[JP68] M. Asefi, A. Zakaria, J. LoVetri, "Microwave Imaging Using Normal Electric Field Components Inside Metallic Resonant Chambers,"
IEEE Transactions on Microwave Theory and Techniques, vol. --, pp. --, 2016.[Link][PDF]
- A novel 3D microwave imaging approach performed within a resonant air-filled metallic chamber is introduced and investigated.
The new method utilizes measurements of normal electric-field components at discrete points along the metallic chamber’s wall—near
the chamber-wall boundary the normal field components are dominant while the tangential components vanish. The inversion algorithm
fully incorporates the resonant features of the low-loss chamber. A numerical study is used to quantify the imaging performance of
using this technique compared to traditional unbounded domain imaging. An experimental system is presented where the electric field
is collected using 24 antennas distributed in three circumferential layers around an object-of-interest located inside the
circular-cylindrical metallic chamber. For collecting the normal component of the field, two types of linearly-polarized antennas
are investigated: λ=4 monopole antennas and specially-designed reconfigurable antennas, both projecting perpendicularly out from
the chamber walls into the enclosure. The measured data are calibrated, then inverted using a multiplicatively-regularized
finite-element contrast source inversion algorithm. Using 3D reconstructions of simple dielectric targets it is shown that utilizing
the reconfigurable antennas improves imaging performance due to a reduction in the modeling error introduced in the inversion algorithm.
[JP67] M. Asefi, G. Faucher, J. LoVetri, "Surface-Current Measurements as Data for Electromagnetic Imaging Within Metallic Enclosures,"
IEEE Transactions on Microwave Theory and Techniques, vol. PP, no. 99, pp. 1-9, 2016.[Link][PDF]
- A 3-D microwave imaging method within metallic enclosures is investigated and improved. This method uses the components of the
surface-current vector at receiver points on the enclosure wall as data. At the metallic wall, the normal component of the magnetic
field as well as the tangential components of the electric field is negligible, whereas the vectorial surface current, which is
directly related to the tangential components of the magnetic field, is dominant. After presenting the results of a numerical
investigation based on synthetic data, the method is validated using an experimental system comprised of 24 co-resident shielded,
coaxial half-loop antennas, distributed in four layers, within a cylindrical metallic enclosure. These antennas are used in
receiver-transmitter pairs to introduce an electromagnetic field into the chamber and collect the magnetic field at the receiver
points. The measured data are used as input to a multiplicatively regularized finite-element contrast source inversion algorithm.
Due to their relatively small size and minimal protrusion into the chamber, these antennas minimally perturb the field distribution
inside the chamber and thereby allow the use of a simple numerical inversion model, which does not need to account for the passive
antennas. These attributes are especially useful for large computationally intensive industrial applications. The experimental
system described herein is a laboratory-scale prototype for a stored-grain imaging application where metallic silos are utilized.
[JP66] P. Mojabi and J. LoVetri, "Composite Tissue-Type and Probability Image for Ultrasound and Microwave Tomography,"
IEEE Journal on Multiscale and Multiphysics Computational Techniques, vol. 1, pp. 25-36, 2016.[Link][PDF]
- The concept of creating a composite tissue-type-image (cTTI) along with an associated probability image is introduced for
ultrasound and microwave tomography. The cTTI integrates information available within different quantitative property images, and
the associated probability image provides an indication of the level of confidence regarding the reconstructed tissue types. It
is shown that the cTTI concept can be applied to ultrasound tomography property images, microwave tomography property images, as
well as to their combination. Thus, the concept is generalizable to the amalgamation of quantitative information derived from a
wide variety of modalities with the goal of increasing the confidence in the reconstructed cTTI. Validation of the concept is
performed on MRI-derived numerical breast phantoms containing up to five different tissue types.
[JP65] M. Asefi, I. Jeffrey, J. LoVetri, C. Gilmore, P. Card, and J. Paliwal, "Grain bin monitoring via electromagnetic imaging,"
Computers and Electronics in Agriculture, vol. 119, pp. 133-141, 2015.[Link][PDF]
- Stored grain monitoring is an important post-harvest stage of the food production chain. Grains are usually stored in large
metal containers referred to as bins or silos. During storage, there is a possibility for grain to spoil and become unusable.
Therefore, monitoring of grain bins is essential to detect conditions leading to spoilage within the bin. Most current grain bin
monitoring techniques lack sensitivity as they require conditions leading to spoilage to surpass a certain limit before detection
is possible, and consequently a large amount of stored grain is lost during monitored storage. This paper presents the advances
in developing a novel grain-monitoring technique using electromagnetic imaging, a modality that can provide global, quantitative
images of grain properties throughout the bin. Side-mounted antennas illuminate the contents of the bin and a set of receivers
measures the electromagnetic energy within the bin at discrete locations. Using these measurements an optimization algorithm
attempts to reconstruct the contents of the bin – herein a finite-element contrast source inversion (FEM-CSI) algorithm was used.
The result is a global map of the electrical properties of the grain throughout the bin. In this work we first present a synthetic
validation of the proposed method for a model of a full scale hopper bin using simulations to produce the electromagnetic field
data. Next, a scaled experimental system was used to collect data from grain that contained regions of induced contamination. This
data was used to produce images that show the applicability of the method in practice. Results suggest that this technology has
potential to provide farmers with a reliable and robust method to remotely monitor stored grain, preserving stored food resources
and increasing their revenue.
[JP64] I. Jeffrey, N. Geddert, K. Brown, and J. LoVetri, "THE TIME-HARMONIC DISCONTINUOUS GALERKIN METHOD AS A ROBUST FORWARD SOLVER FOR MICROWAVE IMAGING APPLICATIONS,"
Progress In Electromagnetics Research, vol. 154, pp. 1-21, 2015.[Link][PDF]
- Novel microwave imaging systems require flexible forward solvers capable of incorporating arbitrary boundary conditions and
inhomogeneous background constitutive parameters. In this work we focus on the implementation of a time-harmonic Discontinuous
Galerkin Method (DGM) forward solver with a number of features that aim to benefit tomographic microwave imaging algorithms: locally
varying high-order polynomial field expansions, locally varying high-order representations of the complex constitutive parameters,
and exact radiating boundary conditions. The DGM formulated directly from Maxwell's curl equations facilitates including both
electric and magnetic contrast functions, the latter being important when considering quantitative imaging with magnetic contrast
agents. To improve forward solver performance we formulate the DGM for time-harmonic electric and magnetic vector wave equations
driven by both electric and magnetic sources. Sufficient implementation details are provided to permit existing DGM codes based on
nodal expansions of Maxwell's curl equations to be converted to the wave equation formulations. Results are shown to validate the DGM
forward solver framework for transverse magnetic problems that might typically be found in tomographic imaging systems, illustrating
how high-order expansions of the constitutive parameters can be used to improve forward solver performance.
[JP63] P. Mojabi and J. LoVetri, "Ultrasound Tomography for Simultaneous Reconstruction of Acoustic Density, Attenuation, and Compressibility Profiles,"
Journal of AcousticalSociety of America, vol. 137, no. 4, pp. 1813-1825, 2015. [Link][PDF]
- A fast and efficient forward scattering solver is developed for use in ultrasound tomography. The solver is formulated
so as to enable the calculation of scattering from large and relatively high-contrast objects with inhomogeneous physical
properties that vary simultaneously in acoustic attenuation, compressibility, and density. It is based on the method of
moments in conjunction with a novel implementation of the conjugate gradient algorithm which requires the use of the adjoints
of the scattering operators. The solver takes advantage of the symmetric block Toeplitz matrix with symmetric Toeplitz blocks
property of the Green's function matrix to increase efficiency and only stores the first row of this matrix to reduce memory
requirements. This row is then used for the matrix-vector multiplication using the fast Fourier transform technique, thus,
resulting in the computational complexity of O(n log n). The marching-on-source technique is also used to provide a good
initial guess which allows the conjugate gradient technique to converge faster than initializing with an arbitrary guess.
This feature is important in tomographic inversion algorithms which require that the object to be imaged be interrogated via
several incident fields. Forward scattering and inversion examples, based on the Conjugate Gradient Least Squares regularized
Born Iterative Method, are shown, in two-dimensions, for objects varying in all three physical properties.
[JP62] A. Baran, D. Kurrant, A. Zakaria, E. Fear, and J. LoVetri, "Breast Imaging Using Microwave Tomography with Radar-Based Tissue-Regions Estimation,"
Progress In Electromagnetics Research, Vol. 149, 2014, pp. 161-171. [Link][PDF]
- Microwave tomography (MWT) and a radar-based region estimation technique are combined to create a novel algorithm for
biomedical imaging with a focus on breast cancer detection and monitoring. The region estimation approach is used to generate
a patient-specific spatial map of the breast anatomy that includes skin, adipose and fibroglandular regions, as well as their
average dielectric properties. This map is incorporated as a numerical inhomogeneous background into an MWT algorithm based on
the finite element contrast source inversion (FEM-CSI) method. The combined approach reconstructs finer structural details of
the breast and better estimates the dielectric properties than either technique used separately. Numerical results obtained with
the novel combined algorithmic approach, based on synthetically generated breast phantoms, show significant improvement in image
quality.
[JP61] M. Asefi, M. Ostadrahimi, A. Zakaria, J. LoVetri, "A 3-D Dual-Polarized Near-Field Microwave Imaging System,"
IEEE Transactions on Microwave Theory and Techniques, Vol. 62, No. 8, Aug. 2014, pp. 1790-1797. [Link][PDF]
- A novel 3-D dual-polarized microwave imaging system based on the modulated scattering technique (MST) is presented.
The system collects the magnitude and phase of the scattered field using 120 MST probes and 12 transmitter/collector antennas
distributed around an object-of-interest in the near-field region. The 12 antennas form a middle circumferential layer while the
printed MST probes are arranged on three circumferential layers including the middle layer. The antennas are linearly
polarized double-layer Vivaldi antennas, each fixed inside its own cylindrical conducting cavity and slanted with respect
to the vertical axis of the imaging chamber. The MST probes are etched on both sides of a thin substrate and loaded with five
evenly distributed p-i-n diodes along their length. These are positioned vertically and horizontally so that
the $z$ - and $phi$ -components of the electric field is measured. Field data are collected using MST, calibrated,
and then inverted using a multiplicatively regularized finite-element contrast source inversion algorithm. The system
performance is evaluated by collecting and inverting data from different 3-D targets.
[JP60] M. Ostadrahimi, L. Shafai, J. LoVetri, "Analysis of a Double-Layered Vivaldi Antenna Inside a Metallic Enclosure,"
Progress In Electromagnetics Research, Vol. 143, 2013, pp. 503-518. [Link][PDF]
- A double-layered Vivaldi antenna enclosed by a metallic cylindrical cavity is investigated.
The antenna is correlated to the same-size circular horn antenna to exploit the equivalent modal
distribution of the Vivaldi-cavity antenna. It is shown that the TM11 and TE11 are the dominant
modes and the proposed antenna operates similar to a dual-mode conical horn.
The antenna is fabricated and successfully tested. The radiation characteristics, mutual coupling,
as well as cross-polarization level are compared to a similarly sized Vivaldi without any metallic enclosure.
[JP59] A. Zakaria, I. Jeffrey, J. LoVetri, "Full-Vectorial Parallel Finite-Element Contrast Source Inversion Method,"
Progress In Electromagnetics Research, Vol. 142, 2013, pp. 463-483. [Link][PDF]
- The multiplicatively regularized finite-element contrast source inversion
algorithm (MR-FEM-CSI) is used to solve the full-vectorial three-dimensional
(3D) inverse scattering problem. The contrast and contrast-source
optimization variables are located at the centroids of tetrahedra within the
problem domain; whereas the electric feld is expanded in terms of edge basis
functions on the same tetrahedra. A dual-mesh is created in order to apply
the multiplicative regularization. To handle large-scale problems the
inversion algorithm is parallelized using the MPI library, with sparse
matrix and vector computations supported by PETSc. The algorithm is tested
using experimental datasets obtained from the Institut Fresnel database. A
synthetic example shows that the technique is able to successfully image
moisture hot-spots within a partially filled grain bin.
