DESIGN OF DUAL BAND FREQUENCY SELECTIVE SURFACE NORSHAHIDA BINTI MOHD SAIDI B071110042 UNIVERSITI TEKNIKAL MALAYSIA MELAKA 2015
UNIVERSITI TEKNIKAL MALAYSIA MELAKA DESIGN OF DUAL BAND FREQUENCY SELECTIVE SURFACE (FSS) This report submitted in accordance with requirement of the Universiti Teknikal Malaysia Melaka (UTeM) for the Bachelor s Degree in Electronics Engineering Technology (Telecommunications) with Honours by NORSHAHIDA BINTI MOHD SAIDI B071110042 920502025622 FACULTY OF ENGINEERING TECHNOLOGY 2015
UNIVERSITI TEKNIKAL MALAYSIA MELAKA BORANG PENGESAHAN STATUS LAPORAN PROJEK SARJANA MUDA TAJUK: DESIGN OF DUAL BAND FREQUENCY SELECTIVE SURFACE SESI PENGAJIAN: 2014/15 SEMESTER 1 Saya: NORSHAHIDA BINTI MOHD SAIDI mengaku membenarkan Laporan PSM ini disimpan di Perpustakaan Universiti Teknikal Malaysia Melaka (UTeM) dengan syarat-syarat kegunaan seperti berikut: 1. Laporan PSM adalah hak milik Universiti Teknikal Malaysia Melaka dan penulis. 2. Perpustakaan Universiti Teknikal Malaysia Melaka dibenarkan membuat salinan untuk tujuan pengajian sahaja dengan izin penulis. 3. Perpustakaan dibenarkan membuat salinan laporan PSM ini sebagai bahan pertukaran antara institusi pengajian tinggi. 4. **Sila tandakan ( ) SULIT TERHAD TIDAK TERHAD (Mengandungi maklumat yang berdarjah keselamatan atau kepentingan Malaysia sebagaimana yang termaktub dalam AKTA RAHSIA RASMI 1972) (Mengandungi maklumat TERHAD yang telah ditentukan oleh organisasi/badan di mana penyelidikan dijalankan) Disahkan oleh: Alamat Tetap: NO 1A, PPRT KG SUNGAI NAMEK, Cop Rasmi: MERBAU KUDUNG, BATU LIMA, 08200 SIK, KEDAH. Tarikh: Tarikh:
DECLARATION I hereby, declared this report entitled Design of Dual Band Frequency Selective Surface is the results of my own research except as cited in references. Signature :. Author s Name : Date : iv
APPROVAL This report is submitted to the Faculty of Engineering Technology of UTeM as a partial fulfillment of the requirements for the Bachelor s Degree in Electronics Engineering Technology (Telecommunications) with Honours. The member of the supervisory is as follow: (Project Supervisor) v
ABSTRAK 'Frequency Selective Surface' (FSS) boleh dianggap sebagai pembinaan permukaan berfungsi sebagai penapis bagi gelombang kapal terbang di mana-mana sudut tuju. Ia telah digunakan secara meluas dalam komunikasi jalur lebar, sistem radar, dan teknologi antena. Hari ini permintaan besar terhadap antena yang mempunyai pelbagai fungsi untuk sistem telekomunikasi semakin meningkat. Oleh itu, permintaan terhadap FSS dengan pelbagai ciri sangat diperlukan. Objektif projek ini adalah untuk mereka bentuk dwi-band FSS yang menggunakan frekuensi tertentu untuk mendapatkan FSS dengan prestasi yang cemerlang dengan memilih unsur yang sesuai atau gabungan unsur-unsur. Teknik yang digunakan untuk mencapai dwi-band FSS adalah dengan menggunakan struktur gelung persegi berganda kerana gelung persegi mempunyai kelebihan yang mudah di dalam struktur dan mudah untuk dianalisis, direka dengan kos bahan yang rendah dan struktur yang ringan serta mudah untuk dikendalikan. Akhir sekali, FSS telah direka dan simulasi dengan menggunakan perisian CST Studio Suite pada 8.0 GHz dan 10.3 GHz saluran frekuensi. vi
ABSTRACT A Frequency Selective Surface (FSS) can be considered to be a surface construction serving as a filter for plane waves at any angles of incidence. It has been widely used in broadband communications, radar systems, and antenna technology. Today there is a growing demand on multifunctional antennas for telecommunication systems. Therefore the development of FSS with multiband characteristics is needed. The objective of this project is to design a dual band Frequency Selective Surface (FSS) by using certain frequency to obtain FSS with excellent performance by choosing a suitable element or combinations of elements. The technique used to achieve dual band FSS is by using Double Square loop structure because the square loop has the advantages which are simple in structure and easy to analyse and fabricate with low cost materials and exhibits a low weight and easy to handle structure. Finally, the FSS was designed and simulated by using CST Studio Suite software at 8.0 GHz and 10.3 GHz resonant frequency. vii
DEDICATION To my beloved parents, Mohd Saidi Bin Wahab and Ruseni Bt Mat Naam that have sacrificed so much and was always encouraging and support for the sake of your daughter to be beneficial person to the society. Without enduring the bone chilling cold, How could the plum blossom emit such a sweet fragrance? viii
