International Journal of Engineering & Technology IJET-IJENS Vol:12 No:5 91 Development of Cavity Backed U-Shaped Cross Dipole Antenna with Reconfigurable Characteristics Abstract The need for directional antennas possessing high gain, wideband and circular polarization characteristics for different wireless applications has increased considerably. In this research paper, a slotted coaxial line fed cavity backed U-shaped cross dipole antenna is developed to achieve wide bandwidth and reconfigurable circular polarization. The cross dipole consists of two orthogonal U-shaped dipoles. These dipoles are mounted on the outer conductor of the coaxial line. The feeding and tuning screws are used for impedance matching and increasing impedance bandwidth. A novel technique is developed to generate reconfigurable circular polarization using cross dipole configuration. The sub-reflector is supported by the feed line, thus requiring no extra support. The antenna is developed on elliptical ground plane with dielectric rim making fabrication of antenna easy. It is demonstrated that antenna achieves voltage standing wave ratio (VSWR) bandwidth of 32.14% for 2:1 VSWR, axial ratio of.2 db with axial ratio ( 3dB) bandwidth of 2.14% and a gain of more than12 dbic. The experimental results for the designed antenna structure are in close agreement with computer simulations. Index Term-- U-shaped dipole, Wideband antenna, Circularly polarized antenna. I. INTRODUCTION The demand for directional antennas with high gain and wideband radiation characteristics for different wireless applications has increased in recent years [1-3]. WiMax (world interoperability for microwave access) used for point to multipoint communication has become hot area [4-5]. The subscriber directional antennas communicate with the base stations connected to internet in WiMax wireless systems. The back fire antenna is very attractive because of its high gain, low side lobe level, and compact configuration. This antenna is widely used in tracking, telemetry, mobile communication, maritime satellite communication, and other wireless applications [ 1]. Circularly polarized antenna is employed to avoid power loss caused by Faraday polarization rotation in satellite communications. Circular polarization can be achieved by using cross aperture technique commonly used in microstrip antennas. The cross aperture topology consists of two rectangular slots orthogonal to each other [11 14]. The circular polarization is achieved by making the rectangular slots of slightly different lengths. The radiations from the slots are 9º out of phase with each other due to difference in lengths of the slots. Therefore the fields radiated from these slots produce circular polarization at broadside in the far field zone. The microstrip line or single probe is generally used to M. J. Asad M. J. Asad, email: mjavid_pk1@yahoo.com 12825-4747-IJET-IJENS October 212 IJENS feed the cross aperture [11 1]. The structure located approximately quarter wavelength above the primary reflector is used to excite the antenna. Impedance matching becomes difficult if the antenna is excited using single probe feed because parasitic inductance of quarter wavelength probe contributes significantly to the inductive component of the input impedance [17]. The cross dipole consisting of two orthogonal dipoles is another excitation structure. This excitation structure usually requires external polarizer like 9º hybrid coupler to produce circular polarization [18]. Moreover the frequency bandwidth for input impedance of such an antenna is also narrow e.g. natural impedance bandwidth is 3-5% for 1.5:1 VSWR [19]. The slots on center-fed slotted patch antenna can be used to increase impedance band width considerably [2 21]. Several attempts have been made to increase impedance band width by using different techniques [22 25]. In this paper, the design and development of high gain broad band circularly polarized cavity backed U-shaped cross dipole antenna is reported. The antenna is excited by cross dipole. Slotted feed line is used to feed the cross dipole giving good impedance matching. Circular polarization is achieved using cross dipole without employing external polarizer such as 9º hybrid coupler. The new technique is developed to make circular polarization reconfigurable. The antenna is developed with dielectric rim on elliptical ground plane instead of circular ground plane. Therefore the antenna has different radiation patterns in two planes, Φ = and Φ = 9. The antenna can find applications in telemetry, WiMax and as feed in cut parabolic reflectors. II. ANTENA STRUCTURE AND DESIGN Fig. 1 shows the configuration of the design. The antenna is designed in S-band using FEM (Finite Element Method) based full-wave electromagnetic software HFSS. It is excited by U- shaped cross dipole, consisting of a primary elliptic reflector with major axis Dar and minor axis D br, a circular subreflector of diameter D sr placed at height H sr. The simulations were carried out to optimize all these parameters, using the following general design guidelines: 1. Choose the diameters of major axis of primary reflector (D ar ), the subreflector (D sr ) and height of subreflector (H sr ) initially to be equal to D ar = 2. λ o, D sr =.4 λ o and H sr =.5 λ o ; where λ o is free space wavelength at the design frequency of 2.8 GHz.
