IPASJ International Journal of Electronics & Communication (IIJEC) Web Site: http://www.ipasj.org/IIJEC/IIJEC.htm Email: editoriijec@ipasj.org ISSN 2321-5984 A Publisher for Research Motivation........ Volume 3, Issue 3, March 2015 Design of Compact Antenna with modified ground plane for ultra wide band communication Suchita Borkar1, Minal A. Mishra2 1 2 Laxmi Institute of Technology, Sarigam Vadodara Institute of Technology, Kotambi ABSTRACT In this paper, T shaped antenna for ultra wide band communication is designed. Both the antennas have modified ground planes. The designed antenna is T-shaped antenna. The results of antenna have shown VSWR of 1.2 for the return loss of -40 dB at the operating frequency of 7.5 GHz. HFSS-11 software is used for the simulation of the antennas. Keywords: UWB, compact antenna, modified ground plane, T-shaped antenna. 1. INTRODUCTION In February, 2002, the FCC(federal communication commission) permitted UWB operation and UWB devices FCC’s spectrum allocation for UWB is from 3.1 GHz to 10.6 GHz. UWB has the high data rate transmission nearly of 500 Mbps. UWB is employed for Short range applications. Its distance range is 10 meters. The power spectral density of UWB are very low -41.3 dBm/MHz[1]. The antennas are divided into two groups. They are directional and omnidirectional antennas. The Directional antennas are narrow band antennas since Their beam is focused wich requires very high gain. Whereas the omni- directional antennas are called as wideband antenna as they radiates in all the directions. The UWB antennas have broad band. UWB systems can be implemented with small size, low cost and low power on the single chip architecture. There are many challenges in UWB antenna design. One of the challenge is to achieve wide impedance bandwidth . UWB antennas are typically required to attain a bandwidth, which reaches greater than 100% of the center frequency to ensure a sufficient impedance match is attained throughout the band such that a power loss less than 10% due to reflections occurs at the antenna terminals. Aside from attaining a sufficient impedance bandwidth, linear phase is also required for optimal wave reception, which corresponds to near constant group delay. This minimizes pulse distortion during transmission. Also, high radiation efficiency is required especially for UWB applications. Since the transmit power is so low (below the noise floor), power loss due to dielectrics and conductor losses must be minimized. Typically, antennas sold commercially achieve efficiencies of 50-60% due to lossy dielectrics. The physical constraints require compatibility with portable electronic devices and integrated circuits. The VSWR of the designed antenna should be less than 2 and the return loss should be less than -10 dB within operating bandwidth 2. DESIGN PROCEDURE STEP 1: CALCULATION OF THE WIDTH (W ): THE WIDTH OF THE MICROSTRIP PATCH ANTENNA IS GIVEN BY EQUATION AS: Step 2: Calculation of Effective dielectric constant (εreff ): Equation gives the effective dielectric constant as: Volume 3, Issue 3, March 2015 Page 13 IPASJ International Journal of Electronics & Communication (IIJEC) Web Site: http://www.ipasj.org/IIJEC/IIJEC.htm Email: editoriijec@ipasj.org ISSN 2321-5984 A Publisher for Research Motivation........ Volume 3, Issue 3, March 2015 Step 3: Calculation of the Effective length (L eff ): Equation gives the effective length as: Step 4: Calculation of the length extension (ΔL ): Equation gives the length extension as: Step 5: Calculation of actual length of patch ( L ): The actual length is obtained by re-writing equation as: 3. ANTENNA CONFIGURATION AND DESIGN The geometry, parameters, top and side views for a prototype of the proposed planar T- shaped antenna are shown in Figure 1. The antenna consists of modified grpound structure.T-shaped antenna is printed on the top side of the substrate and two slot s are printed on opposite sides of substrate that is on ground plane. The planar arms parallel to x-y plane; micro strip line is along the y-axis. 50 ohm microstrip line is used for design of the proposed antenna. (a) (b) (c) Figure 1 Geometry of compact antenna with modified ground plane for UWB communication (a) Top View (b) Bottom View (C) Design geometry Top view and front view of T- shaped patch antenna are indicated in figure2. The proposed antenna was designed on a Rogers RT/duroid 5880TM substrate with dielectric constant εr = 2.2 and height of the substrate is h =0.894 mm. The substrate has length L= 32mm and width W=28.1mm.The substrate is mounted on ground of 32 mm length and 28.1 mm width. The antenna diamensions are W= 12.45mm, Ls= 2.5mm, Ws= 1mm, L= 7.5mm, Groundcut1=28.1X5mm2 Ground cut 2= 28.1X8mm2 . Volume 3, Issue 3, March 2015 Page 14 IPASJ International Journal of Electronics & Communication (IIJEC) Web Site: http://www.ipasj.org/IIJEC/IIJEC.htm Email: editoriijec@ipasj.org ISSN 2321-5984 A Publisher for Research Motivation........ Volume 3, Issue 3, March 2015 Figure 2 Current distribution of antenna with modified ground plane at 7.5 GHz Figures 3 and 4 denotes the VSWR and S11 respectively of the proposed patch antenna. The results shows the absolute bandwidth of 2.4GHz. The fractional bandwidth of 2.5G/7.5G=33% of the centre frequency is obtained. Figure 3 VSWR of patch antenna with modified ground plane Figure 4 S11 of patch antenna with modified ground plane Radiation Pattern 16 Ansoft Corporation HFSSModel1 0 -30 Curve Info rETotal Setup1 : LastAdaptive Phi='0deg' 30 9.60 rETotal Setup1 : LastAdaptive Phi='10deg' 7.20 -60 60 4.80 rETotal Setup1 : LastAdaptive Phi='20deg' 2.40 -90 90 rETotal Setup1 : LastAdaptive Phi='30deg' rETotal Setup1 : LastAdaptive Phi='40deg' -120 120 -150 rETotal Setup1 : LastAdaptive Phi='50deg' 150 -180 (a) Volume 3, Issue 3, March 2015 Page 15 IPASJ International Journal of Electronics & Communication (IIJEC) Web Site: http://www.ipasj.org/IIJEC/IIJEC.htm Email: editoriijec@ipasj.org ISSN 2321-5984 A Publisher for Research Motivation........ Volume 3, Issue 3, March 2015 Radiation Pattern 19 Ansoft Corporation HFSSModel1 0 -30 Curve Info dB(DirTotal) Setup1 : LastAdaptive Phi='0deg' 30 -2.00 dB(DirTotal) Setup1 : LastAdaptive Phi='10deg' -9.00 -60 60 -16.00 dB(DirTotal) Setup1 : LastAdaptive Phi='20deg' -23.00 -90 90 dB(DirTotal) Setup1 : LastAdaptive Phi='30deg' dB(DirTotal) Setup1 : LastAdaptive Phi='40deg' -120 120 -150 dB(DirTotal) Setup1 : LastAdaptive Phi='50deg' 150 -180 (b) Figure 5 Radiation pattern of antenna with modified ground plane at 7.5GHz 4.CONCLUSION In this paper, the antenna with modified ground plane is simulated using HFSS. The proposed antenna has the advantages of small size, easy fabrication and simple construction. The simulated results of proposed antenna for return loss is less than -10 dB and VSWR of less than 2 can be obtained at the operating frequency of 7.5 GHz. The antenna is suitable for ultra- wideband communication. References [1] Zhi Ning Chen, Xuan Hui Wu, Hui feng li, Ning Yang , and Michael yan Wah Chia,” Considerations for source pulses and antennas in UWB system”,IEEE 2004 [2] C. Balanis, Antenna Theory: Analysis and Design, New York, John Wiley & Sons, Inc., 1997. [3] K. Wong, Compact and Broadband Microstrip Antennas, New York, John Wiley & Sons, Inc., 2002. [4] W. Stutzman, G. Thiele, Antenna Theory and Design, New York, John Wiley & Sons, Inc., 1998. [5] S. Bokhari, J. Zurcher, J. Mosig, F. Gardiol, “A small microstrip patch antenna with a convenient tuning option,” IEEE Transactions on Antennas and Propagation, vol. 44, Issue: 11, Nov. 1996, pp. 1521-1528. [6] S. Dey, R. Mittra, T. Kobayashi, M. Itoh, S. Maeda, “Circular polarized meander patch antenna array,” IEEE Antennas and Propagation Society International Symposium, vol. 2, July 1996, pp. 1100-1103. [7] Sang-Gyu Kim and K. Chang “Ultra wideband exponentially-tapered antipodal Vivaldi antennas” IEEE [8] Antennas and Propagation Society Symposium, vol. 3, pp. 2273 – 2276, June 2004, Monterey, CA. [9] J. J. Lee and S. Livingston, “Wide band bunny-ear radiating element”, IEEE Antennas Propagation Society International Symposium. pp. 1604-1607., July 1993, Ann Arbor, MI. [10] M.C. Greenberg, L.L. Virga, “Characterization and design methodology for the dual exponentially tapered slot antenna” IEEE Antennas and Propagation Society International Symposium, vol.1, pp. 88 - 91, July 1999, Atlanta, GA. [11] M.C. Greenberg, K.L. Virga, C.L. Hammond, “Performance characteristics of the dual exponentially tapered slot antenna (DETSA) for wireless communications applications” IEEE Transactions on Vehicular Technology, vol.52 , no.2 , pp. 305 – 312, March 2003. [12] Yo-Shen Lin, Tzyh-Ghuang Ma, Shyh-Kang Jeng, Chun Hsiung Chen, “Coplanar waveguide-fed dual exponentially tapered slot antennas for ultrawideband applications”, Antennas and Propagation Society Symposium, vol. 3, pp. 2951 – 2954, June 2004, Monterey, CA. [13] K. S. Yngvesson, D. H. Schaubert, T. L. Korzeniowski, E. L. Kollberg,T. Thungren, and J. F. Johansson, “Endfire tapered slot antennas on dielectric substrates,” IEEE Transactions on Antennas and Propagation, vol. AP-33, pp. 1392–1400, December 1985. Volume 3, Issue 3, March 2015 Page 16
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