is currently a Distinguished Professor in the Global Big Data Technologies Centre in the Faculty of Engineering and Information Technologies (FEIT) at the University of Technology Sydney, Ultimo NSW, Australia. He became a Professor Emeritus at the University of Arizona in 2018, where he was a Litton Industries John M. Leonis Distinguished Professor in the Department of Electrical and Computer Engineering in the College of Engineering and was also a Professor in the College of Optical Sciences. He was the Computational Electronics and Electromagnetics Thrust Area Leader with the Engineering Research Division of the Lawrence Livermore National Laboratory before joining The University of Arizona, Tucson, AZ, USA in 1990. His current research interests include the application of new mathematical and numerical methods to linear and nonlinear problems dealing with the interaction of electromagnetic and acoustic waves with complex linear and nonlinear media, as well as metamaterials, metamaterial‐inspired structures, nanostructures, and other classical and quantum application‐specific configurations.
Acknowledgments
Antennas are a significant, fundamental, and practical research area of electromagnetics. Unfortunately, they have been considered by many academic administrators and government funding agencies simply as being well established, i.e. “old stuff.” However, the wireless communications and sensors community is well aware that antennas are the key enabling technology of all things wireless.
Wireless technologies have become ubiquitous and truly critical in many ways to our everyday lives. These facts have become exceptionally clear now during this 2020 COVID pandemic. Whether you are a homemaker ordering foodstuffs to sustain your family via your cell phone and its network or you are a child learning and doing schoolwork online in your room while your academic parent is lecturing via Zoom from a home office, both being enabled by their computer’s WiFi connection to the family’s MIMO‐based router, or you are a new grandparent seeing the newest member of your family remotely for the first time with FaceTime on your mobile platform or you are an antenna engineer interacting with company colleagues through Microsoft Teams on your handheld device to practice proper social‐distancing protocols or even if you are two authors writing a book on antenna array technologies and are separated by a 19‐hour time difference and a mere 13,000‐km, wireless has meant that we can continue to perform tasks that need to be accomplished and can communicate and interact with family, friends, and colleagues on a regular basis.
Consequently, there have been very real and intense industry pushes and market pulls for various modern antenna systems to empower current fifth‐generation (5G) and future sixth‐generation (6G), and beyond wireless devices, applications, and their associated ecosystems. Scientific and engineering progress in array technologies has particularly benefited from user and stakeholder cravings for higher data rates and lower latencies. Antenna arrays will continue to play a major role in all future wireless generations. Pioneering wireless array research typically stresses advanced features such as steerable beams, multi‐beams, multiband antenna coexistence, antenna reconfiguration, low‐cost feed networks, and conformity to platforms. The various conundrums associated with the evolving land, air, and space networks associated with them will challenge all of us to develop fundamental and applied electromagnetics breakthroughs to solve them.
Under this backdrop, we have had the great privilege of working with a number of very talented PhD students, postdoctoral fellows, visiting scholars, and international collaborators. Our mutual interest and joint research efforts in antennas and antenna arrays for current 5G (fifth‐generation) and future 6G, and beyond wireless ecosystems have deepened our understanding of their fundamentals, as well as their practical considerations necessary to successfully deliver useful systems for commercial applications that actually satisfy most of their generally overambitious, initial performance goals.
Our presentation of antenna and antenna arrays for current 5G and evolving 6G, and beyond systems in this book is organized into eight logