A Printed Rampart-Line Antenna with a Dielectric
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Transcript A Printed Rampart-Line Antenna with a Dielectric
Modeling Multiple Printed Antennas
Embedded in Stratified Uniaxial
Anisotropic Dielectrics
Ph.D. Candidate:
Benjamin D. Braaten
Electrical and Computer Engineering
North Dakota State University
February 6th, 2009
Topics
Introduction
The printed antenna.
Properties and applications.
Proposed research
Derivation of the new spectral domain immittance
functions.
Solving the new spectral domain immittance functions.
Numerical results and measurements.
Future work.
Conclusion.
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Introduction
In 1953 Deschamps
formally introduced
the microstrip
antenna [1].
Many uses:
Radar
Cellular comm.
Satellite comm.
Wireless networks
Wireless sensors
Biomedical devices
RFID …
[1] G. A. Deschamps, “Microstrip Microwave Antennas,” 3rd USAF Symposium on Antennas, 1953.
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Introduction
Advantages:
Disadvantages:
Low profile
Many designs have a
narrow bandwidth
Lightweight
Radiate into a half space
Low cost
Able to achieve UWB Poor endfire radiation
(in some cases)
Poor isolation between
the feed an radiating
Dual frequency
elements
capabilities
Possible surface waves
Simple to fabricate
(power loss)
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Introduction
Region between
plates act like the
region between a
transmission line and
a ground plane with
both ends open.
Results in a standing
wave.
Fringing fields are
responsible for
radiation.
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Introduction
Properties of interest include:
Input impedance
Current distribution
Radiation patterns
Bandwidth
Feed techniques
Mutual coupling with other
elements
Conducting patch layout
… etc.
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Introduction
Many different types of layouts
exist:
[2]
[3]
[2] Anthony Lai and Tatsou Itoh, “Composite Right/Left Handed Transmission Line Metamaterials,”
IEEE Magazine, September 2004.
[3] H. Wang, X. B. Huang and D. G. Fang, “A single layer wideband U-slot microstrip patch antenna
array,” IEEE Antennas and Wireless Propagation Letters, vol. 7, 2008, pp. 9-12.
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Proposed Research
Consider:
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Proposed Research
RESEARCH QUESTIONS:
What is the input impedance of a driven element in the
layered anisotropic structure in the presence of
other conducting patches defined on arbitrary
anisotropic layers in the same structure?
and
What is the mutual impedance between a driven
element in the layered anisotropic structure and
other conducting patches defined on arbitrary
anisotropic layers in the same structure?
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Proposed Research
The previous two questions are very significant in
many fields.
Microstrip antenna arrays [4].
Frequency Selective Structures (FSS) [5]
Radio Frequency Identification (RFID) [6]
IC based antennas
Radar …
[4] David M. Pozar and Daniel H. Schaubert, “Microstrip Antennas: The analysis and Design of
Microstrip Antennas and Arrays”, IEEE Press, Piscataway, NJ, 1995.
[5] A.L.P.S. Campos an A.G. d'Assuncao, “Scattering paramters of a frequnecy selective surface
between anisotropic dielectric layers for incidnet co-polarized plane waves,” IEEE Antennas and
Propagation Society International Symposium, 2001, Vol. 4, July 8-13, 2001, p. 382-385.
[6] K. Finkenzeller, RFID Handbook:Fundamentals and Applications in Contactless Smart Cards and
Identification, John Wiley and Sons, West Sussex, England, 2003.
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The new spectral domain immittance
functions
Start with the following Hertz vector potentials:
Electric Hertz
potential
and
Magnetic Hertz
potential
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The new spectral domain immittance
functions
Next, only the y-direction of the Hertz vector
potential is needed.
and
This is because the optical axis is in the ydirection
and
this component satisfies the higher order TE
and TM tangential boundary conditions.