[JP58] C. Gilmore, A. Zakaria, S. Pistorius, J.
LoVetri,"Microwave Imaging of Human Forearms: Pilot Study and Image
Enhancement," International Journal of Biomedical Imaging," Vol. 2013,
Article ID 673027, 17 pages, doi:10.1155/2013/673027. [Link][PDF]
- We present a pilot study using a microwave tomography system in which we
image the forearms of 5 adult male and female volunteers between the ages of
30 and 48. Microwave scattering data were collected at 0.8 to 1.2GHz with 24
transmitting and receiving antennas located in a matching fluid of deionized
water and table salt. Inversion of the microwave data was performed with a
balanced version of the multiplicative-regularized contrast source inversion
algorithm formulated using the finite-element method(FEM-CSI). T1-weighted
MRI images of each volunteer forearm were also collected in the same plane
as the microwave scattering experiment. Initial blind imaging results
fromthe utilized inversion algorithm showthat the image quality is dependent
on the thickness of the arm peripheral adipose tissue layer; thicker
layers of adipose tissue lead to poorer overall image quality. Due to the
exible nature of the FEM-CSI algorithm used, prior information can be
readily incorporated into the microwave imaging inversion process. We show
that by introducing prior information into the FEM-CSI algorithm the
internal anatomical features of all the arms are resolved, significantly
improving the images. The prior information was estimated manually from the
blind inversions using an ad hoc procedure.
[JP57] M. OstadRahimi, P. Mojabi, A. Zakaria, J. LoVetri, L.
Shafai, "Enhancement of Gauss-Newton Inversion Method for Biological Tissue
Imaging," IEEE Transactions on Microwave Theory and Techniques, Vol.
61, No. 9, Sept. 2013, pp. 3424-3434. [Link][PDF]
- The multiplicatively regularized Gauss-Newton inversion (GNI) algorithm
is enhanced and utilized to obtain complex permittivity profiles of
biological objects-of-interest. The microwave scattering data is acquired
using a microwave tomography system comprised of 24 co-resident antennas
immersed into a saltwater matching fluid. Two types of biological targets
are imaged: ex vivo bovine legs and in vivo human forearms. Four different
forms of the GNI algorithm are implemented: a blind inversion, a balanced
inversion, a shape-and-location inversion, and a novel balanced
shape-and-location inversion. The latter three techniques incorporate
typical permittivity values of biological tissues as prior information to
enhance the reconstructions. In those images obtained using the balanced
shape-and-location reconstruction algorithm, the various parts of the tissue
being imaged are clearly distinguishable. The reconstructed permittivity
values in the bovine leg images agree with those obtained via direct
measurement using a dielectric probe. The reconstructed images of the human
forearms qualitatively agree with magnetic resonance imaging images, as well
as with the expected dielectric values obtained from the literature.
[JP56] M. OstadRahimi, A. Zakaria, J. LoVetri, L. Shafai "A
Near-Field Dual Polarized (TE-TM) Microwave Imaging System," IEEE
Transactions on Microwave Theory and Techniques, Vol. 61, No. 3, March
2013, pp. 1376-1384. [Link][PDF]
- In this paper, we introduce a novel dual polarized microwave imaging
system. The system is comprised of a circular array of multiplexed antennas,
distributed evenly around an object-of-interest (OI), along with a novel
plurality of probes located at the antennas apertures. Each probe consists
of several p-i-n diodes biased in two different states (open and short). The
probes are used to measure field scattered by an OI based on the modulated
scatterer technique. Half of the probes are oriented vertically with the
second half oriented horizontally. The presence of the two
probe-orientations enables the imaging system to collect two orthogonal
field polarizations, transverse electric (TE) and transverse magnetic (TM),
without the need for mechanical rotation. In order to illuminate the object
with all possible polarizations of the electromagnetic field, the
transmitting antennas are placed at a slant angle with respect to the
longitudinal plane of the imaging chamber. Near-field data are collected
using each probe set, then calibrated.We show that the calibrated data for
each polarization can be used to reconstruct the dielectric profile of
various objects using either two-dimensional TE or TM inversion algorithms.
[JP55] C. Gilmore,A. Zakaria, J. LoVetri, S. Pistorius "A
Study of Matching Fluid Loss in a Biomedical Microwave Tomography System,"
Medical Physics, Vol. 40, No. 2, February 2013, 14 pages. [Link][PDF]
- Purpose: Effective imaging of human tissue with microwave tomography
systems requires a matching fluid to reduce the wave reflections at the
tissue boundary. Further, in order to match the idealized mathematical model
used for imaging with the complicated physical measurement environment, loss
must be added to the matching fluid. Both too little and too much loss
result in low-quality images, but due to the nonlinear nature of the imaging
problem, the exact nature of loss-to-image quality cannot be predicted a
priori. Possible optimal loss levels include a single, highly sensitive
value, or a broad range of acceptable losses. Herein, the authors outline a
process of determining an appropriate level of loss inside the matching
fluid and attempt to determine the bounds for which the images are the
highest quality.
[JP54]
A. Zakaria, A. Baran, J. LoVetri "Estimation and Use of Prior Information in
FEM-CSI for Biomedical Microwave Tomography", IEEE Antennas and Wireless
Propagation Letters, Vol. 11, pp. 1606-1609 (Invited Paper, Special Cluster
on Microwave Imaging) [Link][PDF]
- Prior information is used to improve imaging results obtained using the
finite-element contrast source inversion (FEM-CSI) of a microwave tomography
(MWT) dataset collected as part of a forearm imaging study. The data consist
of field measurements taken inside a prototype MWT system that uses simple
dipole antennas and a saltwater matching medium. Initial images of the 2-D
cross-sectional dielectric profile of the individuals' arms are
reconstructed using FEM-CSI. These initial blind imaging results show that
the image quality is dependent on the thickness of the arm's peripheral
adipose tissue layer: Thicker layers of adipose tissue lead to poorer
overall image quality. The poor image quality for arms with high levels of
adipose tissue is not improved by changing the matching fluid's complex
dielectric constant. Introducing prior information into the FEM-CSI
algorithm in the form of an inhomogeneous background consisting of an
adipose layer surrounding a muscle region provides substantial improvement
of the image quality: The internal anatomical features of the arm are
resolved for each of the five datasets. Two methods are employed to estimate
the arm periphery and adipose layer thickness from the blind imaging
results: manual estimation and a novel image segmentation algorithm based on
global optimization using simulated annealing.
[JP53] A. Zakaria, J. LoVetri "The Finite-Element Method
Contrast Source Inversion Algorithm for 2D Transverse Electric Vectorial
Problems," IEEE Trans. on Antennas and Propagation, Vol. 60, No. 10,
October 2012, pp. 4757-4765. [Link][PDF]
- The contrast source inversion algorithmis formulated using the
finite-element method for two-dimensional transverse electric microwave
imaging problems. Edge-based triangular elements with vector basis functions
are utilized to solve the TE electromagnetic problem. A single
finite-element method (FEM) mesh is used to model both the electric field as
well as the contrast-source and contrast variables used in the inverse
problem. The electromagnetic field ismodeled by taking the unknown values to
be the tangential components of the transverse electric field along the
edges of each triangular element. The unknown contrast-source and contrast
variables are located at the centroids of every triangular element of the
same FEM mesh, but only inside the imaging domain. The adaptation of the
FEM-contrast source inversion (FEM-CSI) algorithm to 2D-TE problems on such
an arbitrary mesh requires the implementation of special transformation
operators which are presented herein. The algorithm's capabilities are
demonstrated by inverting the Fresnel experimental TE datasets as well as
synthetically generated data.
[JP52] D. Isleifson, I. Jeffrey, L. Shafai, J. LoVetri, D.G.
Barber, "A Monte Carlo Method for Simulating Scattering from Sea Ice using
FVTD," IEEE Transactions on Geoscience and Remote Sensing, Vol. 50, No.
7, July 2012, pp. 2658-2668. [Link][PDF]
- A scattering model based on a Monte Carlo method and the finite-volume
time-domain (FVTD) method has been created for sea ice scattering
simulations. Statistical methods were used to generate a
Gaussian-distributed randomly rough surface. The Polderأ-Van Santende Loor
(PVD) model was used to estimate the sea ice dielectric values with inputs
based upon actual measured physical variables obtained during field-based
experiments and well-known parameterizations. Scattering simulations were
performed through an application of the scattered-field (SF) formulation
invoked in an FVTD computational engine. Simulated SFs were compared with
C-band scatterometer measurements and showed good agreement for copolarized
signals in a series of case studies. The developed simulation method has the
potential to be used for a variety of sea ice types under different physical
conditions.
[JP51] I. Jeffrey, J. LoVetri, "Interfacing Thin-Wire and
Circuit Subcell Models in Unstructured Time-Domain Field Solvers," IEEE
Transactions on Antennas and Propagation, , Vol. 60, No. 4, pp. 1978-1986,
April 2012. [Link][PDF]
- A method for driving and terminating Holland-Simpson based thin-wire
models by arbitrary lumped-element circuits is proposed. The approach uses
the fact that these thin-wire models result in modified Telegrapher's
equations, and interfacing transmission lines and lumped-element circuits is
straightforward. The thin-wire voltage and current at a circuit/wire
junction can be written in terms of circuit nodal voltages nd branch
currents, permitting the circuit solution to act as a boundary condition for
the thin-wire system. In this work, we provide the circuit/wire interfacing
conditions and combine circuits ith Edelvik's Holland-Simpson model that
permits thin-wires to be arbitrarily oriented within an unstructured mesh.
Edelvik's work, previously implemented for finite-difference and
finite-element
time-domain solvers is formulated for the finite-volume
method. Numerical and experimental results for circuit-driven thin-wire
antennas are provided to validate the method.
[JP50] C. Gilmore, A. Zakaria, P. Mojabi, M. OstadRahimi, S.
Pistorius, J. LoVetri, "The University of Manitoba Microwave Imaging Repository:
A Two-Dimensional Microwave Scattering Database for Testing Inversion and
Calibration Algorithms," [Measurements Corner], IEEE Antennas and
Propagation Magazine,, Vol. 53, No.5, pp.126-133, Oct. 2011. [Link][PDF]
- We present a repository of multi-static, near-field microwave scattering
measurements. The data are presented both raw (uncalibrated), and calibrated
with a scattered-field calibration. Measurements were taken with 24
co-resident Vivaldi antennas in a single plane, inside an air-filled
microwave tomography system. The antennas were linearly polarized in the
vertical direction, and we intended for the two-dimensional transverse
magnetic (scalar) approximation to apply. Data are presented for seven
targets, both metallic and dielectric, with varying geometrical complexity.
Data from simple geometric targets, useful for calibration using analytic
equations, are given. The repository is available from the Web site:
http://www.ee.umanitoba.ca/~lovetri/EMILab/MWT_data.html.
[JP49] M. OstadRahimi, P. Mojabi, S. Noghanian, J. LoVetri,
L.Shafai, "A Multiprobe per Collector Modulated Scatterer Technique for
Microwave Tomography," IEEE Antennas and Wireless Propagation Letters,
Vol. 10, pp. 1445-1448, 2011. [Link][PDF]
- Scattering probes with collector antennas can be utilized for microwave
tomography (MWT) applications based on the modulated scatterer technique.
Using this technique, we previously demonstrated a novel tomography system
that utilizes a single printed-wire probe in front of each collector of a
multicollector MWT system. Each collector is implemented as a multilayer
Vivaldi antenna. In this letter, the number of collector antennas is reduced
while maintaining the number of probes. This results in a nonuniform
distribution of probes with respect to the collectors and requires special
calibration techniques to infer the scattered-field at the probe location.
