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Log-Periodic Loop Antennas PDF

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Log-Periodic Loop Antennas by Jeong Il Kim Thesis submitted to the Faculty of the Virginia Polytechnic Institute and State University in partial fulfillment of the requirements for the degree of Master of Science in Electrical Engineering Ahmad Safaai-Jazi, Chairman Ting-Chung Poon Warren L. Stutzman July, 1999 Blacksburg, Virginia Keywords : Frequency Independent Antenna, Log-Periodic Loop Antenna, Log-Periodic Dipole Antenna, Ground Reflector, ESP Copyright 1999, Jeong Il Kim Log-Periodic Loop Antennas Jeong Il Kim ABSTRACT The Log-Periodic Loop Antenna with Ground Reflector (LPLA-GR) is investigated as a new type of antenna, which provides wide bandwidth, broad beamwidth, and high gain. This antenna has smaller transverse dimensions (by a factor of 2/p ) than a log-periodic dipole antenna with comparable radiation characteristics. Several geometries with different parameters are analyzed numerically using ESP code, which is based on the method of moments. A LPLA-GR with 6 turns and a cone angle of 30(cid:176) offers the most promising radiation characteristics. This antenna yields 47.6 % gain bandwidth and 12 dB gain according to the numerical analysis. The LPLA-GR also provides linear polarization and unidirectional patterns. Three prototype antennas were constructed and measured in the Virginia Tech Antenna Laboratory. Far-field patterns and input impedance were measured over a wide range of frequencies. The measured results agree well with the calculated results. Because of its wide bandwidth, high gain, and small size, the LPLA is expected to find applications as feeds for reflector antennas, as detectors in EMC scattering range, and as mobile communication antennas. Acknowledgements I would like to sincerely thank my advisor, Dr. Ahmad Safaai-Jazi, for an interesting topic and continuing advice. Without his encouragement and suggestions, this work could not have been completed. I would also like to thank the members of my graduate committee, Dr. Warren L. Stutzman and Dr. Ting-Chung Poon, for their helpful advice. Especially, Dr. Stutzman’s classes during the research for my thesis were invaluable. I would like to express special thanks to Mr. Randall Nealy in the Virginia Tech Antenna Group for the help with the pattern and input impedance measurements. I can not forget to thank Mr. Byeong-Mun Song, Gyoo-Soo Chae, Seong-Youp Suh, Byung-Ki Kim, and Tae-Geun Kim for their sincere advice or support. Also, I would like to thank my colleagues, Eakasit Weeratumanoon and Seok-Won Song. Finally, I wish to thank my family- mother, two brothers, two sisters-in-law, a sister and a brother-in-law for their immeasurable concern and support to me. I would like to thank my friends and all of those who offered me help. And I would like to dedicate my thesis to my father to be in Heaven. I would like to forward all thanks to God, because He makes it possible to finish this thesis. iii Table of Contents Chapter 1. Introduction...............................................................................................1 Chapter 2. Evolution of Log-Periodic Dipole Antenna.............................................5 2.1 Principles of Frequency Independent Antennas....................................................5 2.1.1 Angle-Specified Antennas...............................................................................6 2.1.2 Self-Complementary Configuration................................................................7 2.2 Log-Periodic Antennas..........................................................................................9 2.2.1 Log-Periodic Toothed Planar Antenna............................................................9 2.2.2 Log-Periodic Toothed Trapezoidal Antenna.................................................10 2.3 Log-Periodic Dipole Antenna..............................................................................12 2.4 Modifications of the LPDA.................................................................................15 Chapter 3. Log-Periodic Loop Antenna...................................................................16 3.1 Analysis of Single-Loop Antenna.......................................................................17 3.2 Analysis of Log-Periodic Loop Antenna.............................................................24 Chapter 4. Numerical Analysis of LPLA with Ground Reflector..........................32 4.1 Geometries and Parameters.................................................................................32 4.2 Simulation by ESP...............................................................................................35 4.3 Radiation Characteristics of LPLA with Ground Reflector................................36 4.3.1 Gain and Directivity......................................................................................37 4.3.2 Far-Field Pattern............................................................................................42 4.3.3 Polarization....................................................................................................46 iv 4.3.4 Input Impedance............................................................................................48 4.4 Comparison of LPDA, LPLA without GR and LPLA with GR..........................50 4.5 Expected Applications of the LPLA....................................................................51 Chapter 5. Measurements of LPLA with Ground Reflector..................................53 5.1 Antenna Construction..........................................................................................53 5.2 Far-Field Pattern Measurements..........................................................................56 5.3 Input Impedance Measurement...........................................................................62 Chapter 6. Conclusions and Recommendations for Future Work........................70 6.1 Summary of Results............................................................................................70 6.2 Recommendations for Future Work....................................................................71 References....................................................................................................................73 Appendix A. Matlab Program for the Calculation of Far-Field Patterns.............77 Appendix B. Subroutine WGEOM for LPLA.........................................................80 Appendix C. Numerically-Calculated Far-Field Patterns of LPLAs with GR.....88 Appendix D. Effect of Number of Segments on Radiation Properties Predicted from ESP..............................................................................95 Appendix E. Measured Far-Field Patterns of LPLAs with GR.............................98 