Printed Antenna Design and Simulation for 5G using HFSS

International Journal of Trend in Scientific Research and Development (IJTSRD)
Volume: 3 | Issue: 4 | May-Jun 2019 Available Online: www.ijtsrd.com e-ISSN: 2456 - 6470
@ IJTSRD | Unique Paper ID – IJTSRD24011 | Volume – 3 | Issue – 4 | May-Jun 2019 Page: 961
Printed Antenna Design and Simulation for 5G using HFSS
Mahvish1, Tanika2
1M.Tech Scholar, 2Assistant Professor
1Department of Electronics and Communication Engineering,
1,2Swami Vivekananda Institute of Engineering and Technology, Ramnagar, Banur, Punjab, India
How to cite this paper: Mahvish |
Tanika "Printed Antenna Design and
Simulationfor5GusingHFSS"Published
in International Journal of Trend in
Scientific Research and Development
(ijtsrd), ISSN: 2456-
6470, Volume-3 |
Issue-4, June 2019,
pp.961-965, URL:
https://www.ijtsrd.c
om/papers/ijtsrd24
011.pdf
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ABSTRACT
With expanding number of users, the demand for better technology also
increases. The fifth Generation 5G technology would be one of the best
technologies to meet the need of increased capacity demand, massive
connectivity better speed by using the large amount of spectrum in the
millimeter wave band, with 5G it is expected toget80-100 Mbpsspeed.Theneed
for 5G technology, methodology designing of antenna and varioussimulationsis
offered. The micro strip patch antenna is used here in 5G technologyisrelatively
inexpensive to manufacture and design because of its simple physicalgeometry.
Micro strip Patch Antenna shows multi-band characteristics and has a compact
structure and hence has emerged as a promising candidate forhandheld devices
the proposed idea is implemented by using HFSS software which is used for
antenna designing.
Keywords: 4G, 5G, UHD, IP, GSM
I. Introduction
The early communication systems supported onlyanalogy voiceandnowprovide
wide range of different applications to large number of users. First origination
mobile system supported voice only. Within previous minor years, we have seen
continuous development of mobile telecommunications by the birth of2Gbands,
3G and 4G bands wireless networks respectively. Digital networking procedures
as if modulation techniques, Frequency reuse,Packetswitchingand physicallayer
simulation etc. have appeared in this change. With the
expanding appeal of smart devices, nowadays IP based
networks has grown into an essential Resultant, new
multimedia applications for mobile users. Open Market is
overwhelm with these applications and has opened up new
deals for mobile userand serviceproviders.Theforthcoming
of mobile communications is likely to be very distinct tothat
which we are used to today. While interest for portable
broadband will drastically increase day by day, largely
consumed by UHD video and better screens, we are already
seeing the developing impact of the human capabilities of
technology as the stuff around us become ever more linked.
The approaching 5th generation networkiscertain tooutput
a constant Gbps data speed experience across a wide range
of user scenarios. 5G is more just a new wireless
transmission technology called radio technology. It is a gate
opener to new communication capabilities and used cases,
many of that are still unknown to us. For the bandwidth
aspects, here millimeter wave mobile communications
approach is developed and a micro-strip receiver has
implemented for the 5G cellularnetwork/device. Respecting
the 4G and 5G network bands, its focus is approaching
smooth combination of cellular networks such as GSM and
3G, WLAN and Bluetooth. Micro-strip patch receiver(MPAs)
has beautiful and boundless features due to its low profile,
small size, and lightweight, low cost as well as to the fact
these are very simple to construct, suited to planer and non-
laner surfaces. However, their future use in definite systems
is finite of their almost narrow bandwidth. For generating
the excessive-frequency mm-wave electricsignals,theusage
of traditional electronics turns into less financially
appealing; consequently, there is an excessive concern to at
once generate mm-wave alerts within the optical domain.
For that reason in these paintings, the photonic technology,
variation and circulation of 60 GHz thickness band signals to
be applied in 5G that have been recommended and
established already. Basically, a photonics founded totally
mm-wave is a laser beam together with two or extra
coherent longitudinalmodeswith frequencyspacingsameto
the wanted mm-wave. As the longitudinal method beat with
each dissimilar in the photodiode,thedefiniteelectricalmm-
wave can be achieved.
II. Problem Definition
The fundamental intention of this thesis is to style a micro-
strip patch antenna for milli meter wave mobile
communication at 38GHz frequency by exploitation the
fundamental micro-strip conductor methodology and line
calculation analyze from HFSS computer code. In projected
style excited in its basic mode contains a most radial
asymmetry within the direction perpendicular to the patch
(broadside) and is 8.4316 db. during this style, input
reflection coefficients or the S11 parameter for the antenna
is -42 decibel at resonant frequency a pair of.8 GHz. the
height Gain 8.211 decibel and therefore the most -10dB
information measure of 0.0565GHz are achieved in
simulation of S11 parameter for center frequency a pair of.8
GHz. Another vital parameter of AN antenna is that the
IJTSRD24011

International Journal of Trend in Scientific Research and Development (IJTSRD) @ www.ijtsrd.com eISSN: 2456-6470
information measure it covers. Most of the time solely
resistance or come loss information measure is given.
However, it's vital to comprehend that many different
definitions of information measure exist: radial asymmetry
Bandwidth, polarization information measure and potency
bandwidth. radial asymmetry and potency are usually
combined to achieve information measure
III. Methodology
The methodology involves theuseof theoreticalanalysisand
the system simulation. For the simulation approach, the
event simulator HFSS package tool needs to be used to
investigate the number of parameters. The HFSS software
package is used to design a Micro-strip Patch Antenna and
the parameters investigated are Return Loss, Radiation
Pattern, The Gain, VSWR, Impedance, Directivity etc.
IV. Results
The results obtained after using the HFSS software. The HFSS is an efficient platform for designing micro strip Patch Antenna.
Designed micro strip Patch Antenna using HFSS.
Return Loss Plot
Radiation Pattern

The Gain Plot
VSWR Graph
Impedance Plot
Directivity Graph

Gain vs. Frequency Graph
Results
PARAMETERS VALUES
Return Loss -23 db
Resonance Frequency 6.76GHz
Bandwidth 200 MHz
Highest Radiation Intensity 2.63 db
Directivity 5.87 db
VSWR 1.28 db
Comparison between my base paper and my work
PARAMETERS Reported design at F=2.8 GHz Proposed design at F=6.5 GHz
Return Loss -42dB -23 db
Resonance Frequency 2.76 GHz 6.76GHz
Bandwidth 0.0565 GHz 200 MHz
Highest Radiation Intensity 2.63 db 2.63 db
Directivity 8.48dB 5.87 db
VSWR Not obtained 1.28 db
V. Conclusion:
The paper explains the micro-strip patch antenna
fundamentals and HFSS software. The paper explains in
details the steps needed to develop a complete simulation of
micro-strip patch antenna using the popular HFSS software.
The results are given with parameter values and the
comparison between parameters of bases paper and our
proposed work.
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