Frequency Tuned Planar Inverted F Antenna with L Shaped Slit Design for Wide Frequency Range

Elfergani, Issa T., Hussaini, Abubakar S., Abd-Alhameed, Raed, See, Chan H., Abusitta, M.M., Hraga, Hmeda I., Alhaddad, A.G., Rodriguez, Jonathan

22 March 2011

Yes / A frequency tuned antenna has been designed to meet the coverage requirements of the DCS, PCS, UMTS and WLAN bands. The antenna consists of a main patch, and a planar inverted L (PIL) slot. The radiator patch is fed, and shorted, using simple feed lines with broadband characteristics. The handset represents the finite ground plane, and a varactor diode is mounted across the middle of the slot for tuning purposes. Initial tuning was obtained by placing lumped capacitors, instead of the varactor, over the radiator. Good agreement is obtained between the predicted and measured input return loss, gain and radiation pattern over the tuned frequency range. / MSCRC

Antennas

Tunable antennas

Varactor diode

A Reflection Type Phase Shifter for iNET Phase Array Antenna Applications

Shrestha, Bikram

10 1900

ITC/USA 2010 Conference Proceedings / The Forty-Sixth Annual International Telemetering Conference and Technical Exhibition / October 25-28, 2010 / Town and Country Resort & Convention Center, San Diego, California / In this article we present results from modeling and simulation of a L-band reflection type phase shifter (RTPS) that provides continuous phase shift of 0° to 360°. The RTPS circuit uses a 90º hybrid coupler and two reflective load networks consisting of varactor diodes and inductors. Proper design of 90° hybrid coupler is critical in realizing maximum phase shift. The RTPS circuit implemented on a Rogers Duroid substrate is large in size. We discuss methods to reduce the size of L-band RTPS.

varactor diode

hybrid coupler

phase shift

A MEMS approach to submillimetre-wave frequency multiplier design

Partridge, James G.

January 2000

No description available.

621.31042

Wideband Tunable PIFA Antenna with Loaded Slot Structure for Mobile Handset and LTE Applications

Elfergani, Issa T., Hussaini, Abubakar S., Rodriguez, Jonathan, See, Chan H., Abd-Alhameed, Raed

04 1900

Yes / A compact planar inverted F antenna (PIFA) with a tuneable frequency response is presented. Tuning of the resonant frequency is realized by loading a varactor on an embedded slot of the proposed antenna structure without further optimizing other antenna geometry parameters. The antenna exhibits a wide frequency range from 1570 to 2600 MHz with a good impedance matching (S11 ≤ -10dB) covering the GPS, PCS, DCS, UMTS, WLAN and LTE systems. To validate the theoretical model and design concept, the antenna prototype was fabricated and measured. The compact size of the antenna is 15mm × 8mm × 3mm, which makes this antenna a good candidate for mobile handset and wireless communication applications.

Tunable antenna

Varactor diode

PIFA antenna

Printed monopole antenna with tunable band-notched characteristic for use in mobile and ultra-wide band applications

Elfergani, Issa T., Hussaini, Abubakar S., See, Chan H., Abd-Alhameed, Raed, McEwan, Neil J., Zhu, Shaozhen (Sharon), Rodriguez, Jonathan, Clarke, Roger W.

06 1900

Yes / A tunable band-notch printed monopole antenna is presented, exhibiting a wide impedance bandwidth from 1.5 to 5.5 GHz with good impedance matching (VSWR ≤ 2) and a tunable rejected frequency band from 2.38 to 3.87 GHz. The band-notching is achieved by adding an inner chorded crescent element within a driven element of a similar shape. By varying the value of the varactor which is placed between the inner and outer arcs, the desired variable rejected can be obtained. Simulated and measured results show wide impedance bandwidth with a tunable band notch, stable radiation patterns, and consistent nearly constant gain. The antenna is suitable for mobile and portable applications.

Wideband antenna

Tunable notch

Varactor diode

Monopole antenna

Compact and closely spaced tunable printed F-slot multiple-input–multiple-output antenna system for portable wireless applications with efficient diversity

Elfergani, Issa T., Hussaini, Abubakar S., Rodriguez, Jonathan, Abd-Alhameed, Raed, See, Chan H., Jan, Naeem A., Zhu, Shaozhen (Sharon), McEwan, Neil J.