The advantages of using such a configuration for MWT are investigated. Image
reconstructions for a number of targets using data collected from this
system are shown and compared to results obtained from data collected using
a standard MWT system that uses only the Vivaldi antennas. It is shown that
the new configuration successfully extracts useful data at the locations of
the probes, resulting in good tomographic constructions.
[JP48] OstadRahimi, M., Mojabi, P., Gilmore, C., Zakaria,
A., Noghanian, S., Pistorius, S., LoVetri, J. "Analysis of Incident Field
Modeling and Incident/Scattered Field Calibration Techniques in Microwave
Tomography," IEEE Antennas and Wireless Propagation Letters, Vol. 10,
pp. 900-903, 2011. [Link][PDF]
- Imaging with microwave tomography systems requires both the incident
field within the imaging domain as well as calibration factors that convert
the collected data to corresponding data in the numerical model used for
inversion. The numerical model makes various simplifying assumptions, e.g.,
2-D versus 3-D wave propagation, which the calibration coefficients are
meant to take into account. For an air-based microwave tomography system, we
study two types of calibration techniques-incident and scattered field
calibration-combined with two different incident field models: a 2-D
line-source and an incident field from full-wave 3-D simulation of the
tomography system. Although the 2-D line-source approximation does not
accurately model incident field in our system, the use of scattered field
calibration with the 2-D line-source provides similar or better images to
incident and scattered field calibration with an accurate incident field.
Thus, if scattered field calibration is used, a simple (but inaccurate)
incident field is acceptable for our microwave tomography system. While not
strictly generalizable, we expect our methodology to be applicable to most
other microwave tomography systems.
[JP47] M. OstadRahimi, P. Mojabi, S. Noghanian, L. Shafai,
S. Pistorius, J. LoVetri "A Novel Microwave Tomography System based on the
Scattering Probe Technique," IEEE Trans. on Instrumentation and Measurement,
Vol. 61, No. 2, pp. 379-390, Feb., 2012. [Link][PDF]
- In this paper, we introduce a novel microwave tomography system, which
utilizes twenty-four double layered Vivaldi antennas, each of which is
equipped with a diode-loaded printed-wire probe. By biasing probeأ¢â‚¬â„¢s diodes,
the impedance of the probe is modified, allowing an indirect measurement of
the electric field at the probeأ¢â‚¬â„¢s locations. Each printed-wire probe is
loaded with five equally-spaced PIN diodes, in series. We show that the
electric-field data collected in this way within the proposed tomography
system can be used to reconstruct the dielectric properties of an object of
interest. Reconstructions for various objects are shown. Although the
results are still preliminary, sufficient experimentation has been done to
delineate the advantages of such an indirect method of collecting
scattered-field data for tomographic imaging purposes.
[JP46] P. Mojabi, J. LoVetri, L. Shafai "A Multiplicative
Regularized Gauss-Newton Inversion for Shape and Location Reconstruction,"
IEEE Trans. on Antennas and Propagation, Vol. 59, No. 12, December, pp.
4790-4802. [Link][PDF]
- A multiplicative regularized Gauss-Newton inversion algorithm is
proposed for shape and location reconstruction of homogeneous targets with
known permittivities. The data misfit cost-functional is regularized with
two different multiplicative regularizers. The first regularizer is the
weighted L2-norm total variation which provides an edge-preserving
regularization. The second one imposes a priori information about
the permittivities of the objects being imaged. Using both synthetically and
experimentally collected data sets, we show that the proposed algorithm is
robust in reconstructing the shape and location of homogeneous targets.
[JP45] D. Isleifson, I. Jeffrey,L. Shafai, J. LoVetri, D.G.
Barber "An Efficient Scattered-Field Formulation for Objects in Layered Media
using the FVTD Method," IEEE Trans. on Antennas and Propagation, Vol.
59, No. 11, Nov. 2011, pp. 4162-4170. [Link][PDF]
- A technique for efficiently simulating the scattering from objects in
multi-layered media is presented. The efficiency of the formulation comes
from the fact that the sources for the scattered-fields only occur at the
inhomogeneities and therefore the scattered-fields impinging on the
boundaries are more easily absorbed. To demonstrate the technique, a 1D-FDTD
solution to the plane-wave propagation through a multi-layered medium is
used as an incident-field source for a scattered-field formulation of the
FVTD method. Practical aspects of the application are discussed and
numerical examples for scattering from canonical objects are presented to
show the validity of the proposed technique. The simulation scheme described
herein can be used for simulations of geophysical media with appropriate
specifications of the dielectric properties of the media and the
inhomogeneities.
[JP44] A. Zakaria, J. LoVetri "Application of Multiplicative
Regularization to the Finite-Element Contrast Source Inversion Method," IEEE
Trans. on Antennas and Propagation, Vol. 59, No. 9, pp. 3495-3489, 2011. [Link][PDF]
- Multiplicative regularization is applied to the finite element contrast
source inversion (FEM-CSI) algorithm recently developed for microwave
tomography. It is described for the two dimensional (2D) transverse-magnetic
(TM) case and tested by inverting experimental data where the fields can be
approximated as TM. The unknown contrast, which is to be reconstructed, is
represented using nodal variables and first-order basis functions on
triangular elements; the same first-order basis functions used in the FEM
solution of the accompanying field problem. This approach is different from
other MR-CSI implementations where the contrast variables are located on a
uniform grid of rectangular cells and represented using pulse basis
functions. The linear basis function representation of the contrast makes it
difficult to apply the weighted L2-norm total variation multiplicative
regularization which requires that gradient and divergence operators be
applied to the predicted contrast at each iteration of the inversion
algorithm; the use of finite-difference operators for this purpose becomes
unwieldy. Thus, a new technique is introduced to perform these operators on
the triangular mesh.
[JP43] P. Mojabi, J. LoVetri "A Pre-Scaled Multiplicative
Regularized Gauss-Newton Inversion," IEEE Trans. on Antennas and Propagation,
Vol. 59, No. 8, pp. 2954-2963, August 2011. [Link]
[PDF]
- A prescaled multiplicative regularized Gauss-Newton inversion (GNI)
algorithm is proposed which utilizes a priori information about the
expected ratio between the average magnitude of the real and imaginary parts
of the true contrast as well as the expected ratio between the average
magnitude of the gradient of the real and imaginary parts of the true
contrast. Using both synthetically and experimentally collected data sets,
we show that this prescaled inversion algorithm is successful in
reconstructing both real and imaginary parts of the contrast when there is a
large imbalance between the average magnitude of these two parts where the
standard multiplicative regularized Gauss-Newton inversion algorithm fails.
We further show that the proposed prescaled inversion algorithm is robust
and does not require the a priori information to be exact.
[JP42] P. Mojabi, J. LoVetri "A Novel Microwave
Tomography System Using a Rotatable Conductive Enclosure,"IEEE Trans. on
Antennas and Propagation," Vol. 59, No. 5, pp. 1597-1605, May 2011. [Link][PDF]
- A novel microwave tomography (MWT) setup is proposed wherein a rotatable
conductive enclosure is used to generate electromagnetic scattering data
that are collected at each static position of the enclosure using a minimal
antenna array having as few as only four co-resident elements. The antenna
array remains fixed with respect to the target being imaged and only the
boundary of the conductive enclosure is rotated. To show that non-redundant
scattering data can be generated in this way several 2D transverse magnetic
imaging examples are considered using single-frequency synthetic data. For
each example, the reconstruction of the complex permittivity profile is
compared to that obtained using a homogeneous openregion MWT setup having 16
co-resident antennas. The weighted L2-norm total variation
multiplicative-regularized Gauss-Newton inversion (MR-GNI) is used for all
inversions and for the new MWT setup the data collected at all positions of
the conductive enclosure are inverted simultaneously. The quality of images
obtained from the two systems is similar, but the advantage of the new
configuration is its use of a fixed minimal antenna array which will put
less of a burden on the numerical system model.
[JP41] A. Zakaria, C. Gilmore, J. LoVetri "Finite-element
Contrast Source Inversion Method for Microwave Imaging," Inverse Problems,
26 (2010) 115010. [Link][PDF]
- With respect to the microwave imaging of the dielectric properties in an
imaging region, the full derivation of a new inversion algorithm based on
the contrast source inversion (CSI) algorithm and a finite-element method
(FEM) discretization of the Helmholtz differential operator formulation for
the scattered electromagnetic field is presented. The unknown dielectric
properties are represented as nodal values on a two-dimensional (2D)
arbitrary triangular mesh using linear basis functions. The use of FEM to
represent the Helmholtz operator allows for the flexibility of having an
inhomogeneous background medium, as well as the ability to accurately model
any boundary shape or type: both conducting and absorbing. The resulting
sparse and symmetric FEM matrix equation can be solved efficiently, and it
is shown how its solution can be used to calculate the gradient operators
required in the conjugate-gradient CSI update without storing the inverse of
the FEM matrix. The inversion algorithm is applied to conductive-enclosures
of various shapes and unbounded-region microwave tomography configurations
where the 2D transverse magnetic (TM) approximation can be applied.
[JP40] C. Gilmore, P. Mojabi, A. Zakaria, S. Pistorius, J.
LoVetri "On Super-Resolution with an Experimental Microwave Tomography System,"
IEEE Antennas and Wireless Propagation Letters, Vol. 9, pp. 393-396, 2010.
[Link][PDF]
- The resolution of an experimental microwave tomography (MWT) system is
investigated. Using two cylindrical nylon targets and an operating frequency
of 5 GHz, a separation resolution of 2 mm, or 1/30 of a wavelength, is
achieved. While this resolution is among the highest reported in the
literature, it is not a sufficiently robust indicator of the expected
resolution obtainable for complex targets, and this is shown with further
examples of more complicated targets. However, the basic separation
resolution limit obtained is a good way of comparing various aspects of
different MWT systems.
[JP39] M. OstadRahimi, S. Noghanian, L. Shafai, A. Zakaria,
C. Kaye, J. LoVetri "Investigating a Double Layer Vivaldi Antenna Design for
Fixed Array Field Measurement," Int. J. Ultra Wideband Communications and
Systems, Vol. 1, No. 4, pp. 282-290, 2010. [Link][PDF]
- Vivaldi antenna is widely known as a broadband antenna. In this paper,
we investigate a modified Vivaldi antenna with improved cross polarisation
working in the ultra-wideband (UWB) frequency range (3.1-10.6 GHz) to be
used as multiple probes for microwave tomography system. Our study includes
investigation of radiation characteristics of the antenna, antenna design
steps, fabrication sensitivity effects on the antenna performance and
proposing and implementing a twenty-four antenna element system for fast
data acquisition, including a novel method for frequency selection in
microwave tomography applications. We also studied the fidelity parameter of
the antennas inside the twenty-four element setup. The mutual coupling of
adjacent elements, in spite of close proximity, is less than -17dB and
fidelity variations for the antennas located in front of transmitter are
less than 10%.
[JP38] C. Gilmore, P. Mojabi, A. Zakaria, M. OstadRahimi, C.
Kaye, S. Noghanian, L. Shafai, S. Pistorius, J. LoVetri, "A Wideband Microwave
Tomography System with a Novel Frequency Selection Procedure," IEEE Trans.
on Biomedical Engineering, Vol. 57, No. 4, pp. 894-904, April 2010. [Link][PDF]
- In this paper, we describe a 2-D wideband microwave imaging system
intended for biomedical imaging. The system is capable of collecting data
from 3 to 6 GHz, with 24 coresident antenna elements connected to a vector
network analyzer via a 2 x 24 port matrix switch. As one of the major
sources of error in the data collection process is a result of the strongly
coupling 24 coresident antennas, we provide a novel method to avoid the
frequencies where the coupling is large enough to prevent successful
imaging. Through the use of two different nonlinear reconstruction schemes,
which are an enhanced version of the distorted born iterative method and the
multiplicative regularized contrast source inversion method, we show imaging
results from dielectric phantoms in free space. The early inversion results
show that with
the frequency selection procedure applied, the system is
capable of quantitatively reconstructing dielectric objects, and show that
the use of the wideband data improves the inversion results over
single-frequency data.
