A Wideband suspended Microstrip Patch Antenna

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6464(Print), ISSN (Online) ENGINEERING Volume & 3, Issue TECHNOLOGY 3, October- December (IJECET) (2012), IAEME

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A Wideband suspended Microstrip Patch Antenna Miss.Madhuri Gaharwal 1, Dr,Archana Sharma 2 1 PG student, EC department, TIT(E),Bhopal 2 Assosiate Professor,EC department, TIT(E),Bhopal ABSTRACT In this paper we propose a circularly polarized (CP) microstrip antenna on a suspended substrate with a coplanar capacitive feed and a slot within the rectangular patch. The antenna has an axial ratio bandwidth (< 3 db) of 10.66%. The proposed antenna exhibits a much higher impedance bandwidth of about 32.12% (S11 < 10 db) and also yields return loss better than 15 db in the useful range of circular polarization. It has been found that this antenna offers higher directivity with good radiation properties required for GPS system and mobile applications. The resulting circular polarization bandwidth (with axial ratio 3 db) has been found to meet that required for this application. The proposed antenna possesses a high gain of 6.0 db overall the GPS (1575 MHz) and mobile (1800/1900 MHz) operation. Keywords: GPS Microstrip Antenna, broadband antenna, suspended antenna, Circular Polarization, Axial Ratio. I.INTRODUCTION Although microstrip antennas in their basic form normally provide linear polarization, circular polarization (CP) operation may be obtained by certain modifications to the basic antenna geometry and/or feed. These modifications include adjusting the dimensions of the basic patch with one or more feeds, trimming the corners of a square patch, feeding the patch at adjacent sides, feeding the patch (rectangular) from its corner along the diagonal, and cutting a slot inside the patch [1]. Several such CP microstrip antennas are available in the literature. For example the antenna reported by [2] yields an axial ratio (AR) bandwidth of 6.3% with straight feed and increases up to 14.1% with an L- probe feed. This is a corner trimmed CP antenna with a U-shaped slot cut on the patch to ensure wide impedance bandwidth. There have been other works focusing on reducing the size of the antenna with a modest bandwidth for circular polarization operation [3]. On the other hand, antennas reported by [4] and [5] offer AR bandwidths of 14% and 23% respectively. However, these consist of stacked (multiple metal/dielectric) configurations and hence are considered difficult to fabricate reliably. On the other hand, the antenna reported by Liu and Kao [6], is a simple probe feed H-shaped microstrip antenna fed along its diagonal to excite the CP operation. But the AR bandwidth reported is only about 1.3%. This group has recently reported a linearly polarized coplanar capacitive fed wideband microstrip antenna which provides input impedance bandwidth (S11 < 10 db) of about 50% [7]. Furthermore, we have suggested the use of fractal shaped boundaries for the radiating patch to get symmetric radiation patterns throughout the frequency band [8].In the present work we investigate circular polarization operation of such a patch antenna with fractal boundaries by introducing a suitably designed slot within. In another effort, fractal geometry with fractal slots has been reported with an axial ratio bandwidth of about 2% [9]. The current approach results in significantly higher AR bandwidth while retaining the simplicity of the feed configuration. II.ANTENNA DESIGN The geometry of the antenna is shown in Figure 1. This is basically a suspended coplanar capacitive fed microstrip antenna. Both antenna patch and the feed strip are etched on the same dielectric substrate, which is placed at a height above the ground plane. The antenna is excited by connecting a coaxial probe to the feed strip by a long pin SMA connector. The antenna was designed to operate with a center frequency of 1.6GHz. Volume 4, Issue 11, November 2015 Page 95

(a) Top view of wideband CP geometries III.SIMULATION AND RESULT DISCUSSION (b) Cross sectional view Fig. 1. Proposed wideband CP antenna geometry. In this study we use an FR4 substrate (dielectric constant=4.4, tan delta = 0.0023 and thickness=1.6mm) placed above the ground plane at a 6mm height. Minimum possible width of the feed strip is 9mm so that a hole can be made to connect the probe pin. Its minimum length is approximately one fifth the side of the patch. Due to fabrication constraints the minimum separation between the patch and the feed strip is 0.5mm. The physical parameters of the antenna geometry with a slot are optimized using HFSS simulations and are listed in Table 1. These geometrical parameters (Table 1) are optimized with HFSS software. Table 1. Dimensions for the antenna geometry shown in. Sr.no Parameters Dimensions (mm) 1. Patch Length(L) 63.0 2. Patch Width(W) 83.0 3. Substrate Length(Ls) 108.0 4. Substrate width (Ws) 132.0 5. Slot length(ls1) 2.5 6. Slot length(ws1) 11.0 7. Air gap(h) 9.0 8 Corner Slot length(cs) 10.0 9. feed strip Length (fl) 12.0 10 feed strip Length (fw) 6.0 11. gap bet feed and patch(g) 0.5 Sr. No. Table 2. Comparisons table of different structure of patch. Shape of MSA Freq Return VSWR BW(M (GHZ) Loss Hz) Axial Ratio Gain 1. RMSA Feed diagonal 1.52-13.14 1.54 30 2.50 2.27 2. RMSA Corner Slits 1.54-15.04 1.43 35 1.37 2.30 3. RMSA Corner Slits and cross slits 1.58-15.57 1.39 65 0.98 2.24 Volume 4, Issue 11, November 2015 Page 96

