PERFORMANCE ANALYSIS OF MICROSTRIP PATCH ANTENNA USING COAXIAL PROBE FEED TECHNIQUE
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This document discusses the design and performance analysis of a microstrip patch antenna with a coaxial probe feed at a resonant frequency of 4.24 GHz. It highlights the advantages, such as low profile and lightweight, and evaluates the effects of reactive loading on the antenna's efficiency and radiation characteristics using HFSS simulation software. Results indicate that the antenna provides a gain of 4.80 dB and a voltage standing wave ratio (VSWR) of 2.06 at the specified frequency.
![International Journal of Technical Research and Applications e-ISSN: 2320-8163,
www.ijtra.com Volume 3, Issue 3 (May-June 2015), PP. 365-367
366 | P a g e
Figure 3: Structure of Microstrip Patch Antenna
The dimension of the designed antenna is given in the Table
1, various parameters are considered while doing the
simulation. For this designing purpose we are using substrate
material as Arlon AD260 the relative permittivity of which is
2.6.
Length(L) Width(W) Height(h) ᵋr
Patch 34mm 20mm 2.4mm 2.6
Substrate 98mm 60mm 2.4mm 2.6
Table 1: The dimension of Rectangular Patch and
Substrate in CM
III. TYPES OF FEED
1. Coaxial Probe Feed-
The coaxial feed or probe feed is a very commonly used to
feed the patch located at the top surface of designed antenna.
The configuration of a coaxial feed is shown in Figure. 4. The
inner conductor of the coaxial connector extends through the
dielectric and is soldered to the radiating patch, while the outer
conductor is connected to the ground plane.
Figure 4: Probe Feed for Microstrip Patch.
2. Aperture Coupled Feed-
In this feeding technique, the radiating patch and the
microstrip feed line are separated by the ground plane and
coupling between the patch and the feed line is made through a
slot or an aperture in the ground plane shown in figure 5. The
coupling aperture is usually centered under the patch, which
leads to lower the cross-polarization due to symmetry of the
configuration. The amount of power coupling from the feed
line to the patch is determined by the shape, size and location
of the aperture.
Figure 5: Aperture couple feed for Microstrip Patch
3. Microstrip Line Feed-
In this type of feed technique, a conducting strip is
connected directly to the edge of the microstrip patch. This
strip is smaller in width as compared to the patch. The major
advantage of this arrangement is that the feed can be etched on
the same substrate to provide a planar structure.
IV. DESIGN RESULTS
The simulation is done in HFSS (High Frequency
Structural Simulator). The simulated result of S11 parameter
(return loss) of single element rectangular microstrip patch
antenna is presented in figure 6. On the basis of different
techniques a Rectangular Probe Feed Patch antenna has been
designed and this prototype is improved by applying diffective
ground surface(DGS) techniques.
The return loss of Rectangular patch antenna is shown in
figure.6, which shows that it is resonating at 4.24GHz
frequency.
3.00 3.50 4.00 4.50 5.00 5.50 6.00
Freq[GHz]
-20.00
-17.50
-15.00
-12.50
-10.00
-7.50
-5.00
-2.50
0.00
dB(S(WavePort1,WavePort1))
HFSSDesign2XYPlot1 ANSOFT
m1
Curve Info
dB(S(WavePort1,WavePort1))
Setup1 : Sweep1
pp='0mm'ppy='-10mm'
Name X Y
m1 4.3000 -18.5473
Figure 6: Simulation of S11 Parameter (Return Loss)
Since a Micro strip patch antenna radiates normal to its
patch surface, the elevation pattern for φ = 0 and φ = 90
degrees would be important. The radiation pattern for
proposed microstrip patch antenna for gain-Total at 0deg and
90deg is presented in figure 7
-23.00
-16.00
-9.00
-2.00
90
60
30
0
-30
-60
-90
-120
-150
-180
150
120
HFSSDesign2Radiation Pattern 1 ANSOFT
Curve Info
dB(GainTotal)
Setup1 : LastAdaptive
Freq='6GHz' Phi='0deg'
dB(GainTotal)
Setup1 : LastAdaptive
Freq='6GHz' Phi='90deg'
Fig 7: Radiation Pattern of Microstrip Patch
Figure 8 shows the antenna gain pattern and the gain of
proposed antenna at 4.24GHz is obtained as 4.80dB.