ACKNOWLEDGEMENT Syukur Alhamdulillah, all praises are due to Allah, finally this project report come to an end. In order to complete this report, I was in contact with many people. They have contributed towards my understanding and thought. First, I would like to express my sincere appreciation to my supervisor and co-supervisor, Encik Abdul Halim Bin Dahalan and Encik Mohamad Zoinol Abidin Bin Abdul Aziz who is really kind, patience and continuously guided me by share their time and knowledge during doing this project. Special thanks to my beloved parents, Mohd Saidi Bin Wahab and Ruseni Bt Mat Naam who supported me from long distance with prayer and never stop to give me advice whenever I m down and also thanks a lot to my friends especially my dear classmates and roommate, Nadiatul Shima Bt Kamarudin in helping me to complete my project and thesis. I really appreciate all of you. Again, thank you. ix
TABLE OF CONTENT Abstrak Abstract Dedication Acknowledgement Table of Content List of Tables List of Figures List Abbreviations, Symbols and Nomenclatures i ii iii iv v vi vii viii CHAPTER 1: INTRODUCTION 1 1.1 Project Background 2 1.2 Problem Statement 2 1.3 Objective 3 1.4 Scope of Project 3 1.5 Project Overview 4 CHAPTER 2: LITERATURE REVIEW 2.1 FSS Theory 5 2.1.1 Equivalent Circuit of FSS 8 2.2 Analysis of FSS 9 2.3 Applications of FSS 10 2.4 Design Parameter of FSS 12 2.4.1 Element Geometry 12 2.4.1.1 Group I 13 2.4.1.2 Group II 13 2.4.1.3 Group III 14 2.4.1.4 Group IV 14 2.5 Conductivity and Thickness of FSS 16 2.6 Dielectric Substrates 17 x
2.7 Incident Angle 17 2.8 Research Studies 18 2.8.1 A Novel Dual Band FSS 19 2.8.2 Design of DSLFSS with Swarm Particle Optimization via the Equivalent Circuit Model 20 2.8.3 The Study of Dual Band Frequency Selective Surface with Miniaturized Element in Low Frequency 21 2.9 Conclusion 22 CHAPTER 3: METHODOLOGY 3.1 Introduction 23 3.1.1 Literature Review 23 3.1.2 Data Collection 24 3.1.3 Design and Simulation 24 3.1.4 Fabricate and Hardware Test 24 3.1.5 Documentation 24 3.2 Flowchart 25 3.3 FSS Modelling and Simulation 27 3.3.1 Simulation Software 27 3.3.2 Simulation by using CST 27 3.4 FSS Model 29 3.5 Development Prototype of FSS 31 3.5.1 FSS Fabrication 31 3.5.2 Measurement Setup 34 3.6 Conclusion 36 CHAPTER 4: RESULT AND DISCUSSION 4.1 Simulation Result 37 4.1.1 Transmission and Reflection curve of DSLFSS 38 4.1.2 Effect of Varying Length of Element 39 4.1.3 Effect of Varying Element Width 40 4.1.4 Effect of Varying Width of Element Gap 41 xi
4.2 Free Space Measurement 42 4.3 Result Comparison 43 4.4 Conclusion 45 CHAPTER 5: CONCLUSION AND FUTURE WORK 5.1 Project Conclusion 46 5.2 Future Work 47 REFERENCES 48 APPENDICES A Equivalent Circuit B Gant Chart xii
LIST OF TABLES 2.1 Performance analysis of FSS s different elements 15 3.1 Parameters of Square Loop FSS 28 4.1 Lab measurement results summary 43 4.2 Comparison between simulation and measured result 44 xiii
LIST OF FIGURES 2.1 Types of FSS 6 2.2 Schematic representation of band stop and band pass FSS 6 2.3 Example of band stop FSS with dipole like metallic patches 7 2.4 Equivalent Circuit FSS 8 2.5 NASA DSS 13 beam-waveguide antenna and Cassegrain sub 10 reflector 2.6 FSS radomes integrated in airplanes and radomes for abroad 11 military ships 2.7 N-Poles 13 2.8 Loop Types 13 2.9 Plate Type 14 2.10 Combinations 14 2.11 Effects of dielectric on resonance frequency 17 2.12 Equivalent projected separation between elements by an 18 obliquely incident signal 2.13 Overview of the whole unit. 19 2.14 Simulated reflection and transmission coefficients of the proposed FSS 20 3.1 Overall flowchart 25 3.2 Square loop FSS 28 3.3 Unit cell geometry 29 3.4 7 x 7 Unit cell geometry 30 3.5 FSS prototype fabrication process 31 3.6 Measurement Setup 34 4.1 Transmission and reflection response result 38 4.2 The effect of varying element length 39 4.3 The effect of varying element width 40 4.4 The effect of varying element gap 41 xiv
4.5 Free space measurements 42 4.6 Transmission and Reflection response result 43 4.7 Simulation and Prototype of FSS 44 xv