[JP37] P. Mojabi, J. LoVetri, "Comparison of TE and TM
Inversions in the Framework of the Gauss-Newton Method," IEEE Trans. on
Antennas and Propagation, Vol. 58, No. 4, pp. 1336-1348, 2010. [Link][PDF]
- The Gauss-Newton inversion method in conjunction with a regularized
formulation of the inverse scattering problem is used to invert transverse
electric (TE) and transverse magnetic (TM) data. The utilized data sets
consist of experimental data provided by the Institut Fresnel as well as
synthetic data. TheTE inversion outperformed the TM inversion when utilizing
near-field scattering data collected using only a few transmitters and
receivers. However, very little difference was found between TE and TM
inversions when using far-field scattering data. It is conjectured that the
reason for the better performance of the near-field TE result is that the
near-field TE data contains more information than the near-field TM data at
each receiver point. In all cases considered herein, the TE inversion
required equal or fewer iterations than the TM inversion. The per-iteration
computational complexity of both TE and TM inversions is discussed in the
framework of the Gauss-Newton inversion method. Actual costs are consistent
with the computational complexity analysis that is given.
[JP36] P. Mojabi, J. LoVetri, "Eigenfunction Contrast Source
Inversion for Circular Metallic Enclosures," Inverse problems, Vol. 26,
025011 (23pp), Jan. 2010. [Link][PDF]
- The microwave imaging problem is considered where an object of interest
is surrounded by a circular metallic enclosure. A new contrast source
inversion (CSI) algorithm which uses eigenfunction expansions of the
unknowns is presented for the reconstruction of the complex dielectric
profile. Orthonormal eigenfunction expansions associated with the Helmholtz
operator for a homogeneous medium and Dirichlet boundary conditions are used
for the unknown contrast source and the contrast functions in the CSI
functional. These are also used to express the incident field, which is
assumed known, as well as for expanding the inverse Helmholtz operator in
the CSI functional. The imaging domain is taken to be the whole interior of
the metallic enclosure. No prior information, other than keeping the
permittivity profile physical, is used. Results are provided for synthetic
as well as experimental data. Based on the number of eigenfunctions used, a
theoretical limit to the reconstruction quality is defined. Normalized
errors relative to this theoretical limit are provided for each of the
synthetic data sets.
[JP35] C. Gilmore, J. LoVetri, "Corrigendum on 'Enhancement
of microwave tomography through the use of electrically conducting enclosures',"
Inverse Problems, Vol. 26, 019801 (7pp), Jan. 2010. [Link][PDF]
- Corrigendum and comments on [JP28]
[JP34] P. Mojabi, J. LoVetri, "Enhancement of the Krylov
Subspace Regularization for Microwave Biomedical Imaging," IEEE Trans. on
Medical Imaging, Vol. 28, No. 12, pp. 2015-2019, Dec. 2009. [Link][PDF]
- Although Krylov subspace methods provide fast regularization techniques
for the microwave imaging problem, they cannot preserve the edges of the
object being imaged and may result in an oscillatory reconstruction. To
suppress these spurious oscillations and to provide an edge-preserving
regularization, we use a multiplicative regularizer which improves the
reconstruction results significantly while adding little computational
complexity to the inversion algorithm. We show the inversion results for a
real human forearm assuming the 2D transverse magnetic illumination and a
cylindrical object assuming the 2D transverse electric illumination.
[JP33] P. Mojabi, J. LoVetri, "Overview and Classification
of Some Regularization Techniques for the Gauss-Newton Inversion Method Applied
to Inverse Scattering Problems," IEEE Trans. on Antennas and Propagation,
Vol. 57, No. 9, pp. 2658-2665, 2009. [Link][PDF]
- Different regularization techniques used in conjunction with the
Gauss-Newton inversion method for electromagnetic inverse scattering
problems are studied and classified into two main categories. The first
category attempts to regularize the quadratic form of the nonlinear data
misfit cost-functional at different iterations of the Gauss-Newton inversion
method. This can be accomplished by utilizing penalty methods or projection
methods. The second category tries to regularize the nonlinear data misfit
cost-functional before applying the Gauss-Newton inversion method. This type
of regularization may be applied via additive, multiplicative or
additive-multiplicative terms. We show that these two regularization
strategies can be viewed from a single consistent framework.
[JP32] P. Mojabi, J. LoVetri, "Microwave Biomedical Imaging
Using the Multiplicatively Regularized Gaussأ¢â‚¬â€œNewton Inversion Method," IEEE
Antennas and Wireless Propagation Letters, Vol. 8, pp. 645-648, July 2009.
[Link][PDF]
- The weighted L2-norm total variation multiplicative regularized
GaussNewton inversion method, recently developed for inversion of
low-frequency deep electromagnetic geophysical measurements, is used for
microwave biomedical imaging. This inversion algorithm automatically adjusts
the regularization weight and provides edge-preserving characteristics. The
accuracy of this method is demonstrated by inverting experimental data of a
human forearm and synthetic data taken from brain and breast models, both
assuming two-dimensional (2D) transverse magnetic illumination.
[JP31] C. Gilmore, P. Mojabi, J. LoVetri "Comparison of an
Enhanced Distorted Born Iterative Method and the Multiplicative-Regularized
Contrast Source Inversion Method," IEEE Trans. on Antennas and Propagation,
Vol. 57, No. 8, pp. 2341-2351, August 2009. [Link][PDF]
- For 2D Transverse Magnetic (TM) microwave inversion,
Multiplicative-Regularized Contrast Source Inversion (MR-CSI), and the
Distorted Born Iterative Method (DBIM) are compared. The comparison is based
on a computational resource analysis, inversion of synthetic data, and
inversion of experimentally collected data from both the Fresnel and UPC
Barcelona data sets. All inversion results are blind, but appropriate
physical values for the reconstructed contrast are maintained. The data sets
used to test the algorithms vary widely in terms of the background media,
antennas, and far/near field considerations. To ensure that the comparison
is replicable, an automatic regularization parameter selection method is
used for the additive regularization within the DBIM, which utilizes a fast
implementation of the L-curve method and the Laplacian regularizer.
While not used in the classical DBIM, we introduce an MR term to the DBIM in
order to provide comparable results to MR-CSI. The introduction of this MR
term requires only slight modifications to the classical DBIM algorithm, and
adds little computational complexity. The results show that with the
addition of the MR term in the DBIM, the two algorithms provide very similar
inversion results, but with the MR-CSI method providing advantages for both
computational resources and ease of implementation.
[JP30] D.K. Firsov and J. LoVetri, "New Stability Criterion
for Unstructured Mesh Upwinding FVTD Schemes for Maxwell's Equations," ACES
Journal, Vol. 23, No. 3, pp. 193-199, September 2008. [Link][PDF]
- A new stability criterion applicable to explicit upwind FVTD schemes for
solving Maxwellأ¢â‚¬â„¢s equations on unstructured meshes is derived. This
criterion is based on L2-norm estimates of specially constructed
matrices Gi for each finite volume i. Each such matrix is
constructed using the scalar product of the eigenvectors corresponding to
the unity eigenvalues of the fluxsplitting operators associated with the
facets of volume i. The new stability criterion is obtained
numerically once the grid is constructed using these matrices over the mesh
and is therefore mesh dependent. The new criterion gives a time-step that is
larger than the time-step calculated using previously published stability
criteria. On structured meshes the new criterion gives the same time-step
limit as the von Neumann analysis. The method incurs a small computational
expense at the beginning of each run of the algorithm. The method is
generalizable but the extent to which it can be generalized to other
time-evolving physical phenomenon is not considered in this paper.
[JP29] P. Mojabi and J. LoVetri, "Preliminary Investigation
of the NCP Parameter-Choice Method for Inverse Scattering Problems Using BIM:
2-D TM Case," ACES Journal, Vol. 23, No. 3, pp. 207-214, September
2008. [Link][PDF]
- A new method of choosing the regularization parameter, originally
developed for a general class of discrete ill-posed problems, is
investigated for electromagnetic inverse scattering problems that are
formulated using a penalty method. This so-called normalized cumulative
periodogram (NCP) parameterchoice method uses more information available in
the residual vector, as opposed to just its norm, and attempts to choose the
largest regularization parameter that makes the residual resemble white
noise. This is done by calculating the NCP of the residual for each choice
of the regularization parameter, starting from large values and stopping at
the first parameter which puts the NCP inside the Kolmogorov-Smirnov limits.
The main advantage of this method, as compared, for example, to the L-curve
and Generalized Cross-Validation (GCV) techniques, is that it is
computationally inexpensive and therefore makes it an appropriate technique
for large-scale problems arising in inverse imaging. In this paper, we apply
this technique to the general-form Tikhonovregularized functional arising in
the 2-D/TM inverse electromagnetic problem, which is formulated via an
integral equation and solved using the Born Iterative Method (BIM).
[JP28] C. Gilmore and J. LoVetri, "Enhancement of microwave
tomography through the use of electrically conducting enclosures," Inverse
Problems, vol. 24, issue 3 (21 pp), June 2008 (was online 8 April 2008). [Link][PDF]
- We consider microwave tomography (MWT) where the imaging region is
surrounded by an electrically conducting surface. This surface acts as both
a shield from outside interference, holding tank for any possiblematching
media, and, in certain cases, serves to enhance the performance of
electromagnetic (EM) inversion algorithms. For the 2D transverse magnetic
(TM) case and where the surface consists of a perfect electrical conductor
(PEC) in the shape of a circular cylinder, we formulate an appropriate
Greens function which is amenable to implementation in the existing EM
inversion codes. We utilize this Greens function in the
multiplicative-regularized contrast source inversion (MR-CSI) method.
Several different synthetic examples are used to test the performance of the
inversion when the PEC surface is present and the results show that in many
cases, the tomographic image is significantly improved. The reasons for the
improved inversion results are an area of active research, but are likely to
be due to the increased interrogation energy deposited into the imaging
region. Results are also shown which demonstrate the problems which may
arise if the unbounded domain Greens function is used in an MWT system that
utilizes a matching medium of finite extentأ¢â‚¬â€a problem which is overcome by
the inclusion of a PEC surface on the exterior of the MWT system.
[JP27] P. Mojabi and J. LoVetri, "Adapting the Normalized
Cumulative Periodogram Parameter-Choice Method to the Tikhonov Regularization of
2-D/Tm Electromagnetic Inverse Scattering Using Born Iterative Method,"
Progress In Electromagnetics Research M, vol. 1, pp. 111-138, 2008. [Link][PDF]
- A new method of choosing the regularization parameter, originally
developed for a general class of discrete ill-posed problems,is investigated
for electromagnetic inverse scattering problems that are formulated using a
penalty method. This so-called Normalized Cumulative Periodogram (NCP)
parameter-choice method uses more than just the norm of the residual to
determine the regularization parameter, and attempts to choose the largest
regularization parameter that makes the residual resemble white noise. This
is done by calculating the NCP of the residual vector for each choice of the
regularization parameter, starting from large values and stopping at the
first parameter which puts the NCP inside the Kolmogorov- Smirnov limits.
The main advantage of this method, as compared, for example, to the L-curve
and Generalized Cross Validation (GCV) techniques, is that it is
computationally inexpensive and therefore makes it an appropriate technique
for large-scale problems arising in inverse imaging. In this paper, we apply
this technique, with some modification, to the Tikhonov-regularized
functional arising in the 2-D Transverse Magnetic (TM) inverse
electromagnetic problem, which is formulated via an integral equation and
solved using the Born iterative method (BIM).
[JP26] B. Kordi, G.E. Bridges, J. LoVetri, and J.E.