Fig 8: Gain of Microstrip Patch Antenna](https://image.slidesharecdn.com/ijtra150563-160123094236/85/PERFORMANCE-ANALYSIS-OF-MICROSTRIP-PATCH-ANTENNA-USING-COAXIAL-PROBE-FEED-TECHNIQUE-2-320.jpg)
![International Journal of Technical Research and Applications e-ISSN: 2320-8163,
www.ijtra.com Volume 3, Issue 3 (May-June 2015), PP. 365-367
367 | P a g e
Figure 9 shows the Freq vs dB plot that is VSWR. The VSWR
for proposed antenna is obtained as 2.06dB.
3.00 3.50 4.00 4.50 5.00 5.50 6.00
Freq [GHz]
0.00
5.00
10.00
15.00
20.00
25.00
30.00
35.00
dB(VSWR(WavePort1))
HFSSDesign2XYPlot8 ANSOFT
m1
Curve Info
dB(VSWR(WavePort1))
Setup1 : Sweep1
Name X Y
m1 4.3000 2.3152
Figure 9: VSWR
V. CONCLUSION
The Microstrip patch antenna is designed for a frequency
of 4.24GHz, the patch and ground plane are separated by a
dielectric substrate Arlon AD260 with dielectric constant of
2.6, thickness 2.4mm. The main objective of this work is to
consider the reactive loading effect on the patch and its effect
on the improvement of the antenna characteristics particularly
the radiation characteristics in principle plane (E and H) is
examined. As per theoretical approach reactive loading creates
either capacitive loading or inductive loading. Due to this
effect of the antenna performance may be degraded or
enhanced in terms of efficiency, isolation, gain, impedance
matching etc.
The characteristics of proposed antennas have been
investigated through different parametric studies using HFSS
simulation software.
REFERENCES
[1] W. W. Xu, J. H. Wang, Z. Zhang, and M. E. Chen, “Radiation
and Scattering of Microstrip Patch Antenna with slotted
ground plane” 978-1-4673-1800-6/12/$31.00 ©2012 IEEE
[2] W. W. Xu, J. H. Wang, Z. Zhang, and M. E. Chen, “Radiation
and Scattering Properties of the Dual-Port Fed Differential
Microstrip Antennas,” 2011 4th IEEE International
Symposium on Microwave, Antenna, Propagation and EMC
Technologies for Wireless Communications, PP. 124-127,
Nov. 2011.
[3] X. Q. Zhang, J. H. Wang, Z. R. Li, “Research on the
Transient Scattering Propertied of Dipole Array,” 2006
China-Japan Joint Microwave Conference Proceedings,
2006, Chengdu, pp.107-110
[4] A. S. King, and W. J. Bow, “Scattering from a Finite Array of
Microsteip Patches,” IEEE Trans. Antennas Propag., vol. 40,
no.7, pp. 770-774, July. 1992.
[5] E. H. Newman, D. Rorrai, “Scattering from a Microstip
Patch,” IEEE Trans. Antennas Propag., vol. AP-35, No.3, pp.
245-251, Mar. 1987.
[6] H. B. Zhang, S. X. Gong, and X. L. He, “Fractal Slot for
Microstrip Patch Antenna RCS Reduction,” Journal of
Microwaves., vol. 22, No.6, Dec. 2006.
[7] X. L. He, S. X. Gong, and Q. Z. Liu, “On Meshed Mictostrip
Patch Antennas With Low RCS,” Journal of Microwaves.,
vol. 21, Supplement, Apr. 2005.
[8] W. Q. Li, X. Y. Cao, J. Gao, and X. Yao, “Bionic Antenna
With Low RCS for Microstrip Application,” Modern Radar.,
vol. 33, No. 10, Oct. 2011.
[9] V.Karthikeyan1 and V.J.Vijayalakshmi, Radiation Pattern of
Patch antenna with slits. International Journal on Information
Theory (IJIT), Vol.3, No.1, January 2014 DOI :
10.5121/ijit.2014.3101 1
[10] Balanis, Constantine, “Antenna theory-Analysis and Design”,
John Wiley & Sons Ltd.