International Journal of Engineering & Technology IJET-IJENS Vol:12 No:5 92 2. Set the height of cross dipole (H d ) and location of the feeding screw to.25 λ o. 3. Design slotted coaxial line and the two orthogonal U- shaped dipoles having same length equal to.5 λ o. 4. Increase the length of one dipole and reduce the length of other to achieve circular polarization. 5. Adjust the position of tuning screw for impedance matching and broad bandwidth.. The overall size of short backfire antenna is optimized for good impedance matching and radiation performance. Based upon the above guidelines, the overall height of the antenna equals to be.77λ o and it is 1.997λ o in width, which is also the major diameter of the elliptical primary reflector. The minor diameter of the primary reflector is 1.479λ o. The length of bigger arm of cross dipole is.551λ o while the length of smaller arm is.453λ o. To achieve the Circular polarization, a pair of orthogonal dipoles is used. Each arm of the dipoles is divided into two lengths, larger and smaller. The larger lengths of all dipoles are kept same and equal to 12.19mm with diameter of 3mm. The smaller lengths of the dipoles have 2mm diameter. The smaller lengths are embedded inside the larger lengths of the dipoles. Initially the length of two dipoles is same i.e. λ o /2. Then one dipole is made shorter and the other dipole is made longer. Circularly polarized wave is produced when the length of one dipole is λ o /2 +.51λ o and the length of other dipole is λ o /2.44λ o. This cross dipole is fed by slotted coaxial line. The dipoles are mounted on the outer conductor of the slotted coaxial line. A slot is milled in the outer conductor of the line in a plane normal to the dipole axis. The length, SL and the width, SW of the slot are.53λ o and.187λ o respectively. The inner conductor of the line is short-circuited to the outer conductor by feeding screw. The cross dipole is located at a height of.2518λ o from primary reflector. The sub-reflector is supported by the feed line and hence requires no extra support for it. It is located at a height of.53λ o from primary reflector. The diameter of the sub-reflector is.455λ o. Generally Backfire antenna uses metallic rim to improve side lobe level. But the fabrication of the metallic rim is difficult as it is usually welded with primary reflector. Further, a separate radome is used, which is assembled with the rim, making its fabrication more complex. This difficulty is overcome by developing the proposed antenna with dielectric rim which is integral part of the radome of antenna. The dimension of primary reflector along y-axis is greater than that along x-axis. Hence the radiations reflected from primary reflector in two planes, xz and yz, of different sizes cause different beam widths in the two planes. The different beam widths in two planes make the antenna useful for applications like cut parabolic reflectors. Table1 lists the geometric parameters of the designed and developed antenna. (a) (b) 12825-4747-IJET-IJENS October 212 IJENS
