2022

Yes / This article presents a miniaturized triple-band antenna for Internet of Things (IoT) applications. The miniaturization is achieved by using a split square ring resonator and half ring resonator. The antenna is fabricated on an FR4 substrate with dimensions of (33 × 22 × 1.6) mm3. The proposed antenna resonates at the frequencies 2.4 GHz, 3.7 GHz, and 5.8 GHz for WLAN and WiMax applications. The obtained −10 dB bandwidth for the three bands of the proposed antenna are 300 MHz, 360 MHz, and 900 MHz, respectively. The measured reflection coefficient values of the proposed antenna corresponding to each resonant frequency are equal to −14.772 dB, −20.971 dB, and −28.1755 dB, respectively. The measured gain values are 1.43 dBi, 0.89 dBi, and 1 dBi, respectively, at each resonant frequency. There is a good agreement between the measured and simulated results, and both show an omnidirectional radiation pattern at each of the antenna resonant frequencies that is suitable for IoT portable devices.

Multiband antenna

IoT applications

Reflection coefficient

Monopole

Split ring resonator (SRR)

Frequency Generalized MC-CDMA Systems and Performance over Multiband Channels and with Multiple Level Orthogonal (MLO) Codes

Zhang, Jingtao

January 2010

No description available.

MC-CDMA

FG-MC-CDMA

multicarrier

OFDM

CDMA

power allocation

multiband

multi-level orthogonal codes (MLO)

A GENERALIZED ARCHITECTURE FOR THE FREQUENCY-SELECTIVE DIGITAL PREDISTORTION LINEARIZATION TECHNIQUE

Kim, Ji Woo

19 July 2012

No description available.

Electrical Engineering

digital predistortion

DPD

multiband linearization

memory effect

power amplifier

Exotic superconductivity associated with parity symmetry breaking / パリティ対称性の破れに関連するエキゾチック超伝導

Kanasugi, Shota

23 March 2022

京都大学 / 新制・課程博士 / 博士(理学) / 甲第23688号 / 理博第4778号 / 新制||理||1684(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 柳瀬 陽一, 教授 川上 則雄, 教授 松田 祐司 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

Unconventional superconductivity

Parity symmetry breaking

Ferroelectricity

Odd-frequency superconductivity

Multiband superconductivity

400

MAC and Physical Layer Design for Ultra-Wideband Communications

Kumar, Nishant

25 May 2004

Ultra-Wideband has recently gained great interest for high-speed short-range communications (e.g. home networking applications) as well as low-speed long-range communications (e.g. sensor network applications). Two flavors of UWB have recently emerged as strong contenders for the technology. One is based on Impulse Radio techniques extended to direct sequence spread spectrum. The other technique is based on Orthogonal Frequency Division Multiplexing. Both schemes are analyzed in this thesis and modifications are proposed to increase the performance of each system. For both schemes, the issue of simultaneously operating users has been investigated. Current MAC design for UWB has relied heavily on existing MAC architectures in order to maintain backward compatibility. It remains to be seen if the existing MACs adequately support the UWB PHY (Physical) layer for the applications envisioned for UWB. Thus, in this work we propose a new MAC scheme for an Impulse Radio based UWB PHY, which is based on a CDMA approach using a code-broker in a piconet architecture. The performance of the proposed scheme is compared with the traditional CSMA scheme as well as the receiver-based code assignment scheme. A new scheme is proposed to increase the overall performance of the Multiband-OFDM system. Two schemes proposed to increase the performance of the system in the presence of simultaneously operating piconets (namely Half Pulse Repetition Frequency and Time spreading) are studied. The advantages/disadvantages of both of the schemes are discussed. / Master of Science