[11] A handbook on probe feed patch antenna using HFSS v11.0,
May 2007.](https://image.slidesharecdn.com/ijtra150563-160123094236/85/PERFORMANCE-ANALYSIS-OF-MICROSTRIP-PATCH-ANTENNA-USING-COAXIAL-PROBE-FEED-TECHNIQUE-3-320.jpg)
PERFORMANCE ANALYSIS OF MICROSTRIP PATCH ANTENNA USING COAXIAL PROBE FEED TECHNIQUE
- 1. International Journal of Technical Research and Applications e-ISSN: 2320-8163, www.ijtra.com Volume 3, Issue 3 (May-June 2015), PP. 365-367 365 | P a g e PERFORMANCE ANALYSIS OF MICROSTRIP PATCH ANTENNA USING COAXIAL PROBE FEED TECHNIQUE Mr. Murthi Mahadeva Naik G.1, Dr. Naveen Kumar S.K.2, Bhavya B.P.3 Department of Electronics & Communication Engineering, 1,3 Malnad College of Engineering, Hassan. 2 Mangalore University, Magalore. [email protected], [email protected], [email protected] Abstract— Microstrip patch antennas are the most common form of printed antennas. They became very popular due to their low profile geometry, light weight and low cost. A Rectangular Microstrip Patch Antenna with probe feed and substrate used is Arlon AD260 has the relative permittivity of which is 2.6 is designed and simulated using high frequency structure simulator (HFSS). All the Parameters of this microsrip patch Antenna such as bandwidth, S - parameter, Reflection loss and VSWR has been found and plotted. The main objective of this work is to consider the reactive loading effect on the patch and its effect towards the improvement of the antenna characteristics, particularly the radiation characteristics in principle plane (E and H) is examined. As per theoretical approach reactive loading creates either capacitive loading or inductive loading. Due to this effect the antenna performance may be degraded or enhanced in terms of efficiency, isolation, gain, impedance matching etc. The results of this designed antenna are compared with the existing Micro strip antenna. Index Terms—Micro strip Patch Antenna, Coaxial Probe Feed, HFSS, Return Loss. I. INTRODUCTION A microstrip patch antenna is a low profile antenna that has a number of advantages over other antennas which are lightweight, inexpensive, and easy to integrate with accompanying electronics. Microstrip antennas are one of the most widely used types of antennas in the microwave frequency range, and they are often used in the milli metre- wave application. Microstrip patch antennas consist of a metallic patch of conducting material at the top surface with thickness‘t’ and width ‘L’ and a ground plane to its opposite face are separated by a dielectric substrate of thickness h, with relative permittivity εr as shown in Figure 1. The metallic patch may be of various shapes, among rectangular and circular being the most common. The metallic patch essentially creates a resonant cavity, where the patch is at the top of the cavity, the ground plane is the bottom of the cavity, and the edges of the patch form the sides of the cavity. The edges of the patch act approximately as an open-circuit boundary condition. Hence, the patch acts approximately as a cavity with perfect electric conductor on the top and bottom surfaces, and a perfect “magnetic conductor” on the sides. They can be designed to operate over a large range of frequencies (1- 40 GHz). One advantage of the microstrip patch antenna is that it is has low profile, in the sense that the substrate is fairly thin. The substrate is thin enough, the antenna becomes “conformal, and popular for their low profile geometry, light weight and low cost. The designed microstrip patch antenna can be used in the following applications WLAN, Wireless Sensor Network, Bluetooth, Cordless Telephones and used in most of the ISM band applications, also the designed antenna used in WLAN application. The major disadvantages of the microstrip antenna are that is to be used for narrowband application. Figure 1: Microstrip Patch Antenna front view. Figure 2: Microstrip Patch Antenna Top View. II. ANTENNA GEOMETRY FOR PROBE FEED The detailed design of Microstrip Patch Antenna is shown in Figure 1 and Figure 2. In this design choosing a substrate is as crucial one for its parameters improvements. The selection of dielectric material have many different factors such as dielectric constant, thickness, stiffness as well as loss tangent are considered. Figure 3 shows the Structure of microstrip antenna. The thickness of the dielectric substrate is h = 2.4 mm and the dielectric constant is 2.6. The antenna is fed by a coaxial probe with characteristic impedance of 50 Ω on the midpoint of one edge of the patch. The resonant frequency of the antenna is 4.24 GHz. The incident field is a linearly polarized plane wave with frequency ranging from 1GHz to 7 GHz. The resonant frequency of the patch is determined by the patch length. The length of the patch should be slightly less than half the dielectric wavelength. Figure 3, shows the simple rectangular patch antenna. The length, L= 34mm, and width, W= 20mm, the rectangular microstrip patch antenna designed on one side of the Arlon AD260 with εr =2.6 and height from the ground plane is 2.4mm with a resonating frequency of 4.24GHz. The above dimension antenna is designed and analyzed using a EM simulator software called High Frequency Structural Simulator(HFSS).