Vita.............................................................................................................................115 v List of Figures Figure 1-1. Log-periodic dipole antenna without ground reflector................................3 Figure 1-2. Proposed log-periodic loop antenna with ground reflector.........................3 Figure 2.1.2-1. Examples for Complementary pair and Self-complementary configuration..........................................................................................8 Figure 2.2.2-1. Log-periodic antennas..........................................................................11 Figure 2.3-1. Schematic diagram of log-periodic dipole antenna................................13 Figure 3.1-1. Geometrical arrangement of a circular loop antenna for far-field analysis...................................................................................................18 Figure 3.1-2. Eq radiation pattern in the y-z plane and Ef pattern in the x-z plane for a circular loop antenna at 2 GHz by (3.1-13) and (3.1-14)...............22 Figure 3.1-3. Eq radiation pattern in the E-plane and Ef pattern in the H-plane for a circular loop antenna at 2 GHz by using ESP code................................23 Figure 3.2-1. Geometry and coordinates for log-periodic circular loop antenna.........25 Figure 3.2-2. Element circuit and feeder circuit for the analysis of LPLA..................27 vi Figure 3.2-3. Far-field radiation patterns of LPLA in the E- and H-planes by Rojarayanont and ESP............................................................................30 Figure 3.2-4. Comparison of LPLA and LPDA gains and front-to-back ratios. Gain from ESP simulation for LPLA with 200W terminal resistance....31 Figure 4.1-1. Inverted LPLA and LPLA generated by ESP.........................................34 Figure 4.3.1-1. Variations of gain versus frequency for 5-turn LPLA-GR and inverted LPLA-GR with a =30(cid:176) , 45(cid:176) , and 60(cid:176) ....................................................40 Figure 4.3.1-2. Variations of gain versus frequency for 6-turn LPLA-GR and 7-turn LPLA-GR with a =30(cid:176) , 45(cid:176) , and 60(cid:176) ....................................................41 Figure 4.3.1-3. Variations of Gf versus frequency for 8-turn, 9-turn, and 10-turn LPLA-GR with a =30(cid:176) , 45(cid:176) , and 60(cid:176) ....................................................43 Figure 4.3.2-1. Radiation patterns for a 6-turn LPLA-GR with a =30(cid:176) at 2301 MHz in the E-plane.......................................................................................44 Figure 4.3.3-1. Radiation characteristics for the 6-turn LPLA-GR with a =30(cid:176) at 2001 MHz in the 45(cid:176) plane : Gq pattern plot, Gf pattern plot and the phase difference between Eq and Ef .......................................47 Figure 4.3.4-1. Input impedance versus frequency for a 6-turn LPLA-GR with a =30(cid:176) when about 12 segments and 28 segments per wavelength are used..49 Figure 4.5-1. Schematics of time-domain scattering range..........................................52 vii Figure 4.5-2. Four-foot dish with the log-periodic feed...............................................52 Figure 5.1-1. Photograph of a 6-turn LPLA with a =30(cid:176) mounted above a ground reflector....................................................................................55 Figure 5.2-1. Feed arrangement for LPLA with GR....................................................57 Figure 5.2-2. Measured and Calculated Gq patterns for LP1 at 2301 MHz in the E-plane..........................................................................................58 Figure 5.2-3. Measured far-field patterns for LP2 at 2301 MHz in the E-plane..........59 Figure 5.2-4. Measured and Calculated Gq patterns for LP3 at 1.8 GHz in the E-plane..........................................................................................61 Figure 5.3-1. Normalized input impedance to Z =50W for LP1..................................63 0 Figure 5.3-2. Normalized input impedance to Z =50W for LP2..................................64 0 Figure 5.3-3. Normalized input impedance to Z =50W for LP3..................................65 0 Figure 5.3-4. Input resistance and VSWR for LP1 with correction of negative resistance and averaging of s and s .....................................67 11 21 Figure 5.3-5. Input resistance and VSWR for LP2 with correction of negative resistance and averaging of s and s .....................................68 11 21 Figure 5.3-6. Input resistance and VSWR for LP3 with correction of negative resistance and averaging of s and s .....................................69 11 21 viii List of Tables Table 4-1. Variations and corresponding ranges for the investigation of LPLA with Ground Reflector.................................................................................33 Table 5-1. Parameters for constructed LPLAs with GR...............................................54 Table E-1. For comparison of simulated and measured patterns for LP1....................99 Table E-2. For comparison of simulated and measured patterns for LP2..................100 Table E-3. For comparison of simulated and measured patterns for LP3..................100 ix Chapter 1. Introduction The recent explosion in information technology and wireless communications has created many opportunities for enhancing the performance of existing signal transmission and processing systems and has provided a strong motivation for developing novel devices and systems. There is a continued demand for data transmission at higher rates and over longer distances. Wireless and mobile communication systems are, nowadays, at the forefront of research activities. An indispensable element of any wireless communication system is the antenna. Transmission of data at higher rates requires wider bandwidths for the elements constituting a communication link. This requirement for the antenna, which is the subject of interest in this thesis, means wideband antennas need be designed and used. Frequency independent antennas, as a particular class of wideband antennas, were first studied by Rumsey [1]. His simple but significant theory has become the foundation for studying many wideband antennas, such as log-periodic dipole antenna (LPDA). The LPDA, whose properties vary periodically with the logarithm of frequency, consists of linear dipoles as basic constituent elements, as illustrated in Figure 1-1. The elements are fed from a balanced transmission line, each element being placed in an alternating configuration that leads to 180(cid:176) phase change from the adjacent elements. 1

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The LPDA, with linear diploes as constituent elements, is well known for its wide bandwidth and moderate gain. As far as the broadband characteristic
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