I Microwave and Millimeter Wave Technologies: from Photonic Bandgap Devices to Antenna and Applications Microwave and Millimeter Wave Technologies: from Photonic Bandgap Devices to Antenna and Applications Edited by Prof. Igor Minin In-Tech intechweb.org Published by In-Teh In-Teh Olajnica 19/2, 32000 Vukovar, Croatia Abstracting and non-profit use of the material is permitted with credit to the source. Statements and opinions expressed in the chapters are these of the individual contributors and not necessarily those of the editors or publisher. No responsibility is accepted for the accuracy of information contained in the published articles. Publisher assumes no responsibility liability for any damage or injury to persons or property arising out of the use of any materials, instructions, methods or ideas contained inside. After this work has been published by the In-Teh, authors have the right to republish it, in whole or part, in any publication of which they are an author or editor, and the make other personal use of the work. © 2010 In-teh www.intechweb.org Additional copies can be obtained from: [email protected] First published March 2010 Printed in India Technical Editor: Sonja Mujacic Cover designed by Dino Smrekar Microwave and Millimeter Wave Technologies: from Photonic Bandgap Devices to Antenna and Applications, Edited by Prof. Igor Minin p. cm. ISBN 978-953-7619-66-4 V Preface This book deal with the modern developing of microwave and millimeter wave technologies. The first chapter is aimed at describing the evolution of technological processes for the design of passive functions in millimetre-wave frequency range. From the results HR SOI seems to be a good candidate in the coming year to address both low cost and low power mass market CMOS digital and RF/ MMW applications. Materials that exhibit negative index (NI) of refraction have several potential applications in microwave technology. Examples include enhanced transmission line capability, power enhancement/size reduction in antenna applications and, in the field of nondestructive testing, improved sensitivity of patch sensors and detection of sub-wavelength defects in dielectrics by utilizing a NI superlens. The next two chapters explains the physics underlying the design of purely dielectric NI metamaterials and will discuss some ways in which these materials may be used to enhance various microwave technologies. There are two main reasons to want to have information for the actual anisotropy of a substrate – to control the technology (necessary for the manufacturers) and to conduct more realistic simulations of the structures, containing anisotropic materials (necessary for the users). The 3rd chapter represented the increasing importance of the material’s anisotropy in the modern design and the possibilities for accurate determination of this characteristic by waveguide and resonance methods. Wave propagation in suppositional material was first analyzed by Victor Vesalago in 1968. Suppositional material is characterised by negative permittivity and negative permeability material properties. Under these conditions, phase velocity propagates in opposite direction to group velocity. Since then, these electrical structures have been studied extensively and are referred to as meta-material structures. In the 4th chapter the authors analyze meta-material concepts using transmission line theory proposed by Caloz and Itho and propose effective materials for realising these concepts. They propose a novel NPLH (Near Pure Left Handed) transmission line concept to reduce RH (Right Handed) characteristics and realize compact small antenna designs using meta-material concepts and the possibility of realising negative permittivity using EM shielding of concrete block is considered. The basic theory of microwave filters, to describe how to design practical microwave filters, and to investigate ways of implementing high performance filters for modern communication systems are given in the 5th chapter. And the 6th chapter covered filters made using different technologies including active devices, MEMS, ferroelectric and ferromagnetic materials. Filters involving combined technologies VI were covered; and also the traditional tuning using mechanically adjustable screws was discussed. The 7th chapter present several key points in materials optimization, capacitor structure, and device designs that Georgia Institute of Technology and nGimat have focused on in the last few years. In the 8th chapter summarizes the current status of the MOSFET´s for very high frequency applications. The potential of high permittivity dielectric materials for local capacitive loading of microstrip components has been demonstrated in the 9th Chapter. The designs of miniature microstrip resonators, filters, and antennas with local high-permittivity dielectric loading have been developed, and the prototypes have been fabricated by using the LTCC technology that allowed for coprocessing different ceramic materials in multilayer and planar architecture. Three types of microstrip-to-waveguide transitions are presented in the 10th chapter. One is a transition with a short-circuited waveguide which is quite broadband such that