- 2. International Journal of Technical Research and Applications e-ISSN: 2320-8163, www.ijtra.com Volume 3, Issue 3 (May-June 2015), PP. 365-367 366 | P a g e Figure 3: Structure of Microstrip Patch Antenna The dimension of the designed antenna is given in the Table 1, various parameters are considered while doing the simulation. For this designing purpose we are using substrate material as Arlon AD260 the relative permittivity of which is 2.6. Length(L) Width(W) Height(h) ᵋr Patch 34mm 20mm 2.4mm 2.6 Substrate 98mm 60mm 2.4mm 2.6 Table 1: The dimension of Rectangular Patch and Substrate in CM III. TYPES OF FEED 1. Coaxial Probe Feed- The coaxial feed or probe feed is a very commonly used to feed the patch located at the top surface of designed antenna. The configuration of a coaxial feed is shown in Figure. 4. The inner conductor of the coaxial connector extends through the dielectric and is soldered to the radiating patch, while the outer conductor is connected to the ground plane. Figure 4: Probe Feed for Microstrip Patch. 2. Aperture Coupled Feed- In this feeding technique, the radiating patch and the microstrip feed line are separated by the ground plane and coupling between the patch and the feed line is made through a slot or an aperture in the ground plane shown in figure 5. The coupling aperture is usually centered under the patch, which leads to lower the cross-polarization due to symmetry of the configuration. The amount of power coupling from the feed line to the patch is determined by the shape, size and location of the aperture. Figure 5: Aperture couple feed for Microstrip Patch 3. Microstrip Line Feed- In this type of feed technique, a conducting strip is connected directly to the edge of the microstrip patch. This strip is smaller in width as compared to the patch. The major advantage of this arrangement is that the feed can be etched on the same substrate to provide a planar structure. IV. DESIGN RESULTS The simulation is done in HFSS (High Frequency Structural Simulator). The simulated result of S11 parameter (return loss) of single element rectangular microstrip patch antenna is presented in figure 6. On the basis of different techniques a Rectangular Probe Feed Patch antenna has been designed and this prototype is improved by applying diffective ground surface(DGS) techniques. The return loss of Rectangular patch antenna is shown in figure.6, which shows that it is resonating at 4.24GHz frequency. 3.00 3.50 4.00 4.50 5.00 5.50 6.00 Freq[GHz] -20.00 -17.50 -15.00 -12.50 -10.00 -7.50 -5.00 -2.50 0.00 dB(S(WavePort1,WavePort1)) HFSSDesign2XYPlot1 ANSOFT m1 Curve Info dB(S(WavePort1,WavePort1)) Setup1 : Sweep1 pp='0mm'ppy='-10mm' Name X Y m1 4.3000 -18.5473 Figure 6: Simulation of S11 Parameter (Return Loss) Since a Micro strip patch antenna radiates normal to its patch surface, the elevation pattern for φ = 0 and φ = 90 degrees would be important. The radiation pattern for proposed microstrip patch antenna for gain-Total at 0deg and 90deg is presented in figure 7 -23.00 -16.00 -9.00 -2.00 90 60 30 0 -30 -60 -90 -120 -150 -180 150 120 HFSSDesign2Radiation Pattern 1 ANSOFT Curve Info dB(GainTotal) Setup1 : LastAdaptive Freq='6GHz' Phi='0deg' dB(GainTotal) Setup1 : LastAdaptive Freq='6GHz' Phi='90deg' Fig 7: Radiation Pattern of Microstrip Patch Figure 8 shows the antenna gain pattern and the gain of proposed antenna at 4.24GHz is obtained as 4.80dB. Fig 8: Gain of Microstrip Patch Antenna