Nordstrom, "Full-wave Based Transmission-line Model for Lossy-substrate
Multiconductor Interconnects," Int. J. of Numerical Modelling: Electronic
Networks, Devices and Fields (Special Issue on Frontiers of Applied
Computational Electromagnetics), vol. 21, no. 1-2, pp. 103-115, January-April
2008. [Link][PDF]
- A full-wave-based modal analysis is used for simulating a multiconductor
coplanar waveguide (CPW) over a selectively etched lossy silicon substrate.
Propagating modes, which are similar to the classic أ¢â‚¬ع©commonأ¢â‚¬â„¢ and
أ¢â‚¬ع©differentialأ¢â‚¬â„¢ modes, are extracted, and circuit theory energy relationships
are used for the determination of transmission-line model parameters. A
time-frequency domain technique is employed for implementing the
transmission-line model within a circuit simulator. The model is used to
study the effect of etching the dielectric and the substrate for a
two-conductor CPW line. The simulation results show that etching both the
dielectric and the lossy substrate improves the loss and dispersion
characteristics of the CPW line.
[JP25] D.K. Firsov and J. LoVetri, "FVTDأ¢â‚¬â€Integral Equation
Hybrid for Maxwellأ¢â‚¬â„¢s Equations," Int. J. of Numerical Modelling: Electronic
Networks, Devices and Fields (Special Issue on Frontiers of Applied
Computational Electromagnetics), vol. 21, no. 1-2, pp. 29-42, January-April
2008. [Link][PDF]
- A new hybrid finite-volume time-domain integral equation (FVTD/IE)
algorithm for the solution of Maxwellأ¢â‚¬â„¢s Equations on unstructured meshes of
arbitrary flat-faceted volume elements is presented. A time-domain IE-based
numerical algorithm is applied on the boundary of the computational domain
to determine the incoming fluxes for the boundary facets of the mesh. This
method is a global grid-truncation technique similar to the method
previously introduced for the finite-difference time-domain scheme by
Ziolkowski et al. The three main advantages of this IE truncation method are
that (1) it allows geometrical objects to be located (almost) arbitrarily
close to the mesh boundaries without compromising the physics of the
problem, (2) it couples the physics of unconnected meshes so that distant
scatterers can be surrounded by their own local mesh, thus reducing total
mesh size, and (3) the same IE formulation can be used to compute
electromagnetic field values at points outside the mesh. Currently, the main
disadvantage is that an acceleration scheme for performing the IE update,
which requires integrating field components on an interior surface at a
retarded time, is not available. Computational results are presented for the
scattering from a perfectly electrical conducting sphere and compared
numerically with the analytic time-domain solution as well as the solution
obtained using a large spherical outer mesh boundary with local absorbing
boundary conditions. Results are excellent and show almost no reflections
from the mesh boundary even when the observation point is located close to
the corner of the cubically shaped outside mesh boundary. Results are also
presented and validated for the scattering from two objects that are
contained inside their own unconnected meshes.
[JP24] I. Jeffrey, V. Okhmatovski, J. LoVetri and C.
Gilmore, "An Adaptive Basis Function Solution to the 1D and 2D Inverse
Scattering Problems using the DBIM and the BIM," ACES Journal, vol. 22,
no. 1, pp. 60-70, March 2007. [Link][PDF]
- We present the use of an adaptive set of basis functions used in
conjunction with the MoM to solve the linearized scalar inverse
electromagnetic scattering problem. The basis functions, which are
whole-domain and harmonic, are selected to provide a perfectly conditioned
solution under the first-order Born approximation when multiple frequency
experiments are considered. In order to iteratively solve the full nonlinear
problem by the Distorted Born Iterative Method (DBIM) and/or the Born
Iterative Method (BIM), we introduce a single parameter into the basis
function expansion to demonstrate that it is possible to maintain a
well-conditioned linearized inverse problem by selecting the parameter value
that minimizes the condition number of the discrete matrix operator. The
proposed technique eliminates the need for Tikhonov regularization or
equivalent regularization schemes commonly applied to the single-frequency,
pulse-basis formulation of the linearized inverse scattering problem.
[JP23] D. Firsov, J. LoVetri, I. Jeffrey, V. Okhmatovski, C.
Gilmore, and W. Chamma, "High-Order FVTD on Unstructured Grids using an
Object-Oriented Computational Engine," ACES Journal, vol. 22, no. 1,
pp. 71-82, March 2007. [Link][PDF]
- An object-oriented implementation of a finite-volume time-domain (FVTD)
engine for solving Maxwellأ¢â‚¬â„¢s equations is presented. The relevant aspects of
the FVTD method are discussed from an objectoriented perspective and details
of the object classes are given. Computational results obtained using the
FVTD engine for solving Maxwellأ¢â‚¬â„¢s Equations on unstructured grids are also
shown. The engine implements both MUSCL and polynomial interpolation methods
to approximate the fluxes at the cell boundaries up to thirdorder accuracy.
In addition, the engine has the capability of using a number of
time-integration schemes. Results are presented for the transient scattering
from a PEC sphere and a lossy dielectric cube. For the case of the sphere,
almost perfect agreement with the analytic solution in the time-domain is
achieved. The number of cells required as compared to FDTD is substantially
reduced.
[JP22] C. Gilmore, I. Jeffrey, and J. LoVetri, "Derivation
and Comparison of SAR and Frequency-Wavenumber Migration Within a Common Inverse
Scalar Wave Problem Formulation," IEEE Transactions on Geoscience and Remote
Sensing, vol. 44, no. 6, pp. 1454-1461, June 2006. [Link][PDF]
- Two common Fourier imaging algorithms used in ground penetrating radar
(GPR), synthetic aperture radar (SAR), and frequency-wavenumber (F-K)
migration, are reviewed and compared from a theoretical perspective. The two
algorithms, while arising from seemingly different physical models: a
point-scatterer model for SAR and the exploding source model for F-K
migration, result in similar imaging equations. Both algorithms are derived
from an integral equation formulation of the inverse scalar wave problem,
which allows a clear understanding of the approximations being made in each
algorithm and allows a direct comparison. This derivation brings out the
similarities of the two techniques which are hidden by the traditional
formulations based on physical scattering models. The comparison shows that
the approximations required to derive each technique from the integral
equation formulation of the inverse problem are nearly identical, and hence
the two imaging algorithms and physical models are making similar
assumptions about the solution to the inverse problem, thus clarifying why
the imaging equations are so similar. Sample images of landmine-like targets
buried in sand are obtained from experimental GPR data using both
algorithms.
[JP21] B. Kordi, J. LoVetri, and G. E. Bridges,
"Finite-Difference Analysis of Dispersive Transmission Lines Within a Circuit
Simulator," IEEE Transactions on Power Delivery, vol. 21, pp. 234-242,
2006. [Link][PDF]
- In this paper, a finite-difference time-domain (FDTD) analysis of the
transmission line equations for a general circuit simulator is presented. A
two-port circuit representation is derived for integrating a dispersive
transmission line network within a circuit/system simulator. The circuit
model consists of resistive elements and dependent current sources, which
are updated at every time step by the FDTD algorithm. The frequency
dependence of the conductors' parameters is taken care of by a recursive
integration that employs the Vector Fitting algorithm. The application of
this model is presented for several examples, such as nonuniform
transmission lines, plane wave excitation of the line, and determination of
overvoltages induced by a nearby lightning stroke.
[JP20] I. Jeffrey, C. Gilmore, G. Siemens, and J. LoVetri,
"Hardware invariant protocol disruptive interference for 100BaseTX Ethernet
communications," IEEE Transactions on Electromagnetic Compatibility, vol.
46, pp. 412-422, 2004. [Link][PDF]
- In this paper, we introduce a new concept that we refer to as hardware
invariant protocol disruptive interference (HIPDI). Such interference would
pose a severe threat as intentional EMI to the corresponding protocol for
which it was designed. In this paper, we consider only the 100BaseTX
Ethernet protocol over UTP CAT-5 cable which is used extensively in
local-area networks. We show that low power, narrowband, differential-mode
voltage levels on a 100BaseTX Ethernet twisted-pair can seriously degrade
network throughput independent of the physical features of the network or
the protocol interpreter hardware. Moreover, we show that the required
parameters of disruptive interference can be derived from the protocol
itself using a concept we call hardware aperture. The experimental results
reported herein indicate that creating such interference is practically
feasible and therefore, is a possible threat to existing communication
networks.
[JP19] J. E. Makaran and J. LoVetri, "BLDC motor and drive
conducted RFI simulation for automotive applications," IEEE Transactions on
Electromagnetic Compatibility, vol. 45, pp. 316-329, 2003. [Link][PDF]
- In considering automotive conducted radio-frequency-interference (RFI)
specifications applicable to motors and their associated drives, simulation
of conducted RF emissions in the range from 150 kHz to 30 MHz is an area of
interest from the product design perspective for several reasons.
Traditionally, suppression of conducted noise in this frequency range of
interest has been achieved through the use of bulk suppression elements such
as capacitors and inductors. These elements consume valuable space within
the motor, as well as add cost. The selection of bulk noise suppression
elements, has, in the past, been predominately made through trial and error
"brute force" methods. A method is presented whereby conducted RFI emissions
can be simulated through the use of a high-fidelity virtual motor and drive
model, as well as a virtual spectrum analyzer. Experimental validation of
the model shows that accurate predictions can be made in the low-frequency
range, below 10 MHz. Suggestions are made on how to improve the model at
higher frequencies.
[JP18] S. Primak, J. LoVetri, and J. Roy, "On the statistics
of a sum of harmonic waveforms," IEEE Transactions on Electromagnetic
Compatibility, vol. 44, pp. 266-271, 2002. [Link][PDF]
- In this paper, we address certain aspects of the problem of
statistically characterizing the electromagnetic field inside an enclosure.
The field that we are interested in describing is time-harmonic and a
three-dimensional spatial vector; therefore, two random variables are
required for each vector component at each location in the enclosure. We can
describe either the magnitude (or intensity) and phase, or the real
(in-phase) and imaginary (quadrature) parts, of each spatial component. It
is the relationship between these two modes of description that is addressed
in this paper. We show that this relationship is given by the Blanc-Lapierre
transform and when there is a sum of more than one time-harmonic field, by
equations first derived by Kluyver. The relationships are derived for any
form of distribution taken on by any of the random variable. We also address
issues related to the approximation of the probability density function
(pdf) of the amplitude of an electromagnetic field given a known pdf of the
intensity of this field. The work presented herein fills in some of the gaps
which were left in some literature wherein the independence of the variables
to each other was assumed, that is, the independence of the in-phase to the
quadrature variables.
[JP17] T. Lapohos and J. LoVetri, "Forcing term
discretization techniques in the external field-to-MTL coupling problems,"
International Journal of Numerical Modelling: Electronic Networks, Devices and
Fields, vol. 14, pp. 31-47, 2001. [Link][PDF]
- In this paper, two, under certain conditions, equivalent models of
electromagnetic plane wave coupling to multiconductor transmission lines
(MTLs) are described. The?frequency-to-time domain? (FTD) model incorporates
the effect of the impinging electromagnetic waves by means of distributed
voltage and current sources whose expressions are found through mathematical
approximations made in the frequency domain followed by a transformation to
the time domain. The approximations were made in order to gain an advantage
in computation time in the discrete FTD (DFTD) model. In contrast to this
approach, the same distributed sources of the?approximate analytic? (AA)
model are derived by directly evaluating the corresponding integral
formulas. It is shown that, although the same second-order-accurate
discretization technique has been employed to create both the DFTD and the
discrete AA (DAA) models, the simulation results are not the same. In the
case of the DFTD model, significant numerical error can be seen in the
simulation results, whereas the DAA model does not show such a behaviour. It
is shown that time averaging of the forcing terms in the DFTD model helps to
reduce the numerical errors significantly at no extra computational cost.
