Electrically Small Multiferroic Antennas
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| Author | : Michael Francis Moon |
| Publisher | : |
| Total Pages | : |
| Release | : 2017 |
| Genre | : |
| ISBN | : 9780355150858 |
Multiferroic materials represent a material system with intrinsic coupling between polarization and magnetization, such that an electric field spontaneously magnetizes the material and vice versa. The magnetoelectric coupling in multiferroics is in sharp contrast to the present antenna design approach of using electric current through a wire to generate or receive electromagnetic (EM) waves. First, multiferroic approaches scale with size, a feature absent in modern antenna design where operating in an electrically small regime is always detrimental. Second, the antenna size in modern antenna designs is dictated by the EM wavelength in free space. In multiferroics, the EM wave is transformed from free space into a mechanical domain slowing the wave speed dramatically and reducing the wavelength. The work presented herein explores the effects of multiferroic transduction as applied to the electrically small antenna problem. A study is carried out to determine materials, geometry, and load impedance for a multiferroic receiving antenna. A multiphysics finite element model is developed to adequately capture the coupled magnetostrictive and piezoelectric physics. A custom particle swarm optimization algorithm is generated to refine the antenna elemental dimensions, and a path forward for fabrication is established. Modeling results were obtained that validated multiferroic architectures as a possible solution to the electrically small antenna problem.
| Author | : Emily Burnside |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2023 |
| Genre | : |
| ISBN | : |
While there is a need for low frequency (30-300 kHz) communication through lossy media like seawater and the human body, these dielectric cluttered environments present challenges to conventional communication devices in the form of signal attenuation. This is due to the interaction of the electric field component of electromagnetic radiation with the conductive portions of the surrounding media. Magnetoelectric antennas provide a solution to this problem in that they primarily output magnetic energy in the near field. Furthermore, by using strain-driven magnetoelectric antennas, antenna miniaturization is realizable by operating at acoustic resonance rather than electromagnetic resonance. While there have been successful experimental demonstrations of low frequency magnetoelectric antennas, the community lacks a systematic approach for antenna design and characterization. This first half of this work presents a decoupled system of models including a method for predicting magnetic moments of bulk samples using Landau-Lifshitz-Gilbert micromagnetic simulations, enabling radiation predictions via an analytical dipole model, resulting in a paradigm shift from dipole radiation validations to dipole radiation predictions. This work includes a methodical testing approach to assess the antenna's performance in terms of signal strength, quality factor, and radiation patterns, determining the antenna to be comparable to state-of-the-art pacemaker antennas. The second half of this work discusses the design and characterization of a Galfenol antenna which resonates at two distinct frequencies. This second antenna, called a dual band magnetoelectric antenna, allows for communication via frequency shift keying (FSK) and is the first magnetoelectric to accomplish FSK at two resonance frequencies. This work demonstrates that the data bandwidth can be increased by an order of magnitude and discusses potential for future improvement in data bandwidth. This dissertation also features a discussion on parasitic effects and mitigation techniques as well as material parametric studies for improved antenna performance. This work presents a comprehensive procedural guide for the design, fabrication, and characterization of low frequency magnetoelectric antennas, effectively bridging a gap in the existing literature.
| Author | : R. C. Hansen |
| Publisher | : LibreDigital |
| Total Pages | : 168 |
| Release | : 2006-06-19 |
| Genre | : Technology & Engineering |
| ISBN | : 9780470041031 |
Organized into three parts, each of which is important to the subject of electrically small antennas, Part One ofElectrically Small, Superdirective, and Superconducting Antennas covers the principles of good electrically small antennas, the fundamental limitations that apply, and design data for the few basic types, the antenna designs that are based on good physics yet are poor performers, and antennas whose physics are poor and whose performances are unacceptable.
| Author | : Xiaojing Xu |
| Publisher | : |
| Total Pages | : 116 |
| Release | : 2008 |
| Genre | : |
| ISBN | : |
| Author | : Kyohei Fujimoto |
| Publisher | : Cambridge University Press |
| Total Pages | : |
| Release | : 2014-01-09 |
| Genre | : Technology & Engineering |
| ISBN | : 1107354668 |
If you are involved in designing and developing small antennas, this complete cutting-edge guide covers everything you need to know. From fundamentals and basic theory to design optimization, evaluation, measurements and simulation techniques, all the essential information is included. You will also get many practical examples from a range of wireless systems, whilst a glossary is provided to bring you up to speed on the latest terminology. A wide variety of small antennas is covered, and design and practice steps are described for each type: electrically small, functionally small, physically constrained small and physically small. Whether you are a professional in industry, a researcher, or a graduate student, this is your essential guide to small antennas.