- 3. International Journal of Technical Research and Applications e-ISSN: 2320-8163, www.ijtra.com Volume 3, Issue 3 (May-June 2015), PP. 365-367 367 | P a g e Figure 9 shows the Freq vs dB plot that is VSWR. The VSWR for proposed antenna is obtained as 2.06dB. 3.00 3.50 4.00 4.50 5.00 5.50 6.00 Freq [GHz] 0.00 5.00 10.00 15.00 20.00 25.00 30.00 35.00 dB(VSWR(WavePort1)) HFSSDesign2XYPlot8 ANSOFT m1 Curve Info dB(VSWR(WavePort1)) Setup1 : Sweep1 Name X Y m1 4.3000 2.3152 Figure 9: VSWR V. CONCLUSION The Microstrip patch antenna is designed for a frequency of 4.24GHz, the patch and ground plane are separated by a dielectric substrate Arlon AD260 with dielectric constant of 2.6, thickness 2.4mm. The main objective of this work is to consider the reactive loading effect on the patch and its effect on the improvement of the antenna characteristics particularly the radiation characteristics in principle plane (E and H) is examined. As per theoretical approach reactive loading creates either capacitive loading or inductive loading. Due to this effect of the antenna performance may be degraded or enhanced in terms of efficiency, isolation, gain, impedance matching etc. The characteristics of proposed antennas have been investigated through different parametric studies using HFSS simulation software. REFERENCES [1] W. W. Xu, J. H. Wang, Z. Zhang, and M. E. Chen, “Radiation and Scattering of Microstrip Patch Antenna with slotted ground plane” 978-1-4673-1800-6/12/$31.00 ©2012 IEEE [2] W. W. Xu, J. H. Wang, Z. Zhang, and M. E. Chen, “Radiation and Scattering Properties of the Dual-Port Fed Differential Microstrip Antennas,” 2011 4th IEEE International Symposium on Microwave, Antenna, Propagation and EMC Technologies for Wireless Communications, PP. 124-127, Nov. 2011. [3] X. Q. Zhang, J. H. Wang, Z. R. Li, “Research on the Transient Scattering Propertied of Dipole Array,” 2006 China-Japan Joint Microwave Conference Proceedings, 2006, Chengdu, pp.107-110 [4] A. S. King, and W. J. Bow, “Scattering from a Finite Array of Microsteip Patches,” IEEE Trans. Antennas Propag., vol. 40, no.7, pp. 770-774, July. 1992. [5] E. H. Newman, D. Rorrai, “Scattering from a Microstip Patch,” IEEE Trans. Antennas Propag., vol. AP-35, No.3, pp. 245-251, Mar. 1987. [6] H. B. Zhang, S. X. Gong, and X. L. He, “Fractal Slot for Microstrip Patch Antenna RCS Reduction,” Journal of Microwaves., vol. 22, No.6, Dec. 2006. [7] X. L. He, S. X. Gong, and Q. Z. Liu, “On Meshed Mictostrip Patch Antennas With Low RCS,” Journal of Microwaves., vol. 21, Supplement, Apr. 2005. [8] W. Q. Li, X. Y. Cao, J. Gao, and X. Yao, “Bionic Antenna With Low RCS for Microstrip Application,” Modern Radar., vol. 33, No. 10, Oct. 2011. [9] V.Karthikeyan1 and V.J.Vijayalakshmi, Radiation Pattern of Patch antenna with slits. International Journal on Information Theory (IJIT), Vol.3, No.1, January 2014 DOI : 10.5121/ijit.2014.3101 1 [10] Balanis, Constantine, “Antenna theory-Analysis and Design”, John Wiley & Sons Ltd. [11] A handbook on probe feed patch antenna using HFSS v11.0, May 2007.