Advanced Electromagnetics https://www.aemjournal.org/index.php/AEM <div class="hometabscontainer"> <div style="float: left;"> <table style="height: 280px;" width="158"> <tbody> <tr> <td align="left" valign="top"><a href="https://aemjournal.org/images/aem_cover_new.png"><img class="img-responsive" style="border: 0px;" src="https://aemjournal.org/images/aem_cover_mini_new.png" alt="" width="150" /></a> <p style="text-align: center;"><strong style="text-align: center;">ISSN: 2119-0275</strong></p> </td> </tr> </tbody> </table> </div> <h2><span style="color: #336699;">Publish with impact and global reach!</span></h2> <p><strong>Open Access</strong> – <em>Advanced Electromagnetics</em> is free from all access barriers, allowing for the widest possible global dissemination of your work, leading to more citations.<br /><strong>Comply with archiving policies</strong> – authors can deposit <em>any </em>version of their manuscript in <em>any</em> required repository or archive, or post articles to their personal or institutional website. <br /><strong>Retain copyright</strong> – authors retain the copyright to their own article; you are free to disseminate your work, make unlimited copies, and more.</p> <p><img class="img-responsive" src="https://aemjournal.org/images/indexing.png" alt="" width="583" height="122" /></p> </div> en-US <p>Authors who publish with this journal agree to the following terms:</p><ol><li style="text-align: justify;">Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a <a target="_blank">Creative Commons Attribution License</a> that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.</li><li style="text-align: justify;">Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.</li><li style="text-align: justify;">Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See <a target="_blank">The Effect of Open Access</a>).</li></ol> contact@aemjournal.org (AEM Editorial Team) contact@aemjournal.org (AEM Support Team) Sun, 16 Apr 2023 19:44:38 +0200 OJS 3.3.0.4 http://blogs.law.harvard.edu/tech/rss 60 Wideband E-shaped Patch Antennas for Advanced Wireless Terminals https://www.aemjournal.org/index.php/AEM/article/view/2191 <p>Low-profile patch antennas have become ubiquitous in wireless terminals, especially as devices have become smaller and demand more functionality out of their RF subsystems. While their shape and size is attactive for many applications, their narrow bandwidth hinders their usage in many systems. With the rise of computer-aided design, many patch antenna design concepts have been presented with enhanced bandwidth capabilities. The E-shaped patch antenna, whose original shape presented in the early 2000’s resembles the letter E, offers compelling performance with reasonable manufacturing complexity. In it most basic form, this antenna was linearly polarized and either wideband or dual-band. Over the last two decades, many variations of the E-shaped patch have been presented in literature: circularly polarized, miniaturized, frequency reconfigurable, or even polarization reconfigurable. This paper summarizes these efforts in realizing novel functionalities with a relatively simple design geometry.</p> Y. Rahmat-Samii, J. M. Kovitz Copyright (c) 2023 Yahya Rahmat-Samii, Joshua M. Kovitz https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2191 Mon, 20 Mar 2023 00:00:00 +0100 A Typical Slotted SIW Cavity-backed Antenna for Dual frequency operations in U-NII Bands https://www.aemjournal.org/index.php/AEM/article/view/2146 <p>A low profile circular shaped cavity-backed substrate integrated waveguide (SIW) antenna with two-typical intersecting rectangular slots on the ground plane is designed to operate in the dominant TM010 mode at a frequency of 5.19 GHz in U-NII-1 band for wireless applications. The initially designed antenna produces a gain of 4 dBi with a narrow impedance bandwidth extending from 5.17 – 5.22 GHz. The antenna design is further modified by insertion of another shifted two-typical intersecting rectangular slots to finally resemble that of Hash shape; resulting in dual band antenna operation at 4.9 and 5.93 GHz. The gains obtained are 3.7 dBi and 1.4 dBi for 4.9 and 5.93 GHz respectively with an impedance bandwidth covering 4.88 - 4.92 GHz and 5.92 – 5.94 GHz respectively. The antenna prototype is fabricated using Arlon AD270 substrate material. Parametric studies are performed in terms of return loss and gain of the antenna. All simulations are &nbsp;carried out using HFSS v19.0 and show similar behavior to their experimentally measured counterparts.</p> R. Sengupta, S. Banerjee, M. Mitra Copyright (c) 2023 R. Sengupta, S. Banerjee, M. Mitra https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2146 Sun, 21 May 2023 00:00:00 +0200 Electromagnetic guided mode resonance in dielectric grating affected by transformation of refractive index periodicity https://www.aemjournal.org/index.php/AEM/article/view/2127 <p>The present work studied effects of transformation of refractive index periodicity on electromagnetic wave propagation through grating waveguides. In lieu of the standard refractive index periodicity, although its unit cell consists of two kinds of materials, we consider few such unit cells as a new supercell, where the material parameters in a standard unit cell are changed. It has been shown how by changing parameters of the periodicity to control the wavelength and intensity of resonant optical mode (guided mode resonance) arising inside grating area. High quality factor calculated for the specific angle of incidence and periodicity parameter. Thus, we demonstrated that transformation of refractive index provides additional tools of controlling the GMR, and that means the sample can be designed more functional in terms of real application.