Comparative analyses of enhancing bandwidth of micro strip patch antennas a survey and an idea

IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
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Volume: 03 Special Issue: 03 | May-2014 | NCRIET-2014, Available @ http://www.ijret.org 119
COMPARATIVE ANALYSES OF ENHANCING BANDWIDTH OF MICRO
STRIP PATCH ANTENNAS: A SURVEY AND AN IDEA
Anilkumar Patil1
, B.Suryakant2
1
Asst Professor, SIT, Gulbarga
2
Professor, BKIT, Bhalki
Abstract
Microstrip Patch Antenna (MPA) is generally used in modern communication devices, and a large part of day-to-day
communication is done through it. Study of literature of past few year shows that, the leading work on MPA is focused on
designing compact sized broadband microstrip antenna. But inherently MPA have narrow bandwidth so to enhance bandwidth
various techniques are engaged. This review paper demonstrates some commonly engaged techniques to fabricate MPA with
broader-bandwidth since last few decades.
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1. INTRODUCTION
Micro strip Patch Antenna (MPA) is commonly used because
of its low profile, low cost and ease of manufacturing. A patch
antenna is made by etching metal on one side of dielectric
substrate where as on the opposite side there is continuous
metal layer of the substrate which forms a ground plane [ 1].
MPAs a r e inherently a narrow band antennas so; various
bandwidth enhancement techniques are engaged while
keeping its size as compact as possible to be perfectly used as
a low profile antenna.
Due to which many studies and researches are being done
throughout the globe. Practically bandwidth of MPA is narrow
but, today wireless communication systems require higher
operating bandwidth. Such as about 7.6% for a global system
for mobile communication (GSM; 890–960 MHz), 9.5% for a
digital communication system (DCS; 1710–1880 MHz), 7.5%
for a personal communication system (PCS; 1850–1990 M H z
), a n d 1 2 . 2 % f o r a universal mobile telecommunication
system (UMTS; 1920–2170 MHz) [2] To achieve these
required bandwidths many techniques are used and some of
them are given explained further in review this paper.
2. BANDWIDTH-ENANCWMENT TECHNIQUES
USED FOR MICROSTRIP PATCH ANTENNAS
The major need for today’s communication devices is to
operate at broader band such as to support high speed internet,
multimedia communication and similarly many more
broadband services, this is achieved by using microstrip patch
antennas, but inherently microstrip antennas are narrow band
antennas so, various techniques are used to enhance the
bandwidth of microstrip antenna.
In this section bandwidth enhancement or broadband
techniques are explained Modified shape patch, Planar Multi-
resonator configuration, multilayered configuration and
Stacked Multi-resonator microstrip patch antenna are mainly
used for broadband microstrip antenna.
2.1 Modified Shape Patch Broadband Microstrip
Patch Antenna
In this technique bandwidth enhancement is done by
changing/modifying the shape of radiating patch. It is found
that some shapes of patches have lower Q factor as compared
to other therefore having high bandwidth [5]. These patches
shapes include annular ring, rectangular/square ring, shorted
patch and other geometries. There are several designs of
broadband microstrip patch antenna with modified patches. A
design of broadband circular patch microstrip antenna with
Diamond shape slot is given by Garima, et al. [6].
This antenna is applicable for C-band. Substrate used in this
antenna is FR-4 and produces the bandwidth of 13.58% when
compared with conventional circular patch antenna. The
performance of proposed antenna is improved when compared
with that of conventional circular patch antenna having
identical radius. Another design for modified shape patch is T-
slot Broadband Rectangular Patch Antenna [7]. A single layer
single probe fed
2.2 Planar Multiresonator Configuration of
Broadband Microstrip Patch Antenna
In such configuration of microstrip antenna multiple
resonators are placed near to each other, only one is fed and
others are parasitically coupled, it is also known as gap
coupling. Another way used to feed multiresonator
configuration is to directly connect the patches via microstrip

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line. In some cases hybrid coupling is also used which include
gap and direct coupling [10]. Design of Bandwidth
Enhancement of Microstrip Antennas Using Shifted
Parasitically Coupled Planar Multiresonator [11]. In this
method, a wideband planar multi resonator antenna with
parasitic coupling is used. Results show gradual improvement
in impedance bandwidth from 65MHz to 251MHz (about four
times) with very minor variation of resonance frequency from
2.989 GHz for reference patch to 3.023 GHz for anticlockwise
shifted parasitically coupled elements. In multiresonator
broadband microstrip patch antenna [12], gap-coupled
planar T-slot broad band rectangular patch antenna is
proposed. Impedance bandwidth of 25.23% with an average
gain of about 7.43 dBi over the entire passband and peak gain
of 9.88 dBi at -10dB return loss is achieved. Single-layer
single-patch wideband microstrip antenna with U- shaped slot
Embedded on the patch [8]. Enhanced bandwidth is achieved
by the U-shaped slot with a thick air substrate of 12 mm and
the impedance bandwidth of 500 MHz or 27.5% is achieved at
the centre frequency 1815 MHz (at 10 dB return loss). One
more method of achieving broadband microstrip patch antenna
is Modified E-H Shaped patch antenna [9].