18 August 2014

Yes / In this work, miniaturized tunable two-antenna MIMO systems composed of printed F-slot shaped is developed to operate in the GPS, PCS, DCS and UMTS bands. The two-element MIMO antenna occupies a volume of 50 × 37.5 ×1.6 mm3, and is printed on an FR4 substrate. Initially, the frequency tunability of the MIMO antennas was verified by lumped capacitors with values between 0.75 to 2.75 pF to achieve a tuning range from 1.55 to 2.07GHz while the low mutual coupling between the radiators was accomplished by adding an I-shaped branch to a cut-away ground plane. The two antennas are then loaded with varactors to simultaneously achieve miniaturization and tunability. Simulation and measurement results demonstrate the successful implementation of a tunable MIMO with coupling reduction mechanism for a portable handheld wireless transceiver. The channel capacity of the proposed antenna is investigated and found to be close to that of an un-correlated system with efficient diversity in which the mutual coupling across the full bandwidth was better than -13dB. Owing to the compact size and ease of manufacture, the proposed antennas can be a promising solution for adaptive MIMO systems in handheld devices. / This work has been performed in the framework of ARTEMOS project under work programme ENIAC JU 2010 and FCT (Fundação para a Ciência e Tecnologia) .The authors would like to thank Datong PLC (Leeds LS18 4EG, West Yorkshire, U.K.), for their financial support of the Knowledge Transfer Partnership (KTP No: 008734).

Multiple-Input multiple-output

MIMO

Tunable antenna

Varactor diode

A Frequency Tunable PIFA Design for Handset Applications

Elfergani, Issa T., Abd-Alhameed, Raed, Bin-Melha, Mohammed S., See, Chan H., Zhou, Dawei, Child, Mark B., Excell, Peter S.

January 2010

Yes / A frequency tunable planar inverted F antenna (PIFA) is presented for use in the following bands: DCS, PCS, and UMTS. Initially, the tuning was achieved by placing a lumped capacitor, with values in the range of 1.5 to 4 pF, along the slot of the radiator. The final tuning circuit uses a varactor diode, and discrete lumped elements are fully integrated with the antenna. The antenna prototype is tunable over from 1850 MHz to 2200 MHz, with an associated volume of 21×13.5×5 mm3, making it suitable for potential integration in a commercial handset or mobile user terminal.

Slot antenna

Varactor diode

Planar inverted F antenna (PIFA)

Síntese e projeto de filtros reconfiguráveis de microondas utilizando ressoadores tipo patch. / Synthesis and design of tunable microwave bandpass filters using planar patch resonators.

