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 Capacitively loaded Antenna for use in Mobile Handsets

Elfergani, Issa T., Abd-Alhameed, Raed, See, Chan H., Child, Mark B., Excell, Peter S.

08 November 2010

Yes / A tuneable slotted patch antenna design is presented and verified for use in the DCS, PCS and UMTS bands. The tuning circuit consists of two varactor diodes with some passive components, and is integrated fully with the r radiator patch, with the varactors occupying different locations over the slot. The tuning does not require any further modification to the patch or feed geometry. Good agreement is observed between the predicted and observed impedance bandwidth, return loss, gain and radiation pattern, throughout the range 1.70 GHz-2.05 GHz.

Tunable antennas

Loaded antennas

Mobile handset

Varactor diodes

Bandwidth enhanced antennas for mobile terminals and multilayer ceramic packages

Komulainen, M. (Mikko)

12 June 2009

Abstract In this thesis, bandwidth (BW) enhanced antennas for mobile terminals and multilayer ceramic packages are presented. The thesis is divided into two parts. In the first part, electrically frequency-tunable mobile terminal antennas have been studied. The first three antennas presented were of a dual-band planar inverted-F type (PIFA) and were tuned to operate in frequency bands appropriate to the GSM850 (824–894 MHz), GSM900 (880–960 MHz), GSM1800 (1710–1880 MHz), GSM1900 (1850–1990 MHz) and UMTS (1920–2170 MHz) cellular telecommunication standards with RF PIN diode switches. The first antenna utilized a frequency-tuning method developed in this thesis. The method was based on an integration of the tuning circuitry into the antenna. The tuning of the second antenna was based on a switchable parasitic antenna element. By combining the two frequency-tuning approaches, a third PIFA could be switched to operate in eight frequency bands. The planar monopole antennas researched were varactor-tunable for digital television signal reception (470–702 MHz) and RF PIN diode switchable dual-band antenna for operation at four cellular bands. The key advantage of the former antenna was a compact size (0.7 cm3), while for the latter one, a tuning circuit was implemented without using separate DC wiring for controlling the switch component. The second part of the thesis is devoted to multilayer ceramic package integrated microwave antennas. In the beginning, the use of a laser micro-machined embedded air cavity was proposed to enable antenna size to impedance bandwidth (BW) trade-off for a microwave microstrip in a multilayer monolithic ceramic media. It was shown that the BW of a 10 GHz antenna fabricated on a low temperature co-fired ceramic (LTCC) substrate could be doubled with this technique. Next, the implementation of a compact surface mountable LTCC antenna package operating near 10 GHz was described. The package was composed of a BW optimized stacked patch microstrip antenna and a wide-band vertical ball grid array (BGA)-via interconnection. Along with the electrical performance optimization, an accurate circuit model describing the antenna structure was presented. Finally, the use of low-sintering temperature non-linear dielectric Barium Strontium Titanate (BST) thick films was demonstrated in a folded slot antenna operating at 3 GHz and frequency-tuned with an integrated BST varactor.

LTCC

frequency-tunable antennas

microstrip antennas

mobile terminals

package integration

planar inverted-F antennas

planar monopole antennas

slot antennas

small antennas

TUNABLE ANTENNAS FOR CLOSED-LOOP SYSTEMS

Chowki, ManiChandana, Nagaiahgari, Shrutha Keerthi Reddy

January 2023

Tunable antennas have emerged as a promising technology to address the challenges of achieving optimal performance across a wide range of frequencies. This abstract presents a study focused on designing and implementing an ideal antenna system design within a closed-loop system. Background. Tunable antennas offer a solution for achieving efficient signal transmission and reception over a broad spectrum. Traditionally fixed-frequency antennas have limitations in terms of bandwidth and efficiency, making them unfit for applications requiring adaptability to varying frequencies. The integration of tunable components in antenna systems results in greater flexibility and improved performance. Objectives. The main objective of this research is to evaluate and determine the ideal antenna design for closed-loop antenna systems which achieves maximum frequency coverage and efficiency. This involves the design of an architecture that seamlessly integrates components. Methods. The experimental methodology involves designing an antenna system design. The selected components are interconnected in a closed loop, allowing continuous monitoring and adjustment of the antenna’s characteristics. The Micro Controlling Unit (MCU) is programmed using the Arduino Integrated Development Environment (IDE), serves as the controller for managing the antenna tuner’s settings based on real-time feedback from the directional coupler and power detector. The bi-directional logic level converter ensures proper voltage compatibility between the MCU and the antenna tuner. Results. The results of the study showed that the proposed antenna system architecture was able to achieve the desired goals. The implemented closed-loop system demonstrates significant enhancements in frequency coverage and efficiency of the selected antenna. The antenna system was also able to maintain its efficiency even when the environment changed. Conclusions. The experimental results show that in closed-loop systems the performance of an antenna is optimised. The integration of the components enables dynamic frequency tuning, by enhancing the antenna’s maximum frequency coverage and efficiency. The results underscore the potential of tunable antennas in revolutionizing wireless communication systems, showing the way for more adaptable and high-performance devices in various applications.

