Design of Planar Antenna for Satellite Communication
Transcription
Design of Planar Antenna for Satellite Communication
ISSN(Online): 2320-9801 ISSN (Print): 2320-9798 International Journal of Innovative Research in Computer and Communication Engineering An ISO 3297: 2007 Certified Organization Vol.3, Special Issue 3, April 2015 2nd National Conference On Emerging Trends In Electronics And Communication Engineering (NCETECE’15) Organized by Dept. of ECE, New Prince Shri Bhavani College Of Engineering & Technology, Chennai-600073, India during 6th & 7th April 2015 Design of Planar Antenna for Satellite Communication Application Kardam Kaushal Komalprasad 1, Vivek Ramamoorthy 2, Rajendra Patel 3 P.G. Student, Dept. of E.C. Engineering, MEFGI, Rajkot, Gujarat, India1 Assistant Professor, Dept. of E.C. Engineering, MEFGI, Rajkot, Gujarat, India2 Associate Professor, Dept. of E.C. Engineering, MEFGI, Rajkot, Gujarat, India3 ABSTRACT: The microstrip patch antenna is probably the most simplest and popular planar antenna. From the appearance of the satellite communication we need to improve two key aspects in the communication systems: The quality of the service as well as the costs. One of the ways to achieve these two aspects is the miniaturization of communication components. This research is about design of planar antenna for satellite communication applications using various performance improvement techniques. This project explores the capability of the microstrip antenna at a higher frequency for the satellite communication. KEYWORDS: microstrip patch antenna (MSTPA), Ku- Band I. INTRODUCTION An antenna is one of the most important elements in the RF system for receiving or transmitting signals from and into the air as medium. The microstrip antennas have been object of study for researchers around the world with the purpose to use them in the telecommunications with the objective of reducing size, cost and improving the quality in the communications [1]. The microstrip antennas are designed in such a way that its structure dissipates the power in the particular direction in form of radiation when applied with electrical signal as shown in Fig.1. The important advantages of these planar antennas includes low profile, adaptability to the form of the structure, simple and cheap manufacturing and can work on different frequencies and different polarizations [2]. However, common microstrip antennas are suffering from limitations like narrow bandwidth, limited power capacity and tolerance problems. Fig. 1. Microstrip Patch Antenna [1] The study includes the design of a single layer coaxial feed rectangular microstrip patch antenna operating at 11.7-12.5 GHz and 14.0-14.5 GHz in Ku band. It is expected that the design may reduce the drawback effects of the microstrip antenna like low gain, narrow bandwidth and poor directivity. Copyright @ IJIRCCE www.ijircce.com 54 ISSN(Online): 2320-9801 ISSN (Print): 2320-9798 International Journal of Innovative Research in Computer and Communication Engineering An ISO 3297: 2007 Certified Organization Vol.3, Special Issue 3, April 2015 2nd National Conference On Emerging Trends In Electronics And Communication Engineering (NCETECE’15) Organized by Dept. of ECE, New Prince Shri Bhavani College Of Engineering & Technology, Chennai-600073, India during 6th & 7th April 2015 II. LITERATURE REVIEW With the development of the satellite technologies and its consequent miniaturization it appeared that microstrip antennas giving the possibility of reduced costs, size and maintaining or improving the quality of the satellite and terrestrial links. With its low cost and size it is possible carry out the satellite technology to more people around the world. A single layer coaxial feed rectangular microstrip patch antenna designed by introducing different slits on the patch so that it can resonate at different frequencies in Ku-band [3].The location and dimensions of each slit determine the resonance frequencies and also other antenna parameters [4]. The dual band can be achieved in antenna using different pair of slits on patch [5]. III. DESIGN AND RESULTS After taking account the design requirements such as bandwidth and dielectric constant, the microstrip patch antenna was designed and optimized using HFSS V.13. The design begins with a single layer coaxial feed rectangular microstrip patch antenna resonating around 15 GHz frequency. The radiating patch was implanted on Glass PTFE substrate having 1.6 mm thickness. Design parameter analyses are calculated using fundamental equations from [1]. A. Design 1: Conventional MSTPA Length of patch = 5.6mm, Width of patch = 6mm Fig. 2. Conventional MSTPA B. Fig 3. Return loss at 15.72 GHz Fig. 4. Radiation pattern at 15.72 GHz Design2 : MSTPA having slits on patch On implanting slits on patch of conventional MSTPA, the antenna resonates at 12.84 GHz and 16.32 GHz frequency. Fig. 5. MSTPA with two slits Copyright @ IJIRCCE Fig. 6. Return Loss www.ijircce.com Fig. 7. Radiation Pattern 55 ISSN(Online): 2320-9801 ISSN (Print): 2320-9798 International Journal of Innovative Research in Computer and Communication Engineering An ISO 3297: 2007 Certified Organization Vol.3, Special Issue 3, April 2015 2nd National Conference On Emerging Trends In Electronics And Communication Engineering (NCETECE’15) Organized by Dept. of ECE, New Prince Shri Bhavani College Of Engineering & Technology, Chennai-600073, India during 6th & 7th April 2015 C. Design 3 : MSTPA with slit and notch on patch On implanting one slit and notch on patch of conventional MSTPA, the antenna resonates at 12.1GHz frequency which was convincing to our required band of operation. Fig. 10: Radiation Pattern Fig. 8 : Schematic view of MSTPA IV. FUTURE WORK Fig. 9: Return Loss Further design and optimization of conventional MSTPA has to be done by implanting different slits on patch for introducing 14 -14.5 GHz frequency operation in the antenna with lesser harsh effects on previous design. V. CONCLUSION Simulation results show that by implanting slits and notches on the patch there is shift in resonance frequency. By using these techniques, a compact shaped MSTPA has been introduced for Ku-band satellite applications. From this it is concluded that it is also possible to build a planar antenna array to obtain much better and improved antenna parameters. REFERENCES 1. 2. 3. 4. 5. C. A. Balanis, “Antenna theory analysis and design,” New York: JohnWiley & Sons, 1997. D. M. Pozar, “Microstrip Antennas,” IEEE Proceedings, Vol. 80, pp. 79-91, January 1992. Prasad P.C. and Chattoraj N. “Design of Compact Ku-Band Microstrip Antenna for Satellite Communication,” International Conference on Communications and Signal Processing (ICCSP), Melmaruvathur, 2013, pp.-196 – 200 Sorouri M. and Rezaei P. “A Compact Dual-Band Aperture Coupled Microstrip Antenna for Ku-Band Application,” International Symposium on Antennas and Propagation Society, Chicago, 2012, pp.-1-2 Misran N. et al. “Design of a Compact Dual Band Microstrip Antenna for Ku-Band Application,” International Conference on Electrical Engineering and Informatics, Volume 2, Selangor, 2009, pp. 699-702 Copyright @ IJIRCCE www.ijircce.com 56