[JP16] T. Lapohos, J. LoVetri, and J. Seregelyi, "External
field coupling to MTL networks with nonlinear junctions: numerical modeling and
experimental validation," IEEE Transactions on Electromagnetic Compatibility,
vol. 42, pp. 16-28, 2000. [Link][PDF]
- The problem of predicting the voltages and currents induced on a printed
circuit multiconductor transmission line (MTL) network by an impinging
transient plane wave electromagnetic field is considered. The MTL network
contains nonlinear circuit elements and test cases with various dielectric
substrates are examined. Numerical predictions based on quasi-TEM models of
the MTL and modified nodal analysis (MNA) models of the lumped element
junctions are compared to experimental results obtained in the time domain
using a GTEM cell. As has been done in the past, the effect of the incident
plane wave is introduced as forcing functions in the MTL equations. The
primary goal of this paper is to quantify the accuracy of the various
commonly used quasi-TEM mathematical time-domain models. It is shown that
when modeling the forcing function terms, it is important to take into
account the perturbation of the incident plane wave due to the dielectric
substrate. (The experimental-numerical comparisons herein are shown for the
case of end-fire illumination since it best demonstrates this point.)
Neglecting the dielectric effect on the incident transient pulse, even for
substrates with low dielectric constant, produces poor results.
[JP15] N. R. S. Simons, R. Siushansian, J. LoVetri, and M.
Cuhaci, "Comparison of the transmission-line matrix and finite-difference
time-domain methods for a problem containing a sharp metallic edge," IEEE
Transactions on Microwave Theory and Techniques, vol. 47, pp. 2042-2045,
1999. [Link][PDF]
- We compare Yee's finite-difference time-domain (FDTD) and symmetric
condensed node transmission-line matrix (SCN-TLM) solutions for a cavity
containing a metallic fin. Differential equation-based numerical methods are
known to produce inaccurate results for this type of problem due to the
rapid spatial variation of the field distribution in the vicinity of the
singularity at the edge of the metal fin. This problem is relevant to the
analysis of structures of practical interest such as microstrip and coplanar
waveguides. Based on simulations, it is determined that for identical
discretizations, SCN-TLM is more accurate than FDTD for this problem. We
interpret this result as an indication that the symmetric condensed
representation of fields (used within the SCN-TLM) lends itself to a more
accurate algorithm than the distributed representation used by Yee. We
estimate that the FDTD method requires 3.33 times more cells for a given
three-dimensional problem than the transmission-line matrix (TLM) method
(1.49 times more cells per linear dimension of the problem) in order to
achieve the same accuracy. If we consider the requirements to update and
store a single TLM or FDTD cell, we find the SCN-TLM algorithm is more
efficient than the Yee FDTD algorithm in terms of both computational effort
and memory requirements. Our conclusions regarding computational effort and
memory requirements are limited to problems with homogeneous material
properties.
[JP14] S. L. Primak, J. LoVetri, Z. Damjanschitz, and S.
Kashyap, "Auto-regressive filter-based E-pulse discriminating scheme," IEEE
Transactions on Antennas and Propagation, vol. 47, pp. 216-218, 1999. [Link][PDF]
- Ultrawide-band radar target discrimination schemes have been of great
interest during the last two decades. One of the most used methods is the
so-called E-pulse discrimination scheme, which is based on the late-time
impulse response of a target. Traditional techniques to construct the proper
E-pulses require the determination of the natural frequencies as an
intermediate step. Here, we present a technique that allows us to obtain the
required E-pulses directly. The approach suggested is applied to two simple
three-dimensional (3D) targets: a rectangular cavity and a strip with a fin.
[JP13] R. Siushansian and J. LoVetri, "Efficient evaluation
of convolution integrals arising in FDTD formulations of electromagnetic
dispersive media," Journal of Electromagnetic Waves and Applications,
vol. 11, pp. 101, 1997. [Link][PDF]
- The Trapezoidal Recursive Convolution (TRC) scheme was previously used
to model Nth order Lorentz type dispersive media. In this paper, the full
derivation of this quasi-trapezoidal-based algorithm is presented and the
derivation is expanded to include the Nth order Debye type dispersion as
well as Sellmeyer's dispersion equation. In addition, the case of general
convolution integrals is considered where any arbitrary integrand or the
integral itself is represented as a sum of exponential functions, i.e.
Prony's method. The technique is compared to several previously published
schemes and it is shown that its performance equals or exceeds various other
methods in terms of accuracy, robustness, and computational efficiency. A
comparison to the exact application of trapezoidal numerical integration is
made and it is shown that, for time increments encountered in typical FDTD
analyses, the truncation error due to applying the quasi-trapezoidal
approximation is negligible. Finally, it is shown how the skin effect
phenomenon, as it applies to multiconductor transmission lines, can be
modeled using a rational function approximation to the frequency dependency
of the line resistance. This model is obtained by using Levy's method to
curve fit the line resistance directly in the frequency domain and then the
convolution integral is formulated in a form amenable to the TRC algorithm.
[JP12] J. LoVetri and T. Lapohos, "Explicit upwind schemes
for lossy MTLs with linear terminations," IEEE Transactions on
Electromagnetic Compatibility, vol. 39, pp. 189-200, 1997. [Link][PDF]
- The time domain multiconductor transmission line (MTL) equations are
written as a general first order system of partial differential equations
and a characteristic decomposition is used to obtain first order and second
order accurate upwind differencing schemes. Linear boundary conditions in
the form of generalized Thevenin equivalent sources are incorporated into
the scheme. These schemes are compared with the standard time-space centered
second order accurate leapfrog scheme where the current and voltage
variables are interlaced in space and time. For any general explicit
numerical scheme, for a given MTL, only the fastest propagating TEM mode can
be solved for at the Courant limit of the scheme. This causes the other
slower modes to disperse. The results of our comparisons, show that at the
Courant number both upwind schemes produce less numerical dispersion for the
slower propagating modes than the standard leapfrog scheme under the same
conditions. In addition, the Courant number of the second order upwind
scheme is twice that of the leapfrog scheme. These advantages make the
upwind schemes better tools to model inhomogeneous MTLs with linear
terminations.
[JP11] M. Rizvi and J. LoVetri, "Modeling and reduction of
crosstalk on coupled microstrip line structures and multichip modules: an FDTD
approach," International Journal of Microwave and Millimeter-Wave
Computer-Aided Engineering, vol. 6, pp. 58, 1996. [Link][PDF]
- The finite difference time domain modeling technique is used to model
the near end and far end crosstalk on coupled microstrip structures used in
multichip modules. The lines are terminated in lumped resistors which
closely, but not exactly, match the lines. One line is excited by a Gaussian
voltage pulse produced by a Thevenin equivalent voltage source. It is shown
that adding dielectric strips in the substrate below the conducting lines
will reduce the peak crosstalk by as much as 80%. Eight different
configurations are modeled consisting of dielectric strips with different
dielectric constant combinations. All configurations are modeled with and
without a metal case in order to make sure that the crosstalk reduction
persists when the structure is enclosed in a metallic enclosure (this would
be the case for multichip modules). The results show that using dielectric
strips with the smallest possible dielectric constant reduces crosstalk the
most.
[JP10] J. LoVetri, D. Mardare, and G. Soulodre, "Modeling of
the seat dip effect using the finite-difference time-domain method," The
Journal of the Acoustical Society of America, vol. 100, pp. 2204-2212, 1996.
[Link][PDF]
- In this paper the use of the finite-difference time-domain technique for
the modeling of the seat dip effect in concert halls is demonstrated. The
linear time-domain acoustic partial differential equations are discretized
using a finite-difference technique. The second-order accurate differencing
scheme is timeأ¢â‚¬â€œspace centered, and the velocity and pressure are solved on
an interlaced mesh. First- and second-order Mur absorbing boundary
conditions, originally formulated for electromagnetic problems, are adapted
to the acoustics case and used to truncate the numerical grid. The technique
is first verified by comparing the numerical results to the analytic
solution of a simple point source. Results from computer simulations of the
seat dip phenomena are compared with the findings of previous studies where
measurements had been made on scale models and in real concert halls. The
computer model successfully predicts the effects associated with the
sourceأ¢â‚¬â€œreceiver distance, the height of the receiver, and the height of the
source.
[JP09] R. Siushansian and J. LoVetri, "A comparison of
numerical techniques for modeling electromagnetic dispersive media," IEEE
Microwave and Guided Wave Letters, vol. 5, pp. 426-428, 1995. [Link][PDF]
- A comparison of various time domain numerical techniques to model
material dispersion is presented. Methods that model the material dispersion
via a convolution integral as well as those that use a differential equation
representation are considered. We have shown how the convolution integral
arising in the electromagnetic constitutive relation can be approximated by
the trapezoidal rule of numerical integration and implemented using a newly
derived one-time-step recursion relation. The superiority of the new method,
in terms of accuracy and computer resources, over four previously published
techniques is demonstrated on the problem of a transient electromagnetic
plane wave propagating in a dispersive media. All of the methods considered
are easily incorporated into 3-D codes where the requirement for efficiency
is very important.
[JP08] D. Mardare and J. LoVetri, "The finite-difference
time-domain solution of lossy MTL networks with nonlinear junctions," IEEE
Transactions on Electromagnetic Compatibility, vol. 37, pp. 252-259, 1995. [Link][PDF]
- We describe a numerical technique to solve lossy multiconductor
transmission line (MTL) networks, also known as tube/junction networks,
which contain nonlinear lumped circuits in the junctions. The method is
based on using a finite-difference technique to solve the time-domain MTL
equations on the tubes, as well as the modified nodal analysis (MNA)
formulation of the nonlinear lumped circuits in the junctions. The important
consideration is the interface between the MTL and MNA regimes. This
interface is accomplished via the first and last finite-difference
current/voltage pair on each MTL of the network and, except for this, the
two regimes are solved independently of each other. The advantage of the
FDTD method is that the MTL equations may contain distributed source terms
representing the coupling with an external field. We apply the method to
previously published examples of multiconductor networks solved by other
numerical methods, and the results agree exceptionally well. The case of an
externally coupled field is also considered.
[JP07] J. B. Ehrman and J. LoVetri, "Time-domain
electromagnetic plane waves in static and dynamic conducting media. II," IEEE
Transactions on Electromagnetic Compatibility, vol. 37, pp. 17-25, 1995. [Link][PDF]
- The electromagnetic field inside a lossy half-space for the case of a
transient electromagnetic plane wave impinging on the half-space from free
space is derived. The losses in the half-space are modeled by assuming
either a static (J=σE) or a dynamic (τ∂J/∂t+J=σ0E) conducting medium.
Solutions are derived directly from the first order system of partial
differential equations, i.e. the Maxwell equations. Plots for the total
fields at the half-space boundary are given and expressions for the fields
anywhere inside the half-space based on these boundary fields are given.
Asymptotic formulae for late and early times are derived for the case of a
step function as well as a square pulse plane wave
[JP06] M. Krumpholz, P. Russer, J. LoVetri, and N. R. S.
Simons, "Comments on "A class of symmetrical condensed node TLM methods derived
directly from Maxwell's equations"; [and reply]," IEEE Transactions on
Microwave Theory and Techniques, vol. 42, pp. 1586, 1994. [Link][PDF]
- In the original paper, LoVetri and Simons [see ibid, vol.41, p.