Ariana Maria da Conceição Lacorte Caniato Serrano

02 May 2011

O objetivo desta tese é o projeto e a síntese de filtros passa-faixa sintonizáveis em frequências de micro-ondas utilizando ressoadores planares tipo patch. As características dos filtros projetados, tais como frequência central, largura de banda e/ou seletividade, são eletronicamente ajustadas por uma tensão de controle DC. Uma metodologia para a concepção e síntese de filtros sintonizáveis patch é desenvolvida e aplicada a dois filtros com topologias triangular e circular. A metodologia fornece técnicas para extrair o esquema de acoplamento que modela o comportamento do filtro e as equações necessárias para calcular a matriz de acoplamento. Então, a resposta teórica do filtro resultante da análise dos coeficientes da matriz de acoplamento é comparada com os resultados das simulações completas. As simulações completas combinam os resultados da simulação eletromagnética 3D do layout do filtro com os resultados da simulação elétrica dos dispositivos de ajuste, representados por seu modelo elétrico equivalente de elementos discretos. Isso permite o correto modelamento das características do ajuste e a definição de seus limites. A fim de validar a metodologia, os filtros patch sintonizáveis são fabricados usando tecnologia de micro-ondas de circuito Integrado (MIC) sobre substratos flexíveis. As dimensões mínimas são maiores do que 0,5 mm, garantindo um processo de fabricação de baixo custo. O primeiro filtro é um filtro patch dual-mode sintonizável que utiliza um ressonador triangular com duas fendas perpendiculares. A frequência central e a largura de banda do filtro podem ser ajustadas individualmente por um controle independente de cada modo fundamental degenerado. O controle dos modos é feito através de diodos varactor montados nas fendas do ressoador patch. O filtro apresenta variação de 20 % de frequência central de 2,9 GHz a 3,5 GHz. A banda relativa de 3 dB varia de 4 % a 12 %. Duas tensões de polarização DC diferentes variando de 2,5 V a 22 V são usadas para ajustar este filtro. O segundo filtro é um filtro patch triple-mode sintonizável que utiliza um ressoador circular com quatro fendas radiais, nas quais são conectados os diodos varactor. A frequência central e a largura de banda deste filtro variam simultaneamente. O filtro apresenta 27 % de variação da frequência central de 1,8 GHz a 2,35 GHz com variação concomitante da largura de banda relativa de 8,5 % para 26 %. Apenas uma única tensão de polarização DC variando de 0,5 V a 20 V é usada para sintonizar este filtro. Ambos os filtros são capazes de lidar com níveis de potência de no mínimo +14,5 dBm (filtro com ressoador triangular) e +12,9 dBm (filtro com ressoador circular). / The objective of this thesis is the design and synthesis of tunable bandpass filters at microwave frequencies using planar patch resonators. The characteristics of the designed filters, such as center frequency, bandwidth, and/or selectivity, are electronically adjusted by a DC voltage control. A methodology for the design and synthesis of tunable patch filters is developed and applied to two filters with triangular and circular topologies. The methodology provides techniques to extract the coupling scheme that models the filter behavior and the necessary equations for calculating the corresponding coupling matrix. Then, the theoretical filter response resulting from the analysis of the coupling matrix coefficients is compared to the results of complete simulations. The complete simulations combine the results of the 3D electromagnetic (EM) simulation of the filter layout with the results of the electrical simulation of the tuning devices, represented by their lumped elements equivalent model. This allows the correct model of the tuning effect and the definition of the tuning possibilities and limits. In order to validate the methodology, the tunable patch filters are fabricated using Microwave Integrated Circuit (MIC) technology on flexible substrates. The minimum dimensions are greater than 0.5 mm, ensuring a low cost fabrication process. The first filter is a tunable dual-mode patch filter using a triangular resonator with two perpendicular slots. The central frequency and the bandwidth of the filter are individually tuned by independently controlling each degenerate fundamental mode. The topology with uncoupled modes allows the control of each resonant mode frequency by varactor diodes mounted across the slots of the patch resonator. This filter presents a center frequency tuning range of 20 %, varying from 2.9 GHz to 3.5 GHz. The FBW 3dB can be varied from 4 % to 12 %. Two different DC bias voltages ranging from 2.5 V to 22 V are used to tune this filter. The second filter is a tunable triple-mode patch filter using a circular resonator with four slots, across which the varactor diodes are connected. The center frequency and bandwidth of this filter vary simultaneously. This filter presents a center frequency tuning range of 27 %, varying from 1.8 GHz to 2.35 GHz, changing concomitantly with the bandwidth from 8.5 % to 26 %. Only a single DC bias voltage ranging from 0.5 V to 20 V is used to tune the filter. Both filters are able to handle power levels as high as +14.5 dBm (triangular patch filter) and +12.9 dBm (circular patch filter).

Diodo varactor

Filtros reconfiguráveis

Ressoador multimodo

Ressoadores patch

Multimode resonator

Patch resonators

Tunable filters

Varactor diode

Síntese e projeto de filtros reconfiguráveis de microondas utilizando ressoadores tipo patch. / Synthesis and design of tunable microwave bandpass filters using planar patch resonators.

