FractalComs Exploring the limits of Fractal Electrodynamics for the future telecommunication technologies INFORMATION SOCIETY TECHNOLOGIES (IST) PROGRAMME Quality Factor and Radiation Efficiency Measurement of Genetically Designed Planar Monopoles WP4 Fractal devices development Task 4.3: Prototype construction and measurement J.M. González and J. Romeu May 2003
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FractalComs Exploring the limits of Fractal Electrodynamics for the future telecommunication technologies INFORMATION SOCIETY TECHNOLOGIES (IST) PROGRAMME.
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FractalComsExploring the limits of Fractal Electrodynamics for the future telecommunication
technologiesINFORMATION SOCIETY TECHNOLOGIES (IST) PROGRAMME
Quality Factor and Radiation Efficiency Measurement of Genetically Designed Planar Monopoles
WP4 Fractal devices development
Task 4.3: Prototype construction and measurement
J.M. González and J. Romeu
May 2003
2FRACTALCOMS T0+18 22-23 / 05 / 2003
University of Granada applied GA for the design of Koch-like small antennas, developing a Pareto tool to optimize several characteristics of pre-fractal wire antennas simultaneously.
The code was also used to generate Euclidean structures to investigate wether fractal shapes might be the best alternative for the design of efficient antennas with minimum resonant frequency.
NEC was used to carry out the simulations. The space to be filled by the antennas was a rectangle of
dimensions h x w.
University of Granada Request (1)
3FRACTALCOMS T0+18 22-23 / 05 / 2003
Pre-fractal Meander Line ZigzagResonant Freq.
Matching Freq.
Matching
Quality Factor
Efficiency
University of Granada Request (2)
868 MHz
878 MHz
-7.6 dB
13.6
96.7 %
827 MHz
836 MHz
-8.3 dB
12.8
97.1 %
825 MHz
836 MHz
-7.3 dB
14.1
96.7 %
h=6.22 cm
w=1.73 cm
a=6.45 cm a=6.24 cm
Copper wire = 0.2 mm
4FRACTALCOMS T0+18 22-23 / 05 / 2003
Standard electronics printed circuits board photo-etching technology was used to manufacture the monopoles.
FR4 fiberglass substrate: thickness 0.25 mm. Copper strips: 0.29 mm width and 0.25 m thick to have the same electrical section than the wire models.
Monopoles were mounted on a 80 x 80 cm ground plane. Connection to the RF source through an SMA connector.
Fabricated Monopoles (1)
5FRACTALCOMS T0+18 22-23 / 05 / 2003
Meander Line Zigzag /4Pre-fractal
Fabricated Monopoles (2)
6FRACTALCOMS T0+18 22-23 / 05 / 2003
and Q measured using the Wheeler cap method. The input impedance of the AUT is measured at the resonant
frequency of the antenna with and without a cap. The cap is a metallic surface that completely encloses the AUT.
Measurement Procedure (1)
/2
Zin=Rr+R+jXin Zcap=R+jXcap@ at resonance f0:
@ RLC model:
in
capin
r
r
Z
ZZ
RR
R
Re
ReRe
inin
r
X
d
dX
RQ
2
7FRACTALCOMS T0+18 22-23 / 05 / 2003
To accurately model the input impedance of the antenna as an RLC circuit (series or parallel) a rotation on the measured data is applied to the Smith chart plot.
Measurement Procedure (2)
Matching Freq.= Resonant Freq.
Matching Freq.
Free-space input impedance
Resonant Freq.
Rot
atio
n A
ngle
Wheeler cap input impedance
Rotated free-spaceinput impedance
Rotated Wheeler cap input impedance
8FRACTALCOMS T0+18 22-23 / 05 / 2003
The cap used to carry out the measurements was an aluminium cylinder (height: 12.5 cm; diameter: 6 cm).
Measurement Procedure (3)
-12
-10
-8
-6
-4
-2
0
2
1 2 3 4 5 60.1
Re
turn
Lo
ss
es
(d
B)
f (GHz)
TM 0
1,1
TM 0
1,5
TM 0
1,9
TE 1
1,i
TE 2
1,i
radi
anle
ngth
lim
it
Modes inside a cylindrical cap excited by a /4 monopole resonant at 694 MHz and skewed 10º.
The expected behavior of GA designs was assessed by comparison with a /4 monopole.
Differences between simulated and measured designs: wires / strips ( same electrical section) no connector / SMA connector soldering losses conductivity of copper additional losses
Not corrected effects: contact between cap and ground plane sistematical errors: do not influence measured but Q