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Numerical results and measurements
The TEM, TM and TE modes
TEM mode
TM and TE modes
[9]
[9] http://www.ibiblio.org/kuphaldt/electricCircuits/AC/02407.png
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The new spectral domain immittance
functions
Now define the following expression for the magnetic
and electric field:
where the Hertzian vector potentials are solutions to
the following wave equations:
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The new spectral domain immittance
functions
and
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The new spectral domain immittance
functions
To simplify evaluating the previous expressions, we
define the following Fourier transform:
This results in the following relations:
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The new spectral domain immittance
functions
This results in the following simplified expressions:
where
and
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The new spectral domain immittance
functions
Similarly for
and
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The new spectral domain immittance
functions
Single layer problem
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The new spectral domain immittance
functions
Single layer problem
Now use these expressions
to enforce the boundary
conditions:
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The new spectral domain immittance
functions
Single layer problem
After extensive factoring and manipulation, the following
spectral domain immittance functions are derived:
and
(typical
expression –
spectral
domain
Green’s
function)
where
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The new spectral domain immittance
functions
Double (d3 = 0) and Triple layer problems
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The new spectral domain immittance
functions
Double and Triple layer problems
After extensive factoring and manipulation, the following
spectral domain immittance functions are derived:
and
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Solving the new expressions
The spectral domain
moment method was
used to solve for the
unknown current.
PWS functions were
used as expansion and
basis functions.
A delta source was
used to drive the
problem.
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Numerical results and measurements
The problem chosen to validate newly derived spectral
domain immittance functions was the printed dipole.
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Numerical results and measurements
The first step was to
validate the numerical
results with experimental
measurements.
Radius a = 0.4 mm
Length L = 60 mm
FR-4: εr = 4.35
Printed strip W = 4a
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Numerical results and measurements
Picture of measured monopole.
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Numerical results and measurements
This resulted in the following measured resonant
frequencies:(Epsilam-10:
and
,
Rogers 5880:
)
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Numerical results and measurements
Single layer results
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Numerical results and measurements
Single layer results
L = 15 mm
W = 0.5 mm
d1 = 1.58 mm
Notice the ycomponent has the
most effect on the
resonant frequency
(TM0 mode).
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Numerical results and measurements
Single layer results The TEM, TM and TE mode reminder
A quick illustration
of the TM0 mode.
TM and TE modes
[9]
[9] http://www.ibiblio.org/kuphaldt/electricCircuits/AC/02407.png
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Numerical results and measurements
Single layer results
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Numerical results and measurements
Single layer results
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Numerical results and measurements
Single layer results
L = 15 mm
W = 0.5 mm
f = 500 MHz
d1 = 1.58 mm
Notice:TM0 has
the most effect
(i.e. y-compontent
of the permittivity
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Numerical results and measurements
Double layer results
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Numerical results and measurements
Double layer results
L = 15 mm
W = 0.5 mm
d1 = 1.58 mm
d2 = 1.58 mm
ε1= 2.55
Notice: εx2 affects
the resonant
frequency the
most.
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Numerical results and measurements
Double layer results
The field lines:
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Numerical results and measurements
Double layer results
L = 15 mm
W =0 .5 mm
d1 = 1.58 mm
ε1= 2.55
region 2: anisotropic
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Numerical results and measurements
Double layer results
L = 15 mm
W = 0.5 mm
f = 500 MHz
d1 = 1.58 mm
d2 = 1.58 mm
ε1= 3.25.
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Numerical results and measurements
Double layer results
(Single layer results)
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Numerical results and measurements
Double layer results
L = 15 mm
W = 0.5 mm
f = 500 MHz
d1 = 1.58 mm
d2 = 1.58 mm
ε1= 3.25.
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Numerical results and measurements
Double layer results
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Numerical results and measurements
Triple layer results
L = 15 mm
W = 0.5 mm
f = 500 MHz
d1 = 1.58 mm
d2 = 1.58 mm
d3 = 1.58 mm
ε1= ε2= 3.25.
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Numerical results and measurements
Triple layer results
(Double layer results)
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Conclusion
New spectral domain immittance functions
have been derived.
The new spectral domain immittance
functions have been validated with
measurements, published literature and
commercial software.
One, two and three layer problems have
been investigated.
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Conclusion
The following has been shown:
The permittivity in the direction of the optical axis
below the printed dipole has the most impact on
the resonant frequency.
The layer thickness values eventually have little
effect on the resonant frequency.
The permittivity in the direction of the optical axis
above printed dipoles has little or no effect on the
mutual coupling.
The permittivity in the direction orthogonal to the
optical axis in the layers above the dipoles can be
used to control the mutual coupling.
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Conclusion
Future work
Investigate coupling between rectangular
microstrip antennas in layered anisotropic diel.
Investigate coupling between UWB antennas in
layered anisotropic diel.
Investigate how anisotropic materials could be
used to control coupling between RFID tags
IC based antennas
Metamaterial based designs
Mathematical aspects
poles
surface wave modes
convergence
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Questions
Thank you for listening
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