1419-28,1993] derive the three-dimensional symmetrical condensed node TLM
algorithm using a characteristic based field decomposition of Maxwell's
equations. The goal and eventual result of the investigation was to present
a mathematically sound method for deriving the TLM scattering and transfer
events directly from Maxwell's equations (without recourse to the
approximation of space by a mesh of transmission lines). The statement made
by Krumpholz and Russer, that the original derivation is erroneous, is not
valid and the two specific points they raise are considered
[JP05] J. LoVetri and J. B. Ehrman, "Time-domain
electromagnetic plane waves in static and dynamic conducting media. I," IEEE
Transactions on Electromagnetic Compatibility, vol. 36, pp. 221-228, 1994. [Link][PDF]
- Solutions are derived for the time-domain Maxwell equations for static
(J=σE) and dynamic (τ∂/∂t+J= σ0 E) conducting media where the field is
assumed to vary with respect to only one spatial direction, i.e., plane-wave
propagation. The plane wave is introduced into the media via the imposition
of an electric field boundary condition at the plane boundary of a
half-space and it is assumed that the fields inside the half-space are
initially zero. Solutions are derived directly from the first-order system
of partial differential equations and it is shown that once the electric
field at the plane boundary is imposed, the magnetic field is automatically
determined for causal solutions. It is shown that the form of the Maxwell
equations, without a magnetic conductivity term added, is sufficient to
allow well and uniquely defined solutions of this problem.
[JP04] J. LoVetri and N. R. S. Simons, "A class of
symmetrical condensed node TLM methods derived directly from Maxwell's
equations," IEEE Transactions on Microwave Theory and Techniques, vol.
41, pp. 1419-1428, 1993. [Link][PDF]
- A series of general transmission line matrix (TLM)-type methods, which
include the symmetrical condensed node method, are derived directly from
Maxwell's curl equations without recourse to transmission line models.
Written as a system of conservation laws, Maxwell's equations in 3-D plus
time are decomposed along the orthogonal characteristic directions of a
rectangular grid. The Riemann invariants in this method correspond to the
voltage pulses of the TLM method. A new method of handling inhomogeneous
media is proposed based on a new transfer event. The dispersive nature of
these schemes is also investigated.
[JP03] J. LoVetri and G. I. Costache, "Efficient
implementation issues of finite difference time-domain codes for Maxwell's
equations," International Journal of Numerical Modelling: Electronic
Networks, Devices and Fields, vol. 6, pp. 195-206, 1993. [Link][PDF]
- The computer implementation of time-domain finite difference methods for
the solution of Maxwell's equations is considered. As the basis of this
analysis, Maxwell's equations are expressed as a system of hyperbolic
conservation laws. It is shown that, in this form, all the well-known
differencing schemes can be easily expressed, thus increasing the
applicability of the implementation issues to be discussed. Practical
issues, such as computational efficiency and memory requirements, are
discussed for the implementation of the finite difference schemes. Advanced
programming techniques in the C language are used to implement the finite
difference schemes discussed. The example of the penetration of
electromagnetic energy through a shield with a thick gap is used to check
the performance of the methods. It is shown that, for cases where the
disturbance remains localized in the computational mesh, these techniques
result in memory and CPU time savings.
[JP02] J. LoVetri and G. I. Costache, "An electromagnetic
interaction modeling advisor," IEEE Transactions on Electromagnetic
Compatibility, vol. 33, pp. 241-251, 1991. [Link][PDF]
- A knowledge-based approach for the modeling of electromagnetic (EM)
interactions in a system is described. The purpose is to determine any
unwanted EM effects that could jeopardize the safety and operation of the
system. Modeling the interactions in a system requires the examination of
the compounded and propagated effects of the EM fields. A useful EM modeling
approach is one that is incremental and constraint-based. The approach taken
here subdivides the modeling task into two parts: (a) the definition of the
related EM topology and (b) the propagation of the EM constraints. A
prototype of some of the EM constraints has been implemented in Quintus
Prolog under NeWS on a Sun workstation. User interaction is through a
topology drawing tool and a stack-based attribute interface similar to the
HyperCard interface of the Apple Macintosh computer.
[JP01] J. LoVetri and M. Hamid, "Coulomb wave functions in
the theory of the circular paraboloidal waveguide," Canadian Journal of
Physics, vol. 66, pp. 212, 1988. [Link][PDF]
- It is shown how Coulomb wave functions, commonly used in the description
of a Coulomb field surrounding a nucleus, can be used in the description of
electromagnetic fields that are symmetric with respect of phi inside a
paraboloidal waveguide. The Abraham potentials Q and U, which are useful in
describing fields with rational symmetry, are used to simplify the problem.
It is shown that these potentials must satisfy a partial differential
equation that when separated yields the Coulomb wave equation of order L=0.
Electromagnetic fields due to simple source distributions inside the
paraboloid are expanded in terms of these functions. Specifically, solutions
for current-loop sources located in the focal plane of the paraboloid are
obtained. The case where the wall of the paraboloidal waveguide is assumed
to be perfectly conducting is treated as well as the case where the wall has
finite impedance. The finite paraboloid is also considered, and the far
field is formulated using Huygen's principle. It is found that for the
finite surface-impedance case, the far-field pattern due to a current loop
operating at 100 MHz in the focal plane of a paraboloidal reflector of 1 m
focal length is different from the perfectly conducting case. Specifically,
the pattern seems to be more omnidirectional for the impedance case than the
perfectly conducting case. Numerical results are presented for relevant
aspects of the problem.
P. Mojabi and J. LoVetri, "Development of an ultrasound tomography system: Preliminary results,"
5th Joint Meeting of the Acoustical Society of America and the Acoustical Society of Japan,
Honolulu, Hawaii, December 2016.
P. Mojabi, N. Firoozy, N. Bayat, T. Brown, C. Narendra, Pedram Mojabi, C. Niu, T. Tiede, T. Neusitzer, X. Li, I. Jeffrey, J. LoVetri, D. Barber,"Electromagnetic Inversion for Biomedical Imaging, Antenna Characterization, and Sea Ice Remote Sensing Applications,"
URSI Asia-Pacific Radio Science Conference
Seoul, Korea, August 2016.
J. LoVetri, M. Asefi, A. Baran, K. Nemez, " Effects of Data Collection Schemes and Systems on the Imaging Performance of Electromagnetic Inverse Problems,"
the 37th Progress In Electromagnetics Research Symposium (PIERS),
Shanghai, China, August 2016.
D. Kurrant, E. Fear, A. Baran, J. LoVetri, " Evaluating impact of errors in prior information on performance of microwave tomography."
17th International Symposium on Antenna Technology and Applied Electromagnetics (ANTEM),
Montreal, Canada, July 2016.
I. Jeffrey and J. LoVetri, " Discontinuous Galerkin Gauss-Newton Inversion for Electromagnetic Imaging."
17th International Symposium on Antenna Technology and Applied Electromagnetics (ANTEM),
Montreal, Canada, July 2016.
K. Nemez, M. Asefi, A. Baran, and J. LoVetri, " A faceted magnetic field probe resonant chamber for 3D breast MWI: A synthetic study."
17th International Symposium on Antenna Technology and Applied Electromagnetics (ANTEM),
Montreal, Canada, July 2016.
N. Abdollahi, I. Jeffrey and J. LoVetri, " Green’s Theorem Based Eigenfunction Formulations for PEC-Enclosed Electromagnetic Imaging,"
17th International Symposium on Antenna Technology and Applied Electromagnetic,
Montreal, QC, Canada, July 2016.
I. Jeffrey and J. LoVetri, " High-order contrast source inversion of dielectric targets using a Discontinuous Galerkin discretization of the vector wave equation,"
IEEE MTT-S International Conference on Numerical Electromagnetic and Multiphysics Modeling and Optimization for RF, microwave and Terahertz Applications,
Ottawa, Canada, August 2015.
D. Kurrant, A. Baran, E. Fear, and J. LoVetri, " Iterative refinement of fibroglandular region with microwave breast imaging,"
IEEE MTT-S International Conference on Numerical Electromagnetic and Multiphysics Modeling and Optimization for RF, microwave and Terahertz Applications,
Ottawa, Canada, August 2015.
P. Mojabi and J. LoVetri, " Tissue-Type Imaging Using Ultrasound Tomography,"
IEEE MTT-S International Conference on Numerical Electromagnetic and Multiphysics Modeling and Optimization for RF, microwave and Terahertz Applications,
Ottawa, Canada, August 2015.
C. Kaye, I. Jeffrey, and J. LoVetri, " Magnetic contrast-enhanced microwave biomedical imaging using discontinuous Galerkin contrast source inversion,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Vancouver, Canada, July 2015.
A. Baran, D. Kurrant, E. Fear, and J. LoVetri, " Immersion medium independent algorithm for breast microwave imaging,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Vancouver, Canada, July 2015.
D. Kurrant, A. Baran, E. Fear, and J. LoVetri, " Tumor tracking with microwave breast imaging using refined patient specific prior information,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Vancouver, Canada, July 2015.
M. Asefi, A. Baran, and J. LoVetri, " A Water-based 3-D Breast Imaging System: Modelling and Use of Prior Information,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Vancouver, Canada, July 2015.
M. Ostadrahimi, A. Baran, M. Asefi, C. Kaye, K. Nemez, J. LoVetri, and S. Pistorius, " On the Development of a Clinical Full-Vectorial 3D Microwave Breast Imaging System,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Vancouver, Canada, July 2015.
M. Asefi, A. Baran, and J. LoVetri, " A Water-based 3-D Breast Imaging System: Modelling and Use of Prior Information,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Vancouver, Canada, July 2015.
P. Mojabi N. Bayat, M. Ostadrahimi, A. Zakaria, and J. LoVetri, " On the achievable resolution from microwave tomography,"
Radio Science Conference (URSI AT-RASC), 2015 1st URSI Atlantic,
Gran Canaria, Spain, May 2015.
M. Asefi, J. LoVetri, I. Jeffrey, M. Ostadrahimi, A. Zakaria, C. Gilmore, and P. Card, " Stored grain spoilage monitoring via 3D electromagnetic imaging,"
2015 9th European Conference on Antennas and Propagation (EuCAP),
Lisbon, Portugal, April 2015.
J. LoVetri, P. Mojabi, A. Zakaria, M. Ostadrahimi, and I. Jeffrey, " System and Formulation Options for Biomedical Microwave Imaging,"
31st URSI General Assembly and Scientific Symposium,
Beijing, China, August 2014.
I. Jeffrey, A. Zakaria, and J. LoVetri, " Microwave Imaging by Mixed-Order Discontinuous-Galerkin Contrast Source Inversion,"
31st URSI General Assembly and Scientific Symposium,
Beijing, China, August 2014.
P. Mojabi, and J. LoVetri, " Use of Wirtinger Calculus in Gauss-Newton Inversion of Microwave Tomography,"
31st URSI General Assembly and Scientific Symposium,
Beijing, China, August 2014.
M. Ostadrahimi, K. Nemez, J. LoVetri, L. Shafai, and S. Pistorius, "Slotted Waveguide Arrays for Collecting Near-Field Scattering Data,"
16th International Symposium on Antenna Technology and Applied Electromagnetics (ANTEM),
Vancouver, British Columbia, Canada, July 2014.
I. Jeffrey, A. Zakaria, and J. LoVetri, "Discontinuous-Galerkin Microwave Imaging,"
16th International Symposium on Antenna Technology and Applied Electromagnetics (ANTEM),
Vancouver, British Columbia, Canada, July 2014.
N. Bayat, P. Mojabi, and J. LoVetri, "Use of Synthesized Fields in Microwave Tomography Inversion,"
16th International Symposium on Antenna Technology and Applied Electromagnetics (ANTEM),
Vancouver, British Columbia, Canada, July 2014.
I. Jeffrey, A. Zakaria, A. Baran and J. LoVetri, "Simultaneous High-Order Contrast Source Inversion of Dielectric and Magnetic Targets,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Memphis, Tennessee, July 2014.
P. Mojabi and J. LoVetri, "Microwave and Ultrasound Imaging for Biomedical Tissue Identification,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Memphis, Tennessee, July 2014.
A. Zakaria, M. Asefi, M. Ostadrahimi, I. Jeffrey, and J. LoVetri, "Electromagnetic Imaging Inside Metallic Enclosures using Metallic Enclosures using the Normal Boundary Field Components,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Memphis, Tennessee, July 2014.