International Journal of Engineering & Technology IJET-IJENS Vol:12 No:5 93 TABLE I Optimized geometric parameters of the antenna D ar Major diameter of the elliptical primary reflector D br Minor diameter of the elliptical primary reflector 214 mm (1.997λ ) 15 mm (1.479λ ) H r Height of SBA 72.53mm (.7λ ) D sr H d H sr Diameter of the circular sub-reflector Height of cross dipole from primary reflector Height of the sub-reflector from primary reflector 48.75mm (.455λ ) 2.98mm (.2518λ ) 53.9mm (.53λ ) (c) Fig. 1 Cavity backed U-shaped cross dipole (a) 3-D view (b) Side view (c) Top view III. RESULTS The simulated and measured results for return loss, S 11 of cavity backed U-shaped cross dipole antenna, shown in Fig. 2, are in close agreement. The impedance band width for S 11 1dB is found to be 32.14% which is much better than the conventional antenna [19]. The axial ratio at broadside and the gain are plotted in Fig.3. It is seen that axial ratio is.2 db with bandwidth for AR 3 db of about 2.14% and the gain is 12.35 db. The simulated and measured radiation patterns at 2.8 GHz are shown in Fig. 4. The half power beam widths are 52º and 7º in Φ = º and Φ = 9º planes respectively. First side lobe level is less than 27 db. LLy LLx Length of bigger part of dipole arm in y-direction Length of bigger part of dipole arm in x-direction 12.19mm (.1138λ ) 12.19mm (.1138λ ) SL Length of the slot 53.9mm (.53λ ) Lx SLy SLx DL Ds Df1 Df2 Ly Length of bigger arm of cross dipole Length of smaller part of dipole arm in y-direction Length of smaller part of dipole arm in x-direction Diameter of bigger part of dipole arm Diameter of smaller part of dipole arm Diameter of inner conductor of feeding line Diameter of outer conductor of feeding line Length of smaller arm of cross dipole 54.12mm (.551λ ) 7.11mm (.4λ ) 9.87mm (.921λ ) 3.mm (.28λ ) 2.mm (.187λ ) 4.mm (.373λ ) 1.mm (.933λ ) 48.mm (.453λ ) S w Width of the slot 2mm (.187λ o ) 12825-4747-IJET-IJENS October 212 IJENS
Gain (db) Relative power (db) Axial ratio (db) Return loss (db) Relative power (db) International Journal of Engineering & Technology IJET-IJENS Vol:12 No:5 94-5 Measured Simulated -1-1 -15-2 -2-3 -25 2.5 2.7 2.9 3.1 3.3 3.5 Fig. 2. Simulated and measured results for return loss of the antenna. 8 4 2 14 13 12 11 1 Measured axial ratio Simulated axial ratio 2.7 2.75 2.8 2.85 2.9 Frequncy (GHz) (a) Measured gain Simulated gain 2.74 2.7 2.78 2.8 2.82 2.84 2.8 2.88 (b) Fig. 3. Simulated and measured results of the antenna (a) Axial ratio (b) Gain -4-5 Measured RHCP, o Simulated RHCP, o Measured LHCP, o Simulated LHCP, o - -18-15-12-9 - -3 3 9 12 15 18-1 -2-3 -4-5 - (a) (degree) Measured RHCP, o Simulated RHCP, o Measured LHCP, o Simulated LHCP, o -18-15 -12-9 - -3 3 9 12 15 18 (degree) (b) Fig. 4. Simulated and measured radiation patterns of the antenna (a) Φ = (b) Φ = 9 The change in the position of the tuning screw affects VSWR and impedance band width. When the tuning screw is placed at height of 57.7mm from primary reflector, the impedance band width is 75MHz. It is reduced to 55MHz when the 12825-4747-IJET-IJENS October 212 IJENS
Axial ratio (db) Measured VSWR Axial ratio (db) International Journal of Engineering & Technology IJET-IJENS Vol:12 No:5 95 height of the tuning screw is 2.7mm. The band width is divided into two bands, one at 2.7 GHz and other at 3.3 GHz, when tuning screw is placed at 7.7mm from primary reflector as shown in Fig. 5. Hence the tuning screw can be used to control VSWR and impedance band width of the antenna. The axial ratio and circular polarization band width can be changed by changing the lengths of pair of dipoles. Axial ratio bandwidth is changed by moving