Copyright: 2024
Pages: 390
ISBN: 9781685690465

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Description

Substrate Integrated Waveguide (SIW) has evolved over the last decade as a promising technology to realize low-cost and convenient microwave and mm-wave systems with interesting performance characteristics. With the design of SIW-based systems there is a requirement to look for certain aspects in terms of performance, feasibility and readiness for commercial use cases. Substrate Integrated Waveguides thoroughly outlines the working principle, design rules and fabrication procedures of SIW, and several novel design concepts for implementing antennas and passive and active circuits using SIW technology. It focuses on using substrate-­integrated waveguides for designing antennas, antenna arrays, filters and other parts of a modern transceiver. Substrate Integrated Waveguide is an important technology for 5G applications and beyond.

 

Readers will gain a deep understanding of how to leverage SIW for developing advanced microwave and millimeter-wave systems. The book's coverage extends from basic communication principles to the intricate design of SIW-based circuits and systems, ensuring that the reader is equipped with the necessary knowledge to innovate in this rapidly evolving field.

 

Targeted at RF engineers, academic researchers, and post-graduate students, this book stands out by offering a holistic perspective on SIW technology. It goes beyond just the basics, integrating both theoretical foundations and practical design approaches. This book serves as an essential resource for those seeking to master SIW technology. Whether for academic study or practical application, it provides the tools and insights necessary to contribute to the next generation of communication systems, particularly in terms of 5G and future technologies.

Table Of Contents

Chapter 1: Introduction
1.1 Overview of Communication Systems
1.2 Basics of RF Transciever Systems
1.3 Introduction to SIW Technology
1.4 Types of SIW Structures
1.5 Overview of Analysis Techniques for SIW
1.6 SIW Fabrication

 

Chapter 2: Design and Characteristics of SIW
2.1 Working Principle
2.2 Excitation techniques
2.3 Design of SIW Cavity

 

Chapter 3: SIW Antennas
3.1 SIW Cavity backed slot antenna
3.2 Design Technique for multiband antenna
3.3 Design of Broadband Antenna
3.4 Design of dual polarized antenna

 

Chapter 4: Advanced SIW Antennas
4.1 SIW High Gain Antenna
4.2 SIW Self-multiplexing Antenna
4.3 SIW Slot Array Antenna

 

Chapter 5: SIW Filters
5.1 Bandpass Filter Synthesis and Coupling Matrix
5.2 Bandpass filter design using single-mode rectangular SIW cavity loaded with metallic inductive post and iris
5.3 Bandpass filter design using Substrate Integrated Hexagonal Cavity (SIHC)
5.4 Perturbation of dual-mode hexagonal cavity and its application in filter design
5.5 Single band SIHC filter design using dual-mode cavity
5.6 Dual band SIHC filter design using dual-mode cavity
5.7 Miniaturized SIW Based Bandpass Filter Design
5.8 SIHC based Bandstop Filter

 

Chapter 6: SIW Passive Circuits
6.1 Diplexer Design
6.2 Dual-band Diplexer Design using Single-Mode SIHC
6.3 Triplexer Design
6.4 SIW based Balun Filter and Balun Diplexer Design
6.5 SIW based Hybrid Branch Line Coupler
6.6 Conclusion

 

Chapter 7: SIW Active Circuits
7.1 Low Phase Noise Oscillator
7.2 Self-Oscillating Mixer
7.3 Conclusions

 

Chapter 8: SIW System and its application
8.1 SIW Filtering antenna and its application in active integrated antenna (AIA)
8.2 SIW Active Integrated Antenna
8.3 SIW based RFIC systems
8.4 Application of SIW systems and market trends
8.5 Conclusions

Author

  • Soumava Mukherjee

    received the B.Tech. degree in Electronics and Communication Engineering from the West Bengal University of Technology, in 2009, M.E. degree in Electronics and Telecommunication Engineering from Bengal Engineering and Science University, Shibpur (BESUS), in 2011, with specialization in Microwave and Communication Engineering, and the Ph.D. degree from the Department of Electrical Engineering, IIT Kanpur (IITK), in 2016. Since 2023, he is serving as Associate Professor in the Electrical Engineering Department, IIT Jodhpur, Jodhpur, India where he was serving as Assistant Professor from 2016 to 2023. His current research interests include substrate integrated coaxial line antennas and circuits, substrate integrated waveguide (SIW) antennas and multifrequency and broadband antennas. Dr. Mukherjee was a recipient of the European Microwave Student Grant in EuMC 2013 and EuMC 2014. He also received the International Travel Grant from the Department of Science and Technology (DST), Government of India. He is also a recipient of the Young Scientist Award AP-RASC-2019 (URSI Asia-Pacific Radio Science Conference) instituted by the International Union of Radio Science.

  • Prasun Chongder

    received the M.Tech. degree in Radio Frequency Design Technology (RFDT) from CARE Center of IIT Delhi, in 2009, and the PhD degree in RF & Microwave specialization from electrical engineering department of IIT Kanpur, in 2017. During his PhD, he involved in designing the advanced microwave transceiver system using Substrate Integrated Waveguide (SIW) technology for RADAR communication system. Since 2018, he has been with the Department of Electronics & Communication Engineering, NIT Rourkela, where he is currently an Assistant Professor. His current research interests include substrate integrated circuits (SICs) for microwave and millimeter-waves applications, multiband filter design, and reconfigurability and advanced multiband reconfigurable filtering antenna design for RADAR communication system.

  • Animesh Biswas

    received the B.E degree from Bengal Engineering College, Shibpur in Electronics and Telecommunication in the year 1980 and M Tech. degree in Microwave and Radar engineering from the IIT Kharagpur, India, in 1982. He received PhD degree in electrical engineering from the IIT Delhi, New Delhi, India, in 1989. From 1989 to 1990, he was a Post-Doctoral Fellow at Oregon State University, USA where he was involved in characterizing multi-conductor lines in layered medium. Since 1992, He is serving as faculty with the Department of Electrical Engineering, IIT Kanpur, Kanpur, India and is presently holding a post of Professor. He has served as a technical consultant for M/S COMDEV Europe and was involved in the development of multimode DR filters and diplexers. He also served as RFIC designer for M/s. Ashvattha Semiconductors, USA for a year and contributed significantly to the area of on-chip LNA and Power Amplifier development. His current research includes modeling of microwaves circuits, RF integrated circuits (RFICs), and numerical methods for solving electromagnetic problems. He has authored or co-authored over 220 papers in various peer-reviewed international journals and conference proceedings. Prof. Biswas is a Fellow, West Bengal Academy of Science and Technology, the Institution of Electronics and Telecommunication Engineers, India and Senior Member of IEEE, USA. Recently, he received prestigious Ram Lal Wardha award from IETE, India for outstanding original contributions for last ten years in RF and Microwaves. He also served as Director of National Institute of Technology, Rourkela from 2016 to 2021.