A L-probe fed microstrip patch antenna with low cross-
polarization and modified E-H shaped patch design is
proposed to operate at 1.79 to 2.34 GHz frequency range. The
impedance bandwidth achieved is 27% (550 MHz). All these
techniques provide broadband microstrip patch antennas. In
such configurations broader band is achieved without
increasing the surface area of patch antenna multiresonator
and stacked configurations are combined to obtain wide
bandwidth with higher gain with three rectangular patches
stacked on a single fed patch yielded bandwidth of 830 MHz
(25.7%) with more than 10 dB gain. In multiresonator
broadband microstrip antenna with directly coupled and
parasitic patches [13]. The impedance bandwidth of 12.7% i.e.
365 MHz at center frequency 2879 MHz is obtained with 10
dB return loss. When one patch without any coupling (i.e.
direct and parasitic coupling) is analyzed, impedance
bandwidth of 54 MHz (i.e.2%) is obtained at center frequency
at 2710MHz’s When both cases are compared (i.e. 12%Vs
2%) then the impedance bandwidth of about6.35 times is
obtained for proposed antenna.
Use of additional resonators patches either directly or gap
coupled to the radiating patch will lead to abroad band
configuration of microstrip antenna.
Though the size of resulting antenna is bigger but the resulting
bandwidth is much more than that of a single patch microstrip
antenna.
2.3 Multilayered configurations of Broadband
Microstrip Patch Antenna
In multilayered configuration patches are placed over
different dielectric substrates and they are stacked on each
other. Based on the coupling mechanism these configurations
are of two types electromagnetically-coupled or dielectric
constant. Main disadvantage of this multilayered microstrip
configuration is its increased height which is not desirable in
miniature devices and in aperature coupling ground plane
which is having an aperture slot, and is made up of substrate
with high dielectric constant to reduce radiation losses.
Whereas the top patch is made up of thick substrate with lower
aperture-coupled. Electromagnetic coupled microstrip antenna
one or more patches are located on different dielectric layers.
If two- layered configuration of broadband microstrip patch
antenna is analyzed then any one of them may be fed and
other is electromagnetically coupled.
Patch dimensions and dielectric constant of substrate may be
different where as resonant frequency is closer to each other
for obtaining broad bandwidth [14]. In aperture coupling, the
field is coupled from the microstrip feed line placed on the
other side of ground plane to the radiating patch through an
electrically small aperture/slot in the ground plane. Two
different dielectric substrates could be chosen one for the
patch and other for feed line [14]. Very high bandwidth can be
generated by using multilayered configurations. Near about
70% bandwidth can be generated using multilayered
configuration.
Microstrip line feed electromagnetically coupled microstrip
antenna [15] is a method of exciting the patch. This technique
has the advantage that the dielectric constant of substrate used
for microstrip feed line is high and it is thin so that radiation
from feed line should be minimized, whereas the dielectric
constant of substrate used for radiating patch is low and it is
thick which improves the bandwidth of antenna [15]. Aperture
coupled microstrip patch antenna is also an indirect technique
of exciting patch. In this configuration feed line is on lower
side of backward radiation is major problem [14].
2.4 Stacked Multiresonator microstrip patch antenna
In this configuration multiresonator and stacked
configurations are combined to provide broadband microstrip
patch antenna. A design of dual-frequency broadband stacked
microstrip antenna using a reactive loading and a fractal-
shaped radiating edge [16], is used to obtain dual- frequency
operation antenna is loaded with stub for changing frequency
and which broader bandwidth is achieved by using stacked
parasitic technique.
The central frequencies of the first and second operating bands
are 1.524 and 2.159 GHz, bandwidth enhancement factor
achieved is 22.3 in the first band and 18.7 in the second band
and bandwidth achieved is 12% and 5% respectively [16].
Another broadband design using stacked multiresonator
configuration is gap-coupled planar multi-resonator and
stacked configurations [12]; which is used to obtain wide

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bandwidth with higher gain with three rectangular patches
stacked on a single fed patch yielded bandwidth of 830 MHz
(25.7%) with more than 10 dB gain. A proposed broadband
design using stacked U- slot microstrip antenna incorporating
E-shape and modified half-E shape radiating patches [17] are
introduced. Maximum impedance bandwidth achieved is
60.2%. It’s though size of stacked multiresonator microstrip
patch antenna is more but it yields high bandwidth.