smaller lengths, SLx or SLy, outwardly. For example, axial ratio band width is changed from MHz to 9 MHz by changing smaller lengths of large dipole from 8.725 mm to 9.725 mm as shown in Fig.. The frequency of best axial ratio is changed if the smaller lengths of the dipoles are moved outwardly by greater amount as shown in Fig.7. Hence axial ratio band width as well as frequency of best axial ratio can be controlled by dividing arms of the dipoles into two lengths, longer and smaller, embedding smaller lengths into the longer lengths and changing the smaller lengths giving reconfigurable CP characteristic to the antenna. 7 5 4 3 2 Tuning screw position 57.7mm 2.7mm 8.7mm 1 2.4 2. 2.8 3 3.2 3.4 3. 3.8 4 Fig. 5. Effect of tuning screw on VSWR and impedance band width 15 12 9 3 SLx = 7.725 mm SLx = 8.725 mm SLx = 9.725 mm 2. 2.5 2.7 2.75 2.8 2.85 2.9 2.95 3 Fig.. Simulated results showing effect of lengths of cross dipole on axial ratio bandwidth 12 1 8 4 2 Lx = 54.12mm, Ly = 48.mm Lx = 5.33mm, Ly = 5.59mm 2.5 2.7 2.9 2.71 2.73 2.75 2.77 2.79 2.81 2.83 Fig. 7. Measured results showing effect of lengths of cross dipole on axial ratio CONCLUSIONS IV. A U-shaped cross dipole antenna backed by cavity has been designed and developed to achieve wide impedance bandwidth and reconfigurable circular polarization. The U- shaped cross dipole is fed by slotted coaxial line. Impedance matching and bandwidth improvement is achieved by employing feeding and tuning screws. Circular polarization is achieved using cross dipole without employing external polarizer. The frequency of axial ratio and its band width can be controlled by changing smaller lengths of dipoles. The proposed antenna achieves voltage standing wave ratio (VSWR) bandwidth of 32.14% for 2:1 VSWR, axial ratio of.2 db with axial ratio ( 3dB) bandwidth of 2.14% and a gain of more than 12 dbic. The work on the developed antenna as element in antenna arrays can be carried out in future. REFERENCES [1] Driessen, P. F., Gigabit/s indoor wireless systems with directional antennas, IEEE Trans. Commun., Vol. 44, No. 8, pp. 134 144, 199. [2] Waterhouse, R. B., Novak, D., Nirmalathas, A., and Lim, C., Broadband printed sectored coverage antennas for millimeterwave wireless applications, IEEE Trans. Antennas Propag., Vol. 5, No. 1, pp. 12 1, 22. [3] Yang, S., Tan, S. H., and Fu, J. S., Short backfire antennas for wireless LAN applications at millimeter-waves, Proc. IEEE AP-S Int. Symp., pp. 12 123, 2. [4] Vaughan-Nichols, S. J., Achieving wireless broadband with MiMax, Computer, pp. 1 13, 24. [5] Cherry, S. M., WiMax and Wi-Fi: Separated and unequal, IEEE Spectrum, pp. 19, 23. [] Kory, C. K., Lambert, Acosta, R., and Nessel, J., Prototype Antenna Elements for the Next-Generation TDRS Enhanced Multiple-Access Array, IEEE Trans. Antennas Propag., Vol. 5, No. 4, pp. 72 83, 28. [7] Kory, C. K., Lambert, Acosta, R., and Nessel, J., Prototype antenna elements for the next-generation TDRS enhanced multiple- access array, Proc. IEEE Antennas and Propagation Society International Symposium, pp. 297 3, 2. [8] Ehrenspeck, H. W., The short-backfire antenna, Proc. IEEE, Vol. 53, No., pp. 1138 114, 195. [9] Kumar, A., and Hristov, H. D., Microwave Cavity Antennas, Artech House Norwood MA, pp. 215 38, 1989. 12825-4747-IJET-IJENS October 212 IJENS
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