First, study of different shapes of microstrip patch have been investigated to understand their effects on impedance and AR bandwidths. AR characteristics of the antennas are depicted in Figure 2. It can be noticed from Figure 2 that the axial ratio decreases and bandwidth also increasing with adding cross cut slits. Table 2 Comparisons table of different shapes Fig. 2. Axial ratio of different shape microstrip antenna. The following section deals with the effects of air gap (h). By increasing h, the whole return curve shifts towards higher frequencies. The air gap (h) has a significant effect on the matching to the input impedance. Increasing the height of air gap it helps to improving the bandwidth of suspended microstrip antenna. Figure 3 shows performance of the wideband circularly polarized antenna for different air gap varies from 3mm to 12mm. Fig. 3. Effect of variation in air gap (h) on impedance Bandwidth. Here we have study comparison three different techniques. As compared to conventional and suspended MSA we are getting maximum bandwidth in coplanar suspended microstrip feed antenna. Figure 4 shows performance three different techniques if microstrip antenna. It can be noticed from Fig. 4 that the impedance bandwidth increases for coplanar suspended microstrip feed antenna. Fig. 4. Effect of different techniques on impedance Bandwidth. Volume 4, Issue 11, November 2015 Page 97

The simulated return loss characteristics of the proposed antenna in Fig.5, indicated that the return loss is below 15 db in the CP operating range (1.60GHz 1.91GHz). The corresponding axial ratio characteristics are plotted in Figure 6. It can be shown that axial bandwidth (with axial ratio 3 db) has been found about 250Mhz i.e. 10.66% The radiation patterns are plotted in Fig.7, it can be noted that the gain of proposed antenna are 6 db in the CP range of operation. Table 3. Comparisons table of different techniques of patch. Sr.No Shape of MSA Freq (GHz) Return Loss VSWR BW (MHZ) Axial Ratio Gain 1. RMSA 1.58-15.57 1.39 65 0.98 2.24 2. Suspended RMSA 1.57-15.23 1.42 140 0.31 3.24 3. Coplanar Suspended RMSA 1.60-19.04 1.25 465 1.01 5.93 Fig. 5.Return loss of proposed antenna. The corresponding axial ratio characteristics are plotted in Figure 6 Fig. 6.Axial ratio of proposed antenna. Volume 4, Issue 11, November 2015 Page 98

Fig. 7.Radiation pattern of proposed antenna. IV.CONCLUSION Fig. 8..Gain of proposed antenna. The coplanar suspended microstrip feed antenna was presented for circular polarization. This feed configuration has been shown previously to improve the antenna s impedance bandwidth. The CP geometry was used to get nearly symmetrical radiation patterns. A corner slits was used to excite circular polarization and slot dimensions were optimized to maximize the AR bandwidth. The proposed geometry exhibits the return loss less than 15 db and a gain above 5 db in the CP operating range. By changing the slot orientation, antenna can be made to work in CP mode without changing any of the other parameters of the antenna. With optimum slot dimensions this antenna offers an axial ratio bandwidth of 10.6% (AR< 3 db). It has also been established that the proposed approach can be employed to design antennas with similar performance for the desired operational. REFERENCES [1] Balanis, C. A., Antenna Theory, John Wiley & Sons, Inc., NewYork, 2004. [2] Yang, S. L. S., K. F. Lee, and A. A. Kasha, Design and study of wideband single feed circularly polarized microstrip antennas, PIERS Online, Vol. 80, 45 61, 2008. [3] Chen, W. S., C. K. Wu, and K. L. Wang, Novel compact circularly Polarized square microstrip antenna, IEEE Trans. Antennas Propagat., Vol. 49, No. 3, 340 342, 2001. [4] Esselle, N. K. and A. K. Verma, Optimization of stacked microstrip antenna for circular polarization, IEEE Antennas Wireless Propagat. Lett., Vol. 6, 21 24, 2007. [5] Lien, H. C., Y. C. Lee, and H. C. Tsai, Couple-fed circular polarization bow tie microstrip antenna, PIERS Online, Vol. 3, No. 2, 220 224, 2007. Volume 4, Issue 11, November 2015 Page 99

[6] Liu, W. C. and P. C. Kao, Design of a probe fed Hshaped microstrip antenna for circular polarization, Journal of Electromagnetic Waves and Applications, Vol. 21, No. 6, 857 864, 2007. [7] Kasabegoudar, V. G., D. S. Upadhyay, and K. J. Vinoy, Design studies of ultra wideband microstrip antennas with a small capacitive feed, Int. J. Antennas Propagat., Vol. 2007, No. Q4, 1 8, 2007. [8] Kasabegoudar, V. G. and K. J. Vinoy, A wideband microstrip antenna with symmetric radiation patterns, Microw. Opt. Technol. Lett., Vol. 50, No. 8, 1991 1995, 2008. [9] Rao, P. N. and N. V. S. N. Sarma, A single feed circularly Polarized fractal shaped microstrip antenna with fractal slot, progress In Electromagnetics Research Symposium Proceedings, 95 197, Hangzhou, China, Mar. 24 28, 2008. AUTHORS Miss.Madhuri Gaharwal received her Bachelor of Engineering in Electronics & telecommunication in 2009 from Sant Gadage Baba Amravati University.She is currently pursuing her M.Tech in Electronics & Communication branch from TIT college of Excellence, RGPV University Bhopal Dr. Archana Sharma received her Bachelor of Engineering in Electronics & Communication in 2004 from RGPV,Universit, Bhopal She received her M.tech in Microwave & Millimetre Waves from MANIT, Bhopal, India in 2008. She also received her Ph.D degree from the MANIT, Bhopal, India in 2014. She has many publications in various international journals and conferences.her research field focus on various antenna design and analysis, microstrip antenna s, dielectric resonator antennas, microwave and millimeter wave systems, wireless communication. She is presently working as Associate Professor in Department Electronics & Communication branch, TIT college of Excellence, Bhopal, India. Volume 4, Issue 11, November 2015 Page 100

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