2.5 Tables for the Comparative Analyses of Broadband Techniques
S.
No.
Broadband Techniques Configurations Remarks
1. Modified Shape Patch
Diamond shape slot patch[6]
Bandwidth achieved is 13.58% when
compared
with conventional circular patch.
T-slot rectangular patch[7]
Impedance Bandwidth of 25.23% with
average gain of 7.43 dBi is obtained.
U-shaped slot with single-layer
single- patch[8]
Air substrate of 12 mm is used to
yield bandwidth of 27.5%.
E-H shaped patch[9] Yielded bandwidth is about 27%.
2. Multiresonator Technique
Shifted parasitically
coupled
multiresonator[11]
Improves the impedance bandwidth from
65
MHz to 251 MHz (about four times) with
minor variation of resonance frequency
from 2.989
GHz of reference patch to 3.023 GHz.
Gap-coupled multiresonator and
stacked configuration[12]
Yielded bandwidth of 25.7% with more
than 10 dB gain.
Directly coupled and
parasitic patches[13]
Impedance bandwidth of 12.7% (365
MHz) is obtained, which is 6.35 times
when compared with the simple patch i.e.
2% (54 MHz) at same center frequency of
2879 MHz
3. Multilayered Technique Multilayered configuration
of patches[15]
Nearly 70% of bandwidth can be
generated by using multilayered
configuration of radiating patches.
4.
Stacked Multilayered
Technique
Dual-frequency stacked patch
with reactive loading[16]
Bandwidth enhancement factor is 22.3
and 18.7 for 1.524 GHz and 2.159 GHz
resp. which is further 12% and 5% for
their respective bands.
Gap-coupled planar multiresonator
and stacked configuration[12]
Yielded bandwidth of 25.7% with more
than 10 dB gain
Stacked U-slot microstrip
antenna incorporating E-shape
and modified half-E shape
radiating patch
configuration[17]
Maximum impedance bandwidth of
60.2% can be obtained.

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S.no Parameters
Coaxial
probe
feed
Aperture
Coupled
Feed
L-band
Capacitivey
Coupled
Feed
01
Frequency
( GHz) 5.35 2.25 1.25
02 Gain(dB) 6.8 6 8
03
Return
Loss(dB) -14 -14 -42
04
Bandwidth
(MHz) 51 5% 246
2.6 Bandwidth Analysis by Introducing Slots in
Microstrip Antenna Design Using ANN.
In this method slotted MSA is designed on a substrate of
thickness 1.588mm that gives wideband characteristics using
Artificial Neural Network (ANN). The patch antenna gives
enhanced bandwidth as compared to antenna-without slots of
the same physical dimensions. The bandwidth for the antenna is
around 450 MHz The present work signifies that by introduction
of two slots in the same design, the bandwidth gets enhanced
about 25%-45%, i.e., from 450 to 650 MHz
2.7 Enhancing the Bandwidth of a Microstrip Patch
Antenna using Slots Shaped Patch.
In this method, three different geometry shapes, the U, E and H
are developed from a rectangular patch [20] shows that,
bandwidth of conventional rectangular microstrip antenna can be
enhanced from 4.81% (100MHz) to 28.71% (610 MHz), 28.89%
(630MHz) and 9.13% (110MHz) respectively using U, E and H-
patch over the substrate. The E-shaped patch antenna has the
highest bandwidth followed by U-shaped patch antenna and H-
shaped patch antenna.
2.8 Comparative Study of Different Feeding
Techniques to Enhance Bandwidth of Microstrip Patch
Antenna
This paper describes variety of feeding technique applicable to
microstrip patch antenna which is one of the important aspects.
A good impedance matching condition between the line and
patch without any additional matching elements depends heavily
on feeding techniques used. The Coaxial Probe Feed Microstrip
antenna provides a bandwidth of around 20%.The bandwidth has
been enhanced by using different feeding techniques are as
fallows.
3. CONCLUSIONS
After an extensive literature survey, it has been found that
the bandwidth enhancement is an important area of study
and research in microwave communication. Several
techniques which are reported from time to time by many
researches for enhancing the bandwidth of an MPA have
been revised in this paper. Principles used, advantages and
disadvantages of each method have been described out of
all the techniques specified in this paper, multilayered
technique and stacked multilayered techniques provide
maximum bandwidth. The main intension of this study is to
provide a useful reference to the researchers, designers and
manufacturers of MPA.
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