Impulse Radio

Ultra-Wideband

Multiband-OFDM

Medium Access Control

CDMA

CSMA

Electronic correlation and magnetism in multi-band Kondo lattice models

Sharma, Anand

09 July 2009

Die vorliegende Arbeit untersucht elektronische Korrelationseffekte in Realsubstanzen wie Europium-Sulphid (EuS) und Gadolinium-Nitrid (GdN). Es wird dazu eine Kombination von vielteilchentheoretischen Analysen der Spin-Austauschwechselwirkung zwischen itineranten Bandelektronen und lokalisierten 4f-Momenten, durchgefuehrt im Rahmen eines Mehr-Band-Kondo-Gitter-Modells (KLM), mit first-principles (T=0) Bandstrukturrechnungen vorgeschlagen. Die Ein-Teilchen-Energien (hopping-Integrale), die als Energie-Matrix in den Mehr-Band-Hamilton-Operator eingehen, werden einer TB-LMTO-ASA entnommen. Die interessierenden physikalischen Eigenschaften wie die Quasiteilchen-Spektraldichte und die Quasiteilchen-Zustandsdichte werden mit der Bewegu-ngsgleichungs-Methode Greencher Funktionen berechnet. Dazu wird fuer die gesuchte Mehr-Band-Selbstenergie der itinerantenLadungstraeger als Verallgemeinerung des sogenannten Interpolating Selfenergy Approach (ISA) ein Ansatz vorgeschlagen. Es stellt sich heraus, dassdas elektronische Anregungsspektrum durch die Austausch-Kopplung an das lokalisierte Momenten-System eine spektakulaere Temperaturabhaengigkeit aufweist, in Uebereinstimmung mit vorliegenden experimentellen Beobachtungen. Stark temperaturbestimmte Korrelationseffekte werden registriert, z.B. eine mit fallender Temperatur in der ferromagnetischen Phase auftretende Rotverschiebung der unteren Leitungsbandkante in guter Uebereinstimmung mit experimentellen Daten. Um die reinen f-Spin-Korrelationen zu beschreiben, wird eine modifizierte RKKY-Theorie fuer Mehr-Band-Systeme entwickelt, wobei durch Ausmitteln der elektronischen Freiheitsgrade das Mehr-Band KLM auf ein effektives Heisenberg-Modell abgebildet wird. Mit einer RPA-Theorie wird das effektive Heisenberg-Modell auf Aussagen zu zentralen magnetischen Eigenschaften wie Curie-Temperatur und Magnetisierungskurve analysiert. Durch gezielte Variation der Systemparameter wird die Brauchbarkeit des Modells getestet. / This dissertation deals with a combination of many-body evaluation of a spin exchange interaction between the itinerant electrons and localized 4f moments on a periodic lattice, i.e. within the so-called multi-band Kondo lattice model (KLM), and the T=0 first principles calculations in order to study the electronic correlation effects in real materials like Europium Sulphide (EuS) and Gadolinium Nitride (GdN).The single-particle ground state energy or hopping integral acting as an input in the many-body part is obtained using tight binding linear muffin-tin orbital within atomic sphere approximation (TB-LMTO-ASA) program and is a matrix in general. The physical properties of interest like the quasi-particle spectral density and quasi-particle density of states are calculated within the Green function theory and the equation of motion method. In order to do so the required multi-band self-energy of the band electrons istaken as an ansatz, i.e. the so-called interpolating self-energy approach (ISA). The electronic excitation spectrum gets a striking temperature dependence by its exchange coupling to the localized spin system. We observe very strong temperature dependent electronic correlation effects in GdN and the calculated red-shift of the lower conduction band is in close comparison with experiment. In order to determine the pure f-spin correlations, we develop the multi-band modified RKKY theory. The central idea of this theory beingto average out the itinerant electron degrees of freedom from the spin-exchange interaction and map the latter on to an effective Heisenberg model. Using this procedure, we determine the magnetic properties of the system like Curie temperature (within Random Phase Approximation) while calculating the chemical potential and magnetization within a self consistent scheme for various configurations of system parameters.

EuS

Multiband Kondo gitter modell

Dichte funktional theorie

elektronisch korrelation und magnetismus

GdN.

Multiband Kondo lattice model

Density functional theory

electronic correlation and magnetism

EuS

GdN.

530 Physik

29 Physik, Astronomie

ddc:530

Détection de changement par fusion d'images de télédétection de résolutions et modalités différentes / Fusion-based change detection for ng images of differemote sensirent resolutions and modalities