bandwidth of reflection below −20 dB is 24.9 GHz (32.5 %). Others two are a planar transition in multi-layer and single-layer substrate substrates. The original reflector antenna design with the cylindrical monopole antenna as a sub-reflector for application in radio monitoring for information protection has been presented in 11 chapter. In the 12 chapter present a brief coverage of both established and emerging techniques in materials characterization. The 802.11 a/b/g FEM with PAM was composed of a SPDT switch, a Rx diplexer, two Rx BPFs, a Tx diplexer, two Tx LPFs, two matching circuits, and a dual-band PAM and discussed in the 13 chapter. In simple terms, a millimeter-wave imaging sensor is a camera that uses millimeter waves. The authors in the 14th chapter reviewed imaging sensors using the millimeter-wave band. But to my regret the authors searched publications mainly on International Microwave Symposium and did not survey papers on SPIE and others sources. So the good review is not full, for example, Table 2 could be added by the results from [1] and so on. The authors in the chapter 15 describe and exemplify from many fractals applications one possible use, fractal antenna for terrestrial vehicles. In order to protect the antenna from various environments, dielectric radome is usually covered in front of the antenna. The authors in the chapter 16 mainly focus on the analysis and optimal design of the radome in millimeter wave band. But it could be noted that in some of case with help of 3D diffractive optics it is possible to design a millimeter-wave antenna without special radome [2]. Additional, in the chapter 17 the authors described the design scheme for multibeam dielectric lens antennas that well balances the conflicting aims of high gain and low sidelobe level. The scheme is based on pareto-GA and lens shape is associated with GA chromosomes. In the chapter 18 investigated several structures in order to find the main geometrical parameters able to improve performances of a PBG based particle accelerator. All the VII simulations reveal good performances for a structure based on dielectric rods and a suitable number of grating periods. In the last chapter, specific millimeter-wave features of the Fabry-Perot resonator are discussed. It is expected the book will attract more interest in microwave and millimeter wave technologies and simulate new ideas on this fascinating subject. References: 1. O.V.Minin and I.V.Minin. Diffractive optics of millimeter waves. IOP Publisher, Bristol and Philadelphia, 2004, 396p. ISBN 0-7503-0907-5 2. I.V.Minin and O.V.Minin. Three Dimensional Fresnel Antennas. In: Advances on Antennas, Reflectors and Beam Control, Research Signpost, Kerala, INDIA, 2005, pp. 113-148. ISBN 81- 308-0067-5 Prof. Igor Minin Novosibirsk State Technical University Russia [email protected] VIII IX Contents Preface V 1. Trend on Silicon Technologies for Millimetre-Wave Applications up to 220 GHz 001 Gaëtan Prigent, Thanh Mai Vu, Eric Rius and Robert Plana 2. Integrated Silicon Microwave and Millimeterwave Passive Components and Functions 031 Philippe Benech, Jean-Marc Duchamp, Philippe Ferrari, Darine Kaddour, Emmanuel Pistono, Tan Phu Vuong, Pascal Xavier and Christophe Hoarauand Jean-Daniel Arnould 3. Negative Refractive Index Composite Metamaterials for Microwave Technology 055 Nicola Bowler 4. Dielectric Anisotropy of Modern Microwave Substrates 075 Plamen I. Dankov 5. Application of meta-material concepts 103 Ho-Yong Kim and Hong-Min Lee 6. Microwave Filters 133 Jiafeng Zhou 7. Reconfigurable Microwave Filters 159 Ignacio Llamas-Garro and Zabdiel Brito-Brito 8. Electronically Tunable Ferroelectric Devices for Microwave Applications 185 Stanis Courrèges1, Zhiyong Zhao2, Kwang Choi2, Andrew Hunt2 and John Papapolymerou1 9. Advanced RF MOSFET´s for microwave and millimeter wave applications: RF characterization issues 205 Julio C. Tinoco and Jean-Pierre Raskin 10. Development of Miniature Microwave Components by Using High Contrast Dielectrics 231 Elena Semouchkina 11. Broadband and Planar Microstrip-to-waveguide Transitions 257 Kunio Sakakibara X 12. Microwave and Millimeter Wave TechnologiesA New X-Band Mobile Direction Finder 273 Sergey Radionov, Igor Ivanchenko, Maksym Khruslov, Aleksey Korolev and Nina Popenko 13. Characterization techniques for materials’ properties measurement 289 Hussein KASSEM, Valérie VIGNERAS and Guillaume LUNET 14. Implementation of the Front-End-Module with a Power Amplifier for Wireless LAN 315 Jong-In Ryu, Dongsu Kim and Jun-Chul Kim 15. Millimeter-wave Imaging Sensor 331 Masaru Sato and Koji Mizuno 16. Fractal Antenna Applications 351 Mircea V. Rusu and Roman Baican 17. Analysis and Design of Radome in Millimeter Wave Band 383 Hongfu Meng and Wenbin Dou 18. Design of dielectric lens antennas by multi-objective optimization 405 Yoshihiko Kuwahara and Takashi Maruyama 19. Modelling and Design of Photonic Bandgap Devices: a Microwave Accelerating Cavity for Cancer Hadrontherapy 431 Roberto Marani and Anna Gina Perri 20. Specific Millimeter-Wave Features of Fabry-Perot Resonator for Spectroscopic Measurements 451 Petr Piksa, Stanislav Zvánovec and, Petr Černý
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