LIST OF ABBREVIATIONS, SYMBOLS AND NOMENCLATURE CST - Computer Simulation Technology DSL - Double Square Loop EM - Electromagnetic FFT - Finite integration technique FSS - Frequency Selective Surface PCB - Print Circuit Board RF - Radio Frequency RFID - Radio Frequency Identification RX - Receiving Antenna TX - Transmitting Antenna S11 - Reflector Coefficient S21 - Transmission Coefficient f - Frequecy BW - Bandwidth θ - Theta λ - Wavelength xvi
CHAPTER 1 INTRODUCTION This chapter discussed about the introduction of this project such as general information about Frequency Selective Surface (FSS), problem statement, objective, scope of the project and explanation organization of project. 1.1 Project Background Since early 1960 s, due to applications military potential, structures FSS has being intensive study matter. Marconi and Franklin, however are believed, to becoming early pioneer in this area for their contribution of a parabolic reflection made using half-wavelength wire sections in 1919. FSS as frequency selective materials have traditionally used in stealth technology to reduce radar cross section (RCS) communication system. The use of frequency selective surface (FSS) has successfully proven as a means to enhance communication capabilities satellite platform. In space missions such as Voyager, Galileo, and Cassini, the use of a dual-reflector antenna with FSS sub reflectors has made it possible to share the main reflector among different frequency band. Furthermore, growing demand in on multifunctional antenna for communication systems has required the development of FSS with features multiband. 1
FSS structures to space waves are the counterparts of filters in transmission lines. Once revealed to electromagnetic radiation, FSS behaves like a spatial filter which is some frequency bands are transmitted and some are reflected. In a manner, FSS could be envelope because hide communication facilities. This may be first potential application FSS structures, because they had actually once used as coverage called radomes. Thus, in some applications, the use of filters the signal is very important to get only the necessary signals from space. This is where the use of Frequency Selective Surface (FSS) becomes important. Use of FSS is to reduce interference between the signals and also acts as a filter signal. It only allows the signals required to pass through a given surface and reflects all any other unwanted signals into the air. 1.2 Problem Statement For decades, many novel methods were proposed to obtain FSS with excellent performances but most result comes out with the complexity in the design and difficult to be analyzed. So due to this, there is a need to design of the dual band Frequency Selective Surface by using certain frequency to obtain FSS with excellent performances. 2
1.3 Objective The objectives of this project are: 1. To design of dual band Frequency Selective Surface by using certain frequency to obtain FSS with excellent performance by choosing a suitable element or combinations of elements. 2. To design the FSS by using CST software that offers accurate, efficient computational solutions for the hardware developing for this project. 1.4 Scope of Project Scope of this project is to design dual band FSS at resonant frequency 8 GHz and 10.3 GHz by using CST Studio Suite. Then, to obtain the S-parameters which are reflection coefficient (S11) and transmission coefficient (S21) respectively, the designed structure is simulated by using the software. This scope of project also will cover the study of resonance characteristics of FSS that are depends which is element dimensions and element of FSS design. This project will test by hardware will be done by etching and fabrication process and measurement by using network analyzer in order to get the required results which are close to the theoretical results then the result can be analyzed. 3
1.5 Project Overview This report is organized into five chapters. For the first chapter, it is briefly discussed about the project background, the problem statement, the objective of this project and also the working scope for this project. For the Chapter 2, the literature review was conducted throughout the entire project to gain knowledge and skills needed to complete this project. The main sources for this project are the previous projects and thesis that related to this project. And other sources are books, journals and articles obtained from the internet. As for Chapter 3, this chapter brief the most important step in the design process of a desired