Antenna Design for Ultra Wideband Application Using a New Multilayer Structure

Abstract — As wireless communication applications require more and more bandwidth, the demand for wideband antennas increases as well. For instance, the ultra wideband radio (UWB) utilizes the frequency band of 3.1–10.6GHz.This paper presents a work carried out within UL-TRAWAVES in the area of antenna design and analysis. A new multilayer microstrip antenna is introduced using Stacked Multiresonator patches. In order to achieve suitable bandwidth, the antenna size is fine for mobile applications. The antenna is designed, optimized and simulated using Ansoft designer. In addition results and conclusions are presented. DOI: 10.2529/PIERS060531145356 1

Broadband circularly polarized slot antenna array using sequentially rotated technique for C-band applications

This paper presents the investigation results on a novel circularly polarized square slot antenna (CPSSA) array designed to operate at a frequency of 5.5 GHz. In order to realize the proposed antenna array, four miniature circular polarized square slot antennas are used with L-shape grounded strips located at the slots opposite corners. The antenna is fed by symmetric coplanar waveguide. The CPSSA element achieves a bandwidth of 18% for an axial ratio ≤ 3 dB. The CPSSA’s performance is further enhanced with the construction of a novel 2×2 antenna array that is designed using sequentially rotated feed technique. The 3 dB axial ratio of the array extends over 2 GHz with an impedance bandwidth of 33.33%. The CPSSA array was design operates over the frequency range between 4 and 6.87 GHz (52.8%) for VSWR<2 (1.71:1). Acceptable agreement between the simulation and measured results validates proposed design

A Compact WiMAX Band-Notched UWB MIMO Antenna with High Isolation

A multiple-input-multiple-output (MIMO) antenna is proposed for ultra-wideband (UWB) applications with high isolation capability. The proposed MIMO structure consists of two simple square monopole antennas with slotted ground plane structure with S11 bandwidth of 2.2 to 10.8 GHz and isolation level better than -30 dB. U-shaped and L-shaped slots are adopted to realize a notched band within 3.3-3.8 GHz relating to WiMAX frequency band. With the aim of enhancing the isolation between the monopole antennas, two parasitic structures are wisely embedded between the monopole antennas on backside of the substrate. The MIMO antenna prototype with a compact size of 25×38 mm2 is fabricated and measured. Based on the simulation and experimental results, the proposed MIMO antenna well-performs in ultra-wideband (UWB) band-notched MIMO application

Low-Loss and Dual-Band Filter Inspired by Glide Symmetry Principle Over Millimeter-Wave Spectrum for 5G Cellular Networks

This paper focuses on designing a dual-band, bandpass filter configuration inspired by glide-symmetric structures in a single plane. Geometry configuration of elliptical slots on both sides of single substrate generally affects electromagnetic fields as well as rejection bands. Easy fabrication with misalignment avoidance during assembly procedure unlike conventional structures based on gap waveguide technology, make them appropriate to use in electromagnetic devices. Parametric study on dispersion characteristics is carried out in this article to find out how rejection-bands are offered through breaking the symmetry. A method for producing symmetry is also suggested, which may be helpful for reconfigurable devices. Moreover, equivalent circuit model is demonstrated to get insight of the mechanism of the presented glide symmetry scheme. The transmission frequency ranges of two passbands with center frequencies of 19.74 GHz and 28.233 GHz are shown by the measured and calculated S- parameters of five unit-cell structures

Réseau d'antennes à fentes circulaires à polarisation circulaire utilisant un réseau d'alimentation à rotation séquentielle

International audienceThis paper presents the design, simulation, and measurement of two low-cost broadband circularly polarized (CP) printed antennas: a single element and an array at C band. The proposed single element antenna is excited by an L-shaped strip with a tapered end, located along the circular-slot diagonal line in the back plane. From the array experimental results, the 3 dB axial ratio bandwidth can reach as large as 1900 MHz which covers the 4.7 GHz to 6.6 GHz frequency band. In addition, the measured impedance bandwidth for reflection coefficient of less than-10 dB has the bandwidth with the frequency range from 4.2 GHz to 8 GHz (C Band application). The CP element achieves a bandwidth of 16.6% for an axial ratio less than 3 dB. The proposed antenna array can provide a peak gain of about 8.7 dBic at 5.9 GHz. Acceptable agreements between the simulation and measured results validates the proposed design.Cet article présente la conception, la simulation et la mesure de deux antennes imprimées à polarisation circulaire (CP) à large bande à faible coût : un élément unique et un réseau en bande C. L'antenne à élément unique proposée est excitée par une bande en forme de L avec une extrémité effilée, située le long de la ligne diagonale à fente circulaire dans le plan arrière. D'après les résultats expérimentaux du réseau, la bande passante de rapport axial de 3 dB peut atteindre 1900 MHz, ce qui couvre la bande de fréquences de 4,7 GHz à 6,6 GHz. De plus, la bande passante d'impédance mesurée pour un coefficient de réflexion inférieur à -10 dB a la bande passante avec la plage de fréquences de 4,2 GHz à 8 GHz (application en bande C). L'élément CP atteint une bande passante de 16,6% pour un rapport axial inférieur à 3 dB. Le réseau d'antennes proposé peut fournir un gain de crête d'environ 8,7 dBic à 5,9 GHz. Des accords acceptables entre la simulation et les résultats mesurés valident la conception proposée

The Optimization Design of a Novel Slotted Microstrip Patch Antenna with Multi-Bands Using Adaptive Network-Based Fuzzy Inference System

This paper attempts to apply an adaptive network-based fuzzy inference system (ANFIS) for analysis of the resonant frequency of a single-layer single-patch microstrip rectangular patch antenna with two equal size slots which are placed on the patch in the form of parallel to resonance edges. The resonant frequency is calculated as the position of the slots is shifted from the right endpoint to the left endpoint on the patch between −4.2 mm ≤ Xslot ≤ 4.2 mm with the steps of 0.1 mm. The designed antenna is proposed for downlink of X band satellite, broadcasting satellite service, fixed-satellite service uplink, satellite (Earth-to-space), radio navigation, mobile-satellite (Earth-to-space), and KU band which can be achieved at the resonant frequencies of 7.2 GHz, 12.2 GHz, 14.6 GHz, 17.5 GHz and 19.3 GHz. Next, High Frequency Electromagnetic Field Simulation software (ANSYS HFSS) results for the prototype microstrip antenna are compared with the values obtained through ANFIS system. It can be concluded that the adaptive network-based fuzzy inference system in such designs can be conveniently used due to fuzzy system’s high approximation capability and much faster convergence rate. The best results for our ANFIS system can be obtained if Gaussian membership is used which leads to the mean absolute error of 1.4653