Closed-loop Systems

Tunable Antennas

Radio Frequency (RF)

MCU in closed-loop Systems

Adaptable Tuning

Telecommunications

Telekommunikation

Antennes et dispositifs hyperfréquences millimétriques ultrasouples reconfigurables à base de Microsystèmes Magnéto-Electro-Mécaniques (MMEMS) : conception, réalisation, mesures / Ultrasoft reconfigurable millimeter-wave antennas and devices based on Magneto-Electro-Mechanical Microsystems (MMEMS) : design, fabrication, measurements

Hage-Ali, Sami

30 September 2011

Il y a à l'heure actuelle un grand besoin d'antennes reconfigurables dans la bande des 60 GHz pour des applications de télédétection et de télécommunications sans fil très hauts débits. Les solutions traditionnelles de reconfiguration sont basées sur des semiconducteurs ou des composants RF-MEMS, qui connaissent un coût, une complexité et des pertes croissantes en bande millimétrique. Dans cette thèse, une approche originale a été développée : elle est basée sur la reconfiguration mécanique d'antennes et dispositifs millimétriques microrubans sur substrat élastomère ultrasouple PDMS grâce à des actionneurs MEMS grands déplacements. Premièrement, les choix de conception, la technique de simulation éléments finis (HFSS), et surtout la microfabrication d'antennes sur membrane PDMS ainsi que les techniques de mesure en impédance et rayonnement sont abordés.Deux axes ont ensuite été étudiés : les antennes accordables en fréquence, et les antennes et composants pour le balayage angulaire (déphaseurs et antennes à balayage mécanique de type scanner). Des procédés technologiques innovants ont été développés (reports de métallisations épaisses biocompatibles et d'aimants permanents en couches minces sur membrane PDMS) et différentes techniques d'actionnement (pneumatique, magnétique, par électromouillage) ont été mises en œuvre. Les performances en terme d'accord en fréquence (8,2 %) et de balayage angulaire (-90/+100°) dépassent l'état de l'art des antennes du même type en bande millimétrique, et ceci en utilisant une technologie peu complexe, ultra bas-coût et prometteuse pour la montée en fréquence. / There is currently an increasing need for reconfigurable antennas in the 60 GHz band for remote sensing applications and wireless communications. Traditional reconfiguration solutions are based on semiconductors or RF-MEMS but these components face cost, complexity and losses issues at millimeter-waves.In this thesis, an original approach was developed: it is based on the mechanical reconfiguration of millimeter-wave microstrip antennas and devices printed on ultrasoft PDMS substrates, thank to large displacements MEMS actuators. First, the design choices, the finite element simulation technique (HFSS), and the microfabrication of antennas supported by PDMS membranes as well as the impedance and radiation measurements techniques have been discussed. Two axis have then been studied: frequency-tunable antennas, and beam-steering components (phase shifters and "scanner" type antennas). Innovative technological processes were developed (transfer of biocompatible metal patterns and permanent magnet thin films on PDMS membranes) and several actuation techniques (pneumatic, magnetic, electrowetting) were implemented. Performances in terms of frequency tuning (8.2%) and scan angles (-90 / 100 °) are beyond the state of the art for similar antennas in the millimeter-wave band, and are achieved by using a very simple, ultra low-cost technique that is expected to be effective at even higher frequencies.

Antenne accordable en fréquence

Elastomère PDMS

Antenne millimétrique

Antenne reconfigurable

Polymère ultrasouple

Electronique souple

Balayage angulaire

Déphaseur

Electromouillage

Microsystème magnétique

Frequency-tunable antennas

PDMS elastomer

Millimeter-wave antenna

Reconfigurable antenna

Ultrasoft polymer

Soft electronics

Beam steering

Phase shiffer

Electrowetting

Magnetic microsystem