FSS is the proper choice of constituting elements for the array. So in this chapter, it provides brief description the flow the design of dual band FSS consists of the most important part in the design FSS which is the elements of design and the elements geometries of FSS. All the steps taken to design the proposed FSS will be explained. In Chapter 4, it is discussed about the simulation result from software and measurement result which is a dual-band frequency selective surface was designed, fabricated and measured with perfectly double square loop patch elements. The measurement results are compared with the simulation results obtained. Lastly in Chapter 5, it is a conclusion and a recommendation chapter. This chapter will conclude about the whole project and this chapter also pointed a brief discussion on the recommendation of the future work. 4
CHAPTER 2 LITERATURE REVIEW The literature review was conducted throughout the entire project to gain the knowledge and skills needed to complete this project. The main source for this project is the previous project and thesis related to this project and other sources are books, journals and articles obtained from the internet. In order to design this dual band of FSS, research had been made among previous project to studying the concept use, their method, making the best comparison and then implement in this project. 2.1 FSS Theory Frequency Selective Surface, FSS are periodic surfaces that behave as filter for electromagnetic wave. FSS is a mounting structure that behaves similar plane as filter EM [1]. FSS can also be defined as a metal surface designed to be frequency selective in nature indicating it s reflected or transmitted [6]. The frequency selective property described by Rittenhouse [3] proved the fact that surfaces can exhibit different transmission properties for different frequencies of incident wave. Based on geometries, FSSs can be categorized into four type of filter which is band-stop, bandpass, low-pass and high-pass as shown in Figure 2.1. Filtering characteristics of EM mainly depends on the type and shape of the FSS elements. 5
Figure 2.1: (a) band stop (b) band pass (c) low pass (d) high pass. Conductive part represent by brown color Some types of FSS exist but they can be grouped into two main classes: band stop and band pass FSS. Both reached the behavior depends on their frequency resonance effects exploit periodic planar layout along the surface of the FSS own. In particular, the band stop FSS usually consists of several metal patch arbitrarily shaped printed on a dielectric substrate. Band pass FSS generally designed to create apertures in the metal plate. Both types of FSS can be formed by many layers stacked on top of each other. Figure 2.2: Schematic representation of band stop and band pass FSS 6
Due to the electromagnetic behavior of the FSS tied to a resonance phenomenon, a kind of band stop can achieve reflectance field incident despite the fact that the area covered by the metal is only a small part of the total area. Similarly, the type of band pass can achieve total transmission plane incident despite the fact that the apertures represents only a small fraction of the total area. To further realize the potential of these structures, the following simple example might help to give the proportion of resonance effects. Let's consider band stop FSS composed by metal patch shaped as dipoles, printed together on a regular layout on a dielectric substrate. Figure 2.3: Example of band stop FSS with dipole like metallic patches 7
2.1.1 Equivalent Circuit FSS Patch Element Aperture Element Figure 2.4: Equivalent Circuit FSS As shown in Figure 2.4, patch elements can be seen as a parallel connection of capacitors and inductors, and various elements of the aperture is represented by a series LC circuit, where the conducting element provides inductance and the distance between the elements represents capacitance. From this simple analysis, it is easy to show that the resonant frequency is given by: Equation 2.1 The fractional bandwidth is defined as the difference between the lower and upper frequency at -10 db which is proportional to Equation 2.2 Therefore, increasing the length of the conducting element can reduce the resonant frequency and increase bandwidth. A lower resonant frequency can also be achieved by increasing the capacitance, but resulted in a narrow bandwidth. 8