106 research outputs found
Topological wireless communication in the stopband of magnetoinductive lines
Conventionally, in engineering, the stopband of periodic structures, where propagating signals are unable to penetrate them, was of little interest to engineers. However, with the advent of topological physics, this has changed, and the stopband has moved into the center of attention. Here, we study the behavior of magnetoinductive waves in the stopband of a diatomic line. Surprisingly, here, we find that for lines hosting topological edge states, the signal power at frequencies in the stopband can be higher than anywhere in the passband. Further, they may also exceed both the signal power and Shannon capacity of a conventional monoatomic line, making them of interest for application in wireless communication
Near-field Image Transfer by Magneto-Inductive Arrays: a Modal Perspective
A simple model of near-field pixel-to-pixel image transfer using
magneto-inductive arrays is presented. The response of N-dimensional
rectangular arrays is first found as an excitation of eigenmodes. This
analytical method involves approximating the effect of sources and detectors,
and replaces the problem of solving large numbers of simultaneous equations
with that of evaluating a sum. Expressions are given for the modal expansion
coefficients, and in the low-loss case it is shown that the coefficient values
depend only on the difference in reciprocal frequency space of the operating
frequency from the resonant frequency of each mode. Analytic expressions are
then derived for quasi-optical quantities such as the spatial frequency
response, point-spread function and resolving power, and their implications for
imaging fidelity and resolution are examined for arrays of different dimension.
The results show clearly that there can be no useful image transfer for in-band
excitation. Out-of-band excitation allows image transfer. Provided the array is
larger than the expected image by at least the size of the point spread
function, the effect of the array boundaries may be ignored and imaging is
determined purely by the properties of the medium. However, there is a tradeoff
between fidelity and throughput, and good imaging performance using thick slabs
depends on careful choice of the operating frequency. The approximate analytic
method is verified by comparison of exact numerical solution
Rotational resonance of magnetoinductive waves: Basic concept and application to nuclear magnetic resonance
Published versio
Wireless power transfer in attenuating media
Dissipative media (underground/underwater, biological materials and tissues, etc.) pose a challenge to inductive wireless power transfer systems as they generally attenuate the near fields that enable mutual coupling. Apart from this, the impact of the environment on electromagnetic
fields can also be seen in the self-impedance of coils, resulting in significant eddy current losses and detuning effects. In this article, we study,
theoretically, the mechanism of wireless power transfer via a pair of magnetic resonators inside an infinite homogeneous medium with a
comprehensive circuit model that takes into account all the electromagnetic effects of the background medium. This analytical approach can
offer deep insights into the design and operation of wireless charging systems in non-ideal environments
Superdirectivity from arrays of strongly coupled meta-atoms
This is the final version of the article. Available from AIP Publishing via the DOI in this record.We explore the possibility of achieving superdirectivity in metamaterial-inspired endfire antenna arrays relying on the good services of magnetoinductive waves. These are short-wavelength slow waves propagating by virtue of coupling between resonant meta-atoms. Magnetoinductive waves are capable of providing a rapidly varying current distribution on the scale of the free space wavelength. Using dimers and trimers of magnetically coupled split ring resonators with only one element driven by an external source, we introduce an analytical condition for realising superdirective current distributions. Although those current distributions have been known theoretically for a good 60 years, this is the first time that a recipe is given to realise them in practice. Our key parameters are the size of the array, the resonant frequency and quality factor of the elements, and their coupling constant. We compare our analytical results for coupled magnetic dipoles with numerical results from CST simulations for meta-atoms of various shapes. The calculated bandwidth of 5 MHz for a dimer operating at 150 MHz indicates that, contrary to popular belief, superdirective antennas exist not only in theory but may have practical applications.Financial support by the John Fell Fund (University of Oxford) and by the EPSRC UK (SYMETA, EP/N010493/1) is gratefully acknowledged
Exact solution of the Bragg-diffraction problem in sillenites
A method for the exact solution of the Bragg-difrraction problem for a photorefractive grating in sillenite crystals based on Pauli matrices is proposed. For the two main optical configurations explicit analytical expressions are found for the diffraction efficiency and the polarization of the scattered wave. The exact solution is applied to a detailed analysis of a number of particular cases. For the known limiting cases there is agreement with the published results
A theory of metamaterials based on periodically loaded transmission lines: Interaction between magnetoinductive and electromagnetic waves
Published versio
Feedback-controlled running holograms in strongly absorbing photorefractive materials
We propose a mathematical model for the movement in absorbing materials of photorefractive holograms under feedback constraints. We use this model to analyze the speed of a fringe-locked running hologram in photorefractive sillenite crystals that usually exhibit a strong absorption effect. Fringe-locked experiments permit us to compute the quantum efficiency for the photogeneration of charge carriers in photorefractive crystals if the effect of bulk absorption and the effective value of the externally applied field are adequately taken into consideration. A Bi12TiO20 sample was measured with the 532-nm laser wavelength, and a quantum efficiency of Phi = 0.37 was obtained. Disregarding absorption leads to large errors in Phi. (C) 2000 Optical Society of America [S0740-3224(00)00209-5].1791517152
Investigation of photorefractive subharmonics in the absence of wavemixing
Using a new optical configuration free from the influence of photorefractive optical nonlinearity, we investigate the main characteristics of the spatial subharmonic K/2 excited in a Bi12SiO20 crystal by a light-intensity pattern with wave vector K and frequency O. It is shown that in a large region of intensity and applied electric field the optimum value O of the frequency corresponds to the conditions of parametric excitation of the weakly damped eigenmodes of the medium: the space-charge waves. The threshold and above-threshold characteristics of the subharmonic regime are in good agreement with the theory
Nonlinear Localization in Metamaterials
Metamaterials, i.e., artificially structured ("synthetic") media comprising
weakly coupled discrete elements, exhibit extraordinary properties and they
hold a great promise for novel applications including super-resolution imaging,
cloaking, hyperlensing, and optical transformation. Nonlinearity adds a new
degree of freedom for metamaterial design that allows for tuneability and
multistability, properties that may offer altogether new functionalities and
electromagnetic characteristics. The combination of discreteness and
nonlinearity may lead to intrinsic localization of the type of discrete
breather in metallic, SQUID-based, and symmetric metamaterials. We
review recent results demonstrating the generic appearance of breather
excitations in these systems resulting from power-balance between intrinsic
losses and input power, either by proper initialization or by purely dynamical
procedures. Breather properties peculiar to each particular system are
identified and discussed. Recent progress in the fabrication of low-loss,
active and superconducting metamaterials, makes the experimental observation of
breathers in principle possible with the proposed dynamical procedures.Comment: 19 pages, 14 figures, Invited (Review) Chapte
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