A. Baran, D. Kurrant, A. Zakaria, E. Fear and J. LoVetri, "Breast Cancer Imaging Using Microwave Tomography with Radar-Derived Prior Information,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Memphis, Tennessee, July 2014.
M. Ostadrahimi, K. Nemez, A. Zakaria, J. LoVetri, L. Shafai and S. Pistorius, "A Novel Microwave Tomography System for Breast Imaging Based on the Modulated Scattering Technique,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Memphis, Tennessee, July 2014.
C. Kaye, J. LoVetri, A. Zakaria and A. Baran, "A Study of Contrast-Enhanced Functional Microwave Imaging,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Memphis, Tennessee, USA, July 2014.
M. Asefi, I. Jeffrey, J. LoVetri, M. Ostadrahimi, A. Zakaria, C. Gilmore, P. Card and J. Paliwal, "Grain Bin Monitoring via Microwave Imaging,"
IEEE International Symposium on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Memphis, Tennessee, July 2014.
I. Jeffrey, and J. LoVetri, "Field and contrast eigenfunction expansions and their application to microwave imaging algorithms,"
IEEE International Symposium
on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Orlando, USA, USA, July 2013.
P. Mojabi, J. LoVetri, "Simultaneous reconstruction of compressibility and density profiles in multiple-frequency acoustic inverse scattering,"
IEEE
International Symposium on Antennas and Propagation and USNC/URSI National Radio
Science Meeting, Orlando, USA, July 2013.
P. Mojabi, J. LoVetri, "A fast and efficient MoM forward solver for ultrasound tomography of inhomogeneous compressibility and density profiles,"
IEEE
International Symposium on Antennas and Propagation and USNC/URSI National Radio
Science Meeting, Orlando, USA, July 2013.
M. OstadRahimi, M. Asefi, J. LoVetri, G. Bridges, and L. Shafai, "An
MST-based microwave tomography system using homodyne receiver," IEEE
International Symposium on Antennas and Propagation and USNC/URSI National Radio
Science Meeting, Orlando, USA, July 2013.
C. Kaye, J. LoVetri, A. Zakaria and A. Baran, "Exploration of Novel
Contrast Agents for Functional Imaging Using Microwave Tomography,"
2013 IEEE International Symposium on Antennas and Propagation and USNC/URSI
National Radio Science Meeting, Orlando, FL, July 2013.
A. Baran, C. Kaye, A. Zakaria and J. LoVetri, "Investigation of
Tumour Detection Using Contrast Agents and FEM-CSI in Biomedical Microwave
Tomography, " 2013 IEEE International Symposium on
Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Orlando, FL, July 2013.
M. Asefi, M. OstadRahimi, J. LoVetri, and L. Shafai, "Analysis of a 3D
microwave imaging system," IEEE International Symposium on Antennas and
Propagation and USNC/URSI National Radio Science Meeting, Orlando, USA, July
2013.
A. Zakaria, I. Jeffrey, M. OstadRahimi, M. Asefi, and J. LoVetri, "A
novel 3D near-field microwave imaging system," IEEE International Symposium
on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Orlando, USA, July 2013.
I. Jeffrey, J. LoVetri, A. Zakaria, M. OstadRahimi, M. Asefi, C.
Gilmore, P. Card, and J. Paliwal, "Grain bin storage monitoring via microwave
imaging," IEEE International Symposium on Antennas and Propagation and
USNC/URSI National Radio Science Meeting, Orlando, USA, July 2013.
I. Jeffrey, and J. LoVetri, "A circuit-driven thin-wire model for the discontinuous galerkin time domain method,"
IEEE International Symposium
on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Chicago, USA, July 2012.
I. Jeffrey, J. LoVetri, and C. Fumeaux, "A comparative study of volumetric vs subcell modelling of thin-wire structures in FVTD,"
IEEE International Symposium
on Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Chicago, USA, July 2012.
A. Zakaria and J. LoVetri, "On the
Implementation of a Three-Dimensional Finite-Element Contrast Source
Inversion Method," 2012 IEEE International Symposium on Antennas and Propagation and
USNC/URSI National Radio Science Meeting, Chicago, Illinois, USA, July,
8-14 2012
M. OstadRahimi, J. LoVetri, and L. Shafai, "Feasibility study of a
dual-polarized near-field imaging system based on the scattering probe
technique," IEEE International Symposium on Antennas and Propagation and
USNC/URSI National Radio Science Meeting, Chicago, USA, July 2012.
M. OstadRahimi, A. Zakaria, P. Mojabi, J. LoVetri, and L. Shafai,
"Evaluation of a microwave tomography system for animal tissue imaging,"
IEEE
International Symposium on Antennas and Propagation and USNC/URSI National Radio
Science Meeting, Chicago, USA, July 2012.
M. OstadRahimi, P. Mojabi, J. LoVetri, L. Shafai, and S. Noghanian,
"Enhancement of near-field probing in a microwave tomography system,"
IEEE
International Symposium on Antennas and Propagation and USNC/URSI National Radio
Science Meeting, Chicago, USA, July 2012.
C. Kaye, J. LoVetri, A. Zakaria, and M. OstadRahimi, "Feasibility study
of microwave tomography for in-vivo characterization of tissue as a
diagnostic technique for human disease," IEEE International Symposium on
Antennas and Propagation and USNC/URSI National Radio Science Meeting,
Chicago, USA, July 2012.
P. Mojabi, M. OstadRahimi, L. Shafai, and J. LoVetri, "Microwave
tomography techniques and algorithms: A review," 15th International Symposium
on Antenna Technology and Applied Electromagnetics (ANTEM), Toulouse,
France, June 2012.
A. Zakaria and J. LoVetri, "Using Prior
Information with FEM-CSI for Biomedical Microwave Imaging," European
Electromagnetics Conference 2012, Toulouse, France, July, 2-6 2012.
A. Zakaria, I. Jeffrey and J. LoVetri, "A
Three-Dimensional Finite-Element Contrast Source Inversion Method for
Microwave Imaging Applications," Advanced Electromagnetics Symposium, Paris,
France, April, 16-19 2012.
I. Jeffrey, A. Zakaria, S. King
and J. LoVetri, "Exact Current Densities for
Arbitrarily Oriented Holland-Simpson Thin-Wire Models in Unstructured
Meshes," Advanced
Electromagnetics Symposium, Paris, France, April, 16-19 2012.
A. Zakaria, C. Gilmore, J. LoVetri and S. Pistorius, "Balanced Multiplicative Regularization for the Contrast Source
Inversion Method," The 28th International Review of Progress
in Applied Computational Electromagnetics Conference, Columbus, Ohio, USA,
April, 10-14, 2012.
A. Zakaria and J. LoVetri,
"Application of Finite-Element Contrast Source Inversion on TM and TE
Experimental Data," 2011 IEEE International Symposium on Antennas and
Propagation and USNC/URSI National Radio Science Meeting, Spokane,
Washington, USA, July, 3-8 2011.
M. OstadRahimi, P. Mojabi, S. Noghanian, J. LoVetri, S. Pistorius, and
L. Shafai, "On the feasibility of a novel microwave tomography system based on
the scattering probe technique," IEEE International Symposium on Antennas and
Propagation and USNC/URSI National Radio Science Meeting, Spokane, USA, July
2011.
P. Mojabi, C. Gilmore, M. OstadRahimi, A. Zakaria, I. Jeffrey, J.
LoVetri, S. Pistorius, and L. Shafai, "Reduction of modeling error in microwave
tomography: A review," IEEE International Symposium on Antennas and
Propagation and USNC/URSI National Radio Science Meeting, Spokane, USA, July
2011.
C. Gilmore, A. Zakaria, P. Mojabi, M. OstadRahimi, S. Pistorius, and J.
LoVetri, "A 2D near-field multi-static wideband microwave scattering repository
for the testing of calibration and inversion algorithms," IEEE International
Symposium on Antennas and Propagation and USNC/URSI National Radio Science
Meeting, Spokane, USA, July 2011.
I. Jeffrey, and J. LoVetri, "An empirical study of the effects of flux reconstruction on the FVFD solution of Maxwell's equations on unstructured grids,"
27th International Review of Progress in Applied Computational Electromagnetics (ACES),
Williamsburg, USA, March 2011.
J. LoVetri, C. Gilmore, P. Mojabi, A. Zakaria, M. OstadRahimi, S.
Noghanian, and S. Pistorius, "Practical considerations in the development of
novel biomedical microwave tomography systems," IEEE International Symposium
on Antennas and Propagation and URSI Radio Science Meeting, Toronto, Canada,
July 2010.
A. Zakaria and J. LoVetri, "A
Study of Adaptive Meshing in FEM-CSI for Microwave Tomography", The 14th
International Symposium on Antennas and Electromagnetics and The American
Electromagnetics Conference (ANTEM-AMEREM 2010), Ottawa, ON, Canada, July,
5-9, 2010.
J. LoVetri, P. Mojabi, A. Zakaria, and C. Gilmore, "Evaluation of Imaging
Algorithms for Prototype UWB Microwave Tomography Systems", The 14th
International Symposium on Antennas and Electromagnetics and The American
Electromagnetics Conference (ANTEM-AMEREM 2010), Ottawa, ON, Canada, July
5-9, 2010.
I. Jeffrey, and J. LoVetri, "FVTD thin-wire models terminated by arbitrary lumped-element circuits,"
26th International Review of Progress in Applied Computational Electromagnetics (ACES)
,
Tampere, Finland, April 2010.
A. Zakaria, C. Gilmore, and J.
LoVetri, "A Finite-Element Contrast Source Inversion Method for Microwave
Tomography", The 26th International Review of Progress in Applied
Computational Electromagnetics Conference, Tampere, Finland, April, 25-29,
2010.
C. Gilmore, P. Mojabi, A. Zakaria, M. OstadRahimi, C. Kaye, S. Noghanian, L.
Shafai, S. Pistorius, and J. LoVetri, "An ultra-wideband microwave tomography
System: preliminary results," IEEE Engineering in Medicine and Biology
Society (EMBS), Minneapolis, USA, September 2009.
P. Mojabi, C. Gilmore, A. Zakaria,
C. Kaye, S. Pistorius and J. LoVetri, "Progress in Experimental Resonant Chamber
Imaging for Biomedical Applications," IEEE International Symposium on
Antennas and Propagation and USNC-URSI National Radio Science Meeting 2009.
Charleston, USA, 1-5 June 2009.
A. Zakaria, C. Kaye, I. Jeffrey, and J. LoVetri, "Experimental Validation of Thin-Wire FVTD
Models," 13th International Symposium on Antenna Technology and Applied
Electromagnetics (ANTEM) and the Canadian Radio Sciences Meeting (URSI/CNC),
2009. Banff, AB, Canada. 15-18 February 2009.
P. Mojabi, C. Gilmore, A. Zakaria, and J. LoVetri,
"Biomedical Microwave Inversion in Conducting Cylinders of
Arbitrary Shapes," 13th International Symposium on Antenna Technology and
Applied Electromagnetics (ANTEM) and the Canadian Radio Sciences Meeting
(URSI/CNC), 2009. Banff, AB, Canada. 15-18 February 2009.
A. M. Mehrabani, D. Firsov, C. Kaye, L. Shafai, and J. LoVetri,
"Design of Low-Profile Wire Antennas over an AMC using FVTD," 29th URSI General Assembly, 2008. Chicago, IL, USA. 7-16 August 2008.
C. Kaye, C. Gilmore, P. Mojabi, D. Firsov, and J. LoVetri, "Development of a
Resonant Chamber Microwave Tomography System," European
Electromagnetics Conference 2008, Lausanne, Switzerland, July, 21-25, 2008.
D. Firsov, C. Kaye, and J. LoVetri, "FVTD Thin-Wire Modelling of a Microwave Tomography System,"
The 24th International Review of Progress
in Applied Computational Electromagnetics Conference, Niagara Falls, Ontario, Canada, March 30 - April 4, 2008.
