141 research outputs found
A statistical model for the excitation of cavities through apertures
In this paper, a statistical model for the coupling of electromagnetic
radiation into enclosures through apertures is presented. The model gives a
unified picture bridging deterministic theories of aperture radiation, and
statistical models necessary for capturing the properties of irregular shaped
enclosures. A Monte Carlo technique based on random matrix theory is used to
predict and study the power transmitted through the aperture into the
enclosure. Universal behavior of the net power entering the aperture is found.
Results are of interest for predicting the coupling of external radiation
through openings in irregular enclosures and reverberation chambers.Comment: 12 pages, 11 figures, in press, IEEE Transactions on Electromagnetic
Compatibilit
Generalised Impedance Model of Wireless Links Assisted by Reconfigurable Intelligent Surfaces
We devise an end-to-end communication channel model that describes the
performance of RIS-assisted MIMO wireless links. The model borrows the
impedance (interaction) matrix formalism from the Method of Moments and
provides a physics-based communication model. In configurations where the
transmit and receive antenna arrays are distant from the RIS beyond a
wavelength, a reduced model provides accurate results for arbitrary RIS unit
cell geometry. Importantly, the simplified model configures as a cascaded
channel transfer matrix whose mathematical structure is compliant with widely
accepted, but less accurate, system level RIS models. A numerical validation of
the communication model is presented for the design of binary RIS structures
with scatterers of canonical geometry. Attained results are consistent with
path-loss models: For obstructed line-of-sight between transmitter and
receiver, the channel capacity of the (optimised) RIS-assisted link scales as
, with RIS-receiver distance at fixed transmitter position. Our
results shows that the applicability of communication models based on mutual
impedance matrices is not restricted to canonical minimum scattering RIS unit
cells.Comment: Submitted to IEEE Transactions on Antennas and Propagation; 15 pages,
11 figure
Quantifying Volume Changing Perturbations in a Wave Chaotic System
A sensor was developed to quantitatively measure perturbations which change
the volume of a wave chaotic cavity while leaving its shape intact. The sensors
work in the time domain by using either scattering fidelity of the transmitted
signals or time reversal mirrors. The sensors were tested experimentally by
inducing volume changing perturbations to a one cubic meter mixed chaotic and
regular billiard system. Perturbations which caused a volume change that is as
small as 54 parts in a million were quantitatively measured. These results were
obtained by using electromagnetic waves with a wavelength of about 5cm,
therefore, the sensor is sensitive to extreme sub-wavelength changes of the
boundaries of a cavity. The experimental results were compared with Finite
Difference Time Domain (FDTD) simulation results, and good agreement was found.
Furthermore, the sensor was tested using a frequency domain approach on a
numerical model of the star graph, which is a representative wave chaotic
system. These results open up interesting applications such as: monitoring the
spatial uniformity of the temperature of a homogeneous cavity during heating up
/ cooling down procedures, verifying the uniform displacement of a fluid inside
a wave chaotic cavity by another fluid, etc.Comment: 13 pages, 13 figure
Predicting the statistics of wave transport through chaotic cavities by the Random Coupling Model: a review and recent progress
In this review, a model (the Random Coupling Model) that gives a statistical
description of the coupling of radiation into and out of large enclosures
through localized and/or distributed channels is presented. The Random Coupling
Model combines both deterministic and statistical phenomena. The model makes
use of wave chaos theory to extend the classical modal description of the
cavity fields in the presence of boundaries that lead to chaotic ray
trajectories. The model is based on a clear separation between the universal
statistical behavior of the isolated chaotic system, and the deterministic
coupling channel characteristics. Moreover, the ability of the random coupling
model to describe interconnected cavities, aperture coupling, and the effects
of short ray trajectories is discussed. A relation between the random coupling
model and other formulations adopted in acoustics, optics, and statistical
electromagnetics, is examined. In particular, a rigorous analogy of the random
coupling model with the Statistical Energy Analysis used in acoustics is
presented.Comment: 32 pages, 9 figures, submitted to 'Wave Motion', special issue
'Innovations in Wave Model
Absorbing cross section in reverberation chamber: experimental and numerical results
Reverberation chamber (RC) test facility allows to determine the absorbing cross section (ACS) of lossy materials under a random field excitation. Measurements are based on the quality factor variation produced by the sample under test presence with respect to the empty chamber condition. Simulations are based on the representation of the RC electromagnetic field by means of a random plane wave superposition. A finite-difference time-domain code is used to compute the material absorbed power and to recover a numerical ACS. The method sensibility is stressed by application to small size samples. Comparison between numerical and experimental data reveals a satisfactory agreement. Results for different materials are presented in the paper: soft foam absorbers, carbon foam sheets, and carbon/carbon sheets
Probability distribution of the coherence bandwidth of a reverberation chamber
A theoretical probability distribution and associated statistics for the coherence bandwidth of an ideal mode-stirred reverberation chamber are derived. The stochastic model assumes and exploits the ergodicity of a dynamic wave chaotic cavity by expressing the coherence bandwidth in terms of the random effective excitation bandwidth and by replacing spatial averaging of transmitter-receiver locations with stir (ensemble) averaging. The theoretical model is validated through comparison with the empirical cumulative distribution function (cdf) extracted from measured S-parameter data from a real chamber, and through simulation using analytical calculations for a fictitious wall-stirred chamber. The results are particularly relevant to the improvement of transmission quality and uncertainty quantification of wireless multipath propagation
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