Ferraris, Vinicius

26 October 2018

La détection de changements dans une scène est l’un des problèmes les plus complexes en télédétection. Il s’agit de détecter des modifications survenues dans une zone géographique donnée par comparaison d’images de cette zone acquises à différents instants. La comparaison est facilitée lorsque les images sont issues du même type de capteur c’est-à-dire correspondent à la même modalité (le plus souvent optique multi-bandes) et possèdent des résolutions spatiales et spectrales identiques. Les techniques de détection de changements non supervisées sont, pour la plupart, conçues spécifiquement pour ce scénario. Il est, dans ce cas, possible de comparer directement les images en calculant la différence de pixels homologues, c’est-à-dire correspondant au même emplacement au sol. Cependant, dans certains cas spécifiques tels que les situations d’urgence, les missions ponctuelles, la défense et la sécurité, il peut s’avérer nécessaire d’exploiter des images de modalités et de résolutions différentes. Cette hétérogénéité dans les images traitées introduit des problèmes supplémentaires pour la mise en œuvre de la détection de changements. Ces problèmes ne sont pas traités par la plupart des méthodes de l’état de l’art. Lorsque la modalité est identique mais les résolutions différentes, il est possible de se ramener au scénario favorable en appliquant des prétraitements tels que des opérations de rééchantillonnage destinées à atteindre les mêmes résolutions spatiales et spectrales. Néanmoins, ces prétraitements peuvent conduire à une perte d’informations pertinentes pour la détection de changements. En particulier, ils sont appliqués indépendamment sur les deux images et donc ne tiennent pas compte des relations fortes existant entre les deux images. L’objectif de cette thèse est de développer des méthodes de détection de changements qui exploitent au mieux l’information contenue dans une paire d’images observées, sans condition sur leur modalité et leurs résolutions spatiale et spectrale. Les restrictions classiquement imposées dans l’état de l’art sont levées grâce à une approche utilisant la fusion des deux images observées. La première stratégie proposée s’applique au cas d’images de modalités identiques mais de résolutions différentes. Elle se décompose en trois étapes. La première étape consiste à fusionner les deux images observées ce qui conduit à une image de la scène à haute résolution portant l’information des changements éventuels. La deuxième étape réalise la prédiction de deux images non observées possédant des résolutions identiques à celles des images observées par dégradation spatiale et spectrale de l’image fusionnée. Enfin, la troisième étape consiste en une détection de changements classique entre images observées et prédites de mêmes résolutions. Une deuxième stratégie modélise les images observées comme des versions dégradées de deux images non observées caractérisées par des résolutions spectrales et spatiales identiques et élevées. Elle met en œuvre une étape de fusion robuste qui exploite un a priori de parcimonie des changements observés. Enfin, le principe de la fusion est étendu à des images de modalités différentes. Dans ce cas où les pixels ne sont pas directement comparables, car correspondant à des grandeurs physiques différentes, la comparaison est réalisée dans un domaine transformé. Les deux images sont représentées par des combinaisons linéaires parcimonieuses des éléments de deux dictionnaires couplés, appris à partir des données. La détection de changements est réalisée à partir de l’estimation d’un code couplé sous condition de parcimonie spatiale de la différence des codes estimés pour chaque image. L’expérimentation de ces différentes méthodes, conduite sur des changements simulés de manière réaliste ou sur des changements réels, démontre les avantages des méthodes développées et plus généralement de l’apport de la fusion pour la détection de changements / Change detection is one of the most challenging issues when analyzing remotely sensed images. It consists in detecting alterations occurred in a given scene from between images acquired at different times. Archetypal scenarios for change detection generally compare two images acquired through the same kind of sensor that means with the same modality and the same spatial/spectral resolutions. In general, unsupervised change detection techniques are constrained to two multiband optical images with the same spatial and spectral resolution. This scenario is suitable for a straight comparison of homologous pixels such as pixel-wise differencing. However, in somespecific cases such as emergency situations, punctual missions, defense and security, the only available images may be of different modalities and of different resolutions. These dissimilarities introduce additional issues in the context of operational change detection that are not addressedby most classical methods. In the case of same modality but different resolutions, state-of-the artmethods come down to conventional change detection methods after preprocessing steps appliedindependently on the two images, e.g. resampling operations intended to reach the same spatialand spectral resolutions. Nevertheless, these preprocessing steps may waste relevant informationsince they do not take into account the strong interplay existing between the two images. The purpose of this thesis is to study how to more effectively use the available information to work with any pair of observed images, in terms of modality and resolution, developing practicalcontributions in a change detection context. The main hypothesis for developing change detectionmethods, overcoming the weakness of classical methods, is through the fusion of observed images. In this work we demonstrated that if one knows how to properly fuse two images, it is also known how to detect changes between them. This strategy is initially addressed through a change detection framework based on a 3-step procedure: fusion, prediction and detection. Then, the change detection task, benefiting from a joint forward model of two observed images as degradedversions of two (unobserved) latent images characterized by the same high spatial and highspectral resolutions, is envisioned through a robust fusion task which enforces the differencesbetween the estimated latent images to be spatially sparse. Finally, the fusion problem isextrapolated to multimodal images. As the fusion product may not be a real quantity, the process is carried out by modelling both images as sparse linear combinations of an overcomplete pair of estimated coupled dictionaries. Thus, the change detection task is envisioned through a dual code estimation which enforces spatial sparsity in the difference between the estimated codes corresponding to each image. Experiments conducted in simulated realistically and real changes illustrate the advantages of the developed method, both qualitatively and quantitatively, proving that the fusion hypothesis is indeed a real and effective way to deal with change detection

Détection de changements

Fusion d’image

Multimodalité

Image optique multibande

Image radar

Change detection

Image fusion

Multimodality

Multiband optical image

Radar image