Serrano, Ariana Maria da Conceição Lacorte Caniato

02 May 2011

O objetivo desta tese é o projeto e a síntese de filtros passa-faixa sintonizáveis em frequências de micro-ondas utilizando ressoadores planares tipo patch. As características dos filtros projetados, tais como frequência central, largura de banda e/ou seletividade, são eletronicamente ajustadas por uma tensão de controle DC. Uma metodologia para a concepção e síntese de filtros sintonizáveis patch é desenvolvida e aplicada a dois filtros com topologias triangular e circular. A metodologia fornece técnicas para extrair o esquema de acoplamento que modela o comportamento do filtro e as equações necessárias para calcular a matriz de acoplamento. Então, a resposta teórica do filtro resultante da análise dos coeficientes da matriz de acoplamento é comparada com os resultados das simulações completas. As simulações completas combinam os resultados da simulação eletromagnética 3D do layout do filtro com os resultados da simulação elétrica dos dispositivos de ajuste, representados por seu modelo elétrico equivalente de elementos discretos. Isso permite o correto modelamento das características do ajuste e a definição de seus limites. A fim de validar a metodologia, os filtros patch sintonizáveis são fabricados usando tecnologia de micro-ondas de circuito Integrado (MIC) sobre substratos flexíveis. As dimensões mínimas são maiores do que 0,5 mm, garantindo um processo de fabricação de baixo custo. O primeiro filtro é um filtro patch dual-mode sintonizável que utiliza um ressonador triangular com duas fendas perpendiculares. A frequência central e a largura de banda do filtro podem ser ajustadas individualmente por um controle independente de cada modo fundamental degenerado. O controle dos modos é feito através de diodos varactor montados nas fendas do ressoador patch. O filtro apresenta variação de 20 % de frequência central de 2,9 GHz a 3,5 GHz. A banda relativa de 3 dB varia de 4 % a 12 %. Duas tensões de polarização DC diferentes variando de 2,5 V a 22 V são usadas para ajustar este filtro. O segundo filtro é um filtro patch triple-mode sintonizável que utiliza um ressoador circular com quatro fendas radiais, nas quais são conectados os diodos varactor. A frequência central e a largura de banda deste filtro variam simultaneamente. O filtro apresenta 27 % de variação da frequência central de 1,8 GHz a 2,35 GHz com variação concomitante da largura de banda relativa de 8,5 % para 26 %. Apenas uma única tensão de polarização DC variando de 0,5 V a 20 V é usada para sintonizar este filtro. Ambos os filtros são capazes de lidar com níveis de potência de no mínimo +14,5 dBm (filtro com ressoador triangular) e +12,9 dBm (filtro com ressoador circular). / The objective of this thesis is the design and synthesis of tunable bandpass filters at microwave frequencies using planar patch resonators. The characteristics of the designed filters, such as center frequency, bandwidth, and/or selectivity, are electronically adjusted by a DC voltage control. A methodology for the design and synthesis of tunable patch filters is developed and applied to two filters with triangular and circular topologies. The methodology provides techniques to extract the coupling scheme that models the filter behavior and the necessary equations for calculating the corresponding coupling matrix. Then, the theoretical filter response resulting from the analysis of the coupling matrix coefficients is compared to the results of complete simulations. The complete simulations combine the results of the 3D electromagnetic (EM) simulation of the filter layout with the results of the electrical simulation of the tuning devices, represented by their lumped elements equivalent model. This allows the correct model of the tuning effect and the definition of the tuning possibilities and limits. In order to validate the methodology, the tunable patch filters are fabricated using Microwave Integrated Circuit (MIC) technology on flexible substrates. The minimum dimensions are greater than 0.5 mm, ensuring a low cost fabrication process. The first filter is a tunable dual-mode patch filter using a triangular resonator with two perpendicular slots. The central frequency and the bandwidth of the filter are individually tuned by independently controlling each degenerate fundamental mode. The topology with uncoupled modes allows the control of each resonant mode frequency by varactor diodes mounted across the slots of the patch resonator. This filter presents a center frequency tuning range of 20 %, varying from 2.9 GHz to 3.5 GHz. The FBW 3dB can be varied from 4 % to 12 %. Two different DC bias voltages ranging from 2.5 V to 22 V are used to tune this filter. The second filter is a tunable triple-mode patch filter using a circular resonator with four slots, across which the varactor diodes are connected. The center frequency and bandwidth of this filter vary simultaneously. This filter presents a center frequency tuning range of 27 %, varying from 1.8 GHz to 2.35 GHz, changing concomitantly with the bandwidth from 8.5 % to 26 %. Only a single DC bias voltage ranging from 0.5 V to 20 V is used to tune the filter. Both filters are able to handle power levels as high as +14.5 dBm (triangular patch filter) and +12.9 dBm (circular patch filter).

Diodo varactor

Filtros reconfiguráveis

Multimode resonator

Patch resonators

Ressoador multimodo

Ressoadores patch

Tunable filters

Varactor diode

Reconfigurable Band-pass Comb-line Filter Design

Li, Jinjing

January 2020

No description available.

Electrical Engineering