</p> A. Abramov, Y. Yue, V. Rumyantsev Copyright (c) 2023 A. Abramov, Y. Yue, V. Rumyantsev https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2127 Sun, 12 Feb 2023 00:00:00 +0100 Electrothermal Analyses of Bandpass NGD RLC-Network Topologies https://www.aemjournal.org/index.php/AEM/article/view/2125 <p class="Abstract"><span lang="EN-US">This paper develops an original study of temperature effect on the unfamiliar bandpass (BP) negative group delay (NGD) lumped passive circuits. The paper presents the first study of electrothermal analysis of electronic circuits classified as BP-NGD topologies. The considered BP-NGD passive cells are mainly constituted by RLC-resonant networks. The equivalence between two basic BP-NGD topologies constituted by RLC-series and RLC-parallel networks is elaborated via the voltage transfer function (VTF) analogy. Then, the theoretical demonstrations are introduced to define the main specifications as the NGD center frequency, NGD value, attenuation and NGD bandwidth. The electrothermal innovative study is developed based on the temperature coefficient resistor (TCR) of elements constituting the BP-NGD circuits. With proofs of concept of RLC-series and RLC-parallel circuits operating with -500 ns NGD value at 13.56 MHz, calculated and simulated results showing are in excellent agreement. The sensitivity analyses of BP-NGD specifications in function of ambient temperature variation from 0°C to 100°C are investigated. The BP-NGD response variations versus frequency and temperature are characterized with thermo-frequency cartographies and discussed.</span></p> E. J. R. Sambatra, S. Ngoho, F. Haddad, M. Guerin, G. Fontgalland, W. Rahajandraibe, B. Ravelo Copyright (c) 2023 E. J. R. Sambatra, S. Ngoho, F. Haddad, M. Guerin, G. Fontgalland, W. Rahajandraibe, B. Ravelo https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2125 Sat, 11 Mar 2023 00:00:00 +0100 Generation of OAM Beam with High Azimuthal Symmentry through Planar UCA for Vehicular Communication https://www.aemjournal.org/index.php/AEM/article/view/2104 <p>In this paper, a uniform circular array (UCA) with circularly polarized (CP) square patches is presented for the generation of orbital angular momentum (OAM) beam with high azimuthal symmetry. The proposed CP UCA is a compact structure with a simple feed network generating OAM beams. The design consists of eight circularly polarized square patch antennas which are geometrically rotated to obtain the required phase distribution. The left hand circularly polarized square patch used as a radiating element in UCA exhibits l = + 1 OAM mode, while the right hand circularly polarized square patch exhibits l = - 1 OAM mode. In addition, the antenna exhibits a single-layer structure, which facilitated the fabrication of the design and reduced the cost as well. The simulated and measured results are reported showing that the antenna exhibits an OAM beam of l = + 1 and l = - 1 modes at 5.85 GHz with high azimuthal symmetry. The mode purity estimation is also reported for the OAM l = + 1 and l = - 1 modes. The gain of the conical shaped OAM beam is almost 11 dBi which makes it quite viable for applications in wireless and vehicular communications.</p> Y. Mallikharjuna Reddy, U. V. Ratna Kumari Copyright (c) 2023 Y. Mallikharjuna Reddy, U. V. Ratna Kumari https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2104 Thu, 25 May 2023 00:00:00 +0200 Broadband Printed Tapered Slot Antenna Fed by CPW Fulfilled with Planar Artificial Magnetic Conductor for X-Band Operation https://www.aemjournal.org/index.php/AEM/article/view/2087 <p>A low-profile printed slot antenna (PSA) backed by broadband planar artificial magnetic conductor (AMC) is introduced in this study. Firstly, a suggested PSA with the radiating tapered slots excited by coplanar-waveguide (CPW) is used to expand the bandwidth in the measured range of 9-11 GHz (S11≤ -10 dB). Then, the suggested planar AMC surface as the ground plane of the antenna is inserted into the PSA to gain improved radiation efficiency. The realized result from the PSA with the 9×9 planar AMC array exhibits -10 dB measured impedance bandwidth from 6.63 to 13.73 GHz (70%). The suggested PSA with AMC compared to the PSA without AMC exhibits a size reduction of 60%, enhanced bandwidth of 50%, and excellent impedance matching with a minimum value of almost -40 dB. The novel AMC unit cell is realized to operate at 10.14 GHz with an AMC bandwidth of 8-12.35 GHz (43.1%) for X-band operation. Besides, by loading a periodic AMC unit cells into PSA, a high gain of more than 11 dBi with uni-directional radiation patterns is achieved.