| Author | : Sungkyun Lim |
| Publisher | : |
| Total Pages | : 252 |
| Release | : 2007 |
| Genre | : Antennas (Electronics) |
| ISBN | : |
As the demand for compact, portable communication electronics increases, the technology of miniaturization has made great progress. A beneficiary of that progress has been research into new concepts for the antenna, one of the essential components in wireless communications. As the size of an antenna becomes smaller, however, the antenna suffers from high Q and low radiation resistance. The results are narrow bandwidth, poor matching, low efficiency, and, more generally, poor performance throughout the communication system. First, the design of a small antenna for HF/VHF communications is described. As the operating frequency of an antenna decreases, for example, into the HF and low VHF regions, the physical size of the antenna becomes a critical issue. It is desirable to design a truly electrically small antenna by reducing the ground plane size. Moreover, when the antenna size is very small, the bandwidth of the antenna is extremely narrow, which is critical to various deployment variances and propagation effects such as multi-path fading. The new design, which is an inductively coupled, top-loaded, monopole structure optimized by a genetic algorithm (GA), maximizes transmission of HF/VHF waves. Electrically small, spiral ground planes for the monopole and the electrically small antenna are designed for HF ground-wave transmission. In addition, a tunable small antenna is investigated that overcomes the narrow-bandwidth limitation of electrically small antennas. Second, new design methodologies for electrically small antennas are discussed. Use of an inductively coupled feed is one of the well-known methods for boosting input resistance. As the antenna size becomes smaller, however, it is found that the efficiency of an antenna using an inductively coupled feed is lower than an antenna using multiple folds. After a comparison of the two methods, the design of a thin, multiply folded, electrically small antenna is proposed for achieving high efficiency in a physically compact size. The GA is used to assess the effect of geometry on the performance (in terms of efficiency and bandwidth) of the electrically small antennas, including the folded conical helix and folded spherical helix. Finally, the prospects of using the new Yagi antennas to achieve small size are explored. Yagi antennas are used widely to obtain high gain in a simple structures. The antenna is composed of the driven element and the parasitic elements, which include a reflector and one or more directors. Typically, sufficient spacing on the order of 0.15[lambda] to 0.4[lambda] between the driven element and the parasitic elements is needed for the Yagi antenna to operate well. For some applications, however, it is desirable to reduce the spacing and the length of the elements to achieve a physically more compact size. In this dissertation, closely spaced, folded Yagi antennas in both three dimensions and two dimensions are investigated, and a design for an electrically small Yagi antenna is suggested.
| Author | : Wei Gu |
| Publisher | : |
| Total Pages | : 107 |
| Release | : 2019 |
| Genre | : |
| ISBN | : |
An innovative idea that ferromagnetic resonance (FMR) can be utilized to improve the radiation efficiency and input impedance matching for electrically small antennas (ESAs) simultaneously is proposed. This idea is inspired by the recent discovery that using magnetic materials with extremely large imaginary permeability can still achieve high radiation efficiency in designs of ESAs. The equation of radiation efficiency for ESAs as a function of ferrites' complex permeability is re-derived based on the field modeling and analysis of an ideal thin-film ferrite radiator to verify the discovery. Furthermore, taking FMR into consideration, a conclusion is made that the gilbert damping factor of the resonance determines radiation efficiency more essentially than of ferrites. The first practical design for the proposed FMR enhanced ESAs has been realized through a modified, small single loop antenna loaded with a thin-film yttrium-iron-garnet (YIG) core. A real physical prototype has been fabricated and evaluated through both full-wave simulations and experiments. The simulation results match to the experimental results, demonstrating the efficacy and significance of the idea. Novel frequency-independent, equivalent circuit models for small loops and FMR enhanced ESAs have been developed in this paper to guide the design of highly efficient ESAs in the future. The circuit models prove to be trustworthy in predicting input impedance and radiation efficiency by comparing with full-wave simulations and agreed.
| Author | : Ming Liu |
| Publisher | : John Wiley & Sons |
| Total Pages | : 305 |
| Release | : 2019-04-03 |
| Genre | : Science |
| ISBN | : 3527803696 |
Written by well-known experts in the field, this first systematic overview of multiferroic heterostructures summarizes the latest developments, first presenting the fundamental mechanisms, including multiferroic materials synthesis, structures and mechanisms, before going on to look at device applications. The resulting text offers insight and understanding for scientists and students new to this area.
| Author | : Jinzhao Hu |
| Publisher | : |
| Total Pages | : 124 |
| Release | : 2020 |
| Genre | : |
| ISBN | : |
This dissertation focuses on high frequency multiferroic devices from both theoretical and experimental aspects. Some potential applications for high frequency multiferroic: antennas, logic and memory, will be presented in this dissertation. The introduction section provides a fundamental explanation on the multiferroic devices as well as the modeling methods for strain-mediated multiferroic systems. Former researches indicate that the composites of piezoelectric substrate and the magnetoelastic material show great potential on reducing both the devices' size as well as energy consumption. Part I of the dissertation shows multiferroics for antenna applications. Conventionally, antennas such as dipoles and loops rely on an electromagnetic (EM) wave resonance. Therefore, the sizes of such antennas are within the same order of free space wavelength. Multiferroic antenna can transfer the EM wave into an acoustic wave, which has much smaller wavelength compared with the wavelength of the EM wave under the same frequency. In this way, multiferroic antennas show a promising path for reducing the antenna system's size, weight and volume. Also, three multiferroic antennas: shear wave antenna, lamb wave antenna as well as tunable frequency broadband antenna are introduced in this section. The shear wave antenna and lamb wave antenna are studied experimentally, and the tunable frequency broadband antenna is studied theoretically. All of them show great potential on reducing the antenna's size. Part II of this dissertation indicates other applications of multiferroic devices: logic and memory. For the logic aspects, a numerical simulation is performed on in-plane mode Bennett clocking systems. For memory aspects, a new concept for breaking the switch symmetry the high frequency control of the magnetization in nanodisk. In this part, a fully coupled finite element model is used to simulate the switch process of the magnetization in the nanodisks. This voltage-controlled process has potential be used in magnetic memory devices with very low energy dissipations.
| Author | : Jiaying Zhang |
| Publisher | : |
| Total Pages | : |
| Release | : 2011 |
| Genre | : |
| ISBN | : 9788792465894 |