</p> H. Malekpoor Copyright (c) 2023 H. Malekpoor https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2087 Tue, 24 Jan 2023 00:00:00 +0100 On the Computation of the Attenuation Constant by Using the Generalized Telegraphist’s Equations Based Electromagnetic Analysis Method https://www.aemjournal.org/index.php/AEM/article/view/2086 <p>Numerical results for the attenuation constant obtained by using the generalized telegraphist’s equations (GTEs) based electromagnetic analysis method and comparison with the HFSS (High Frequency Structure Simulator) results are reported. To calculate the attenuation constant with the GTEs method, not only the amplitudes of the voltage modes but also the amplitudes of the current modes must be found. In this paper, it is demonstrated that the relationships reported by other authors for the amplitudes of the current modes are not correct and new ones are proposed. To validate these relationships, the attenuation constants for homogeneous and different partially dielectric-filled rectangular waveguides are computed for the fundamental propagation mode by using the GTEs based analysis method and the results are compared with those obtained with HFSS. It is shown that using the revised relationships for the amplitudes of the current modes, the GTE method can be used to compute accurately the propagation and attenuation constant, but only for propagation modes in which the components of the electric field are not oriented perpendicular to the interface between different dielectrics. This limitation is not due to the proposed current mode relationships, but is due to the GTE method which cannot highlight the electric field discontinuities.</p> S. Simion Copyright (c) 2023 S. Simion https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2086 Sun, 12 Feb 2023 00:00:00 +0100 High Isolation Quad-Element SWB-MIMO Antenna with Dual Band-Notch for ISM and WLAN Band Wireless Applications https://www.aemjournal.org/index.php/AEM/article/view/2080 <p>A quad-element super-wideband (2-20GHz) MIMO antenna including dual notched-band response at WiMAX (3.30-3.70GHz) and satellite-band (6.99-8.09GHz) is designed on RO3035 with total dimension of 118mm×86mm×1.67mm. Unique decoupling structure has been deployed to enhance the isolation (˃20dB) between two antenna elements. The fundamental properties of MIMO antennas like bandwidth ratio (10:1), isolation (&gt;18dB), gain (4.14dB), Envelop Correlation-Coefficient (&lt;0.0065), Total Active Reflection-Coefficient (&lt; 0dB), Channel Capacity Loss (&lt;0.25bps/Hz) and radiation patterns are also investigated in order to determine their practicality. Measurement and simulation results of the proposed SWB-MIMO antenna from 2 to 20GHz indicate that it will be the suitable candidate for wireless and biomedical applications.</p> G. Saxena, U. Gupta, S. Shukla, U. Shukla, S. Bharti, Y. K. Awasthi, C. Sanjay, W. A. M. Saif, H. Singh Copyright (c) 2023 G. Saxena, U. Gupta, S. Shukla, U. Shukla, S. Bharti, Y. K. Awasthi, C. Sanjay, W. A. M. Saif, H. Singh https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2080 Mon, 04 Sep 2023 00:00:00 +0200 Design of Wide-Band Microstrip Antenna for S-Band Telemetry Applications https://www.aemjournal.org/index.php/AEM/article/view/2078 <p>This paper exemplifies the design of a low profile wide-band microstrip antenna suitable for S-Band telemetry applications. The proposed design explores the concept of wide-band antenna with improved omnidirectional gain and smaller size essentially aiming at low-earth orbit (LEO) satellite telemetry. The proposed partial annular radiating patch design has an operating impedance bandwidth ranging from 2.7 GHz to 3.8 GHz with a percentage bandwidth of 31%. It exhibits vertical polarization with a gain of around 1.434 dBi. The design and simulations are carried out using 3D EM tools and the measurement results for various performance metrics of the antenna are validated with the simulation results.</p> Pushpalatha M, Namana N, T. S. Navadagi, Varun D Copyright (c) 2023 PUSHPALATHA M, Namana N, T. S. Navadagi, Varun D https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2078 Sat, 11 Mar 2023 00:00:00 +0100 Dual-Band MIMO Antenna with Four CPW Elements using Polarization Diversity for 5G Mobile Communication Networks and Satellite https://www.aemjournal.org/index.php/AEM/article/view/2077 <p class="Abstract">In this paper, a novel design of compact quad-element MIMO (Multiple Input Multiple Output) antenna for 5G communication networks and satellites is proposed. The four similar elements of this antenna are placed perpendicularly to each other on a 40x40 mm2 FR4 substrate. Each element is fed by a CPW (coplanar waveguide) line. Two slits and an I-shaped slot are etched into the patch, and by varying their parameters; a good matching is achieved in the lower (4.9 GHz) and upper (17 GHz) frequency bands. However, 25 and 30 dB isolations are attained in the lower and upper bands, using the polarization diversity technique and adding stubs on the ground plane. A prototype of the proposed antenna is fabricated and measured. Moreover, the performance of the MIMO antenna is studied in terms of ECC (envelope correlation coefficient), DG (diversity gain), TARC (total active reflection coefficient), realized gain, efficiency, and radiation pattern, validated with the measured results, and showed a good agreement.</p> D. El Hadri, A. Zugari, A. Zakriti, M. El Ouahabi Copyright (c) 2023 D. El Hadri, A. Zugari, A. Zakriti, M. El Ouahabi https://creativecommons.org/licenses/by/4.0 https://www.aemjournal.org/index.php/AEM/article/view/2077 Tue, 08 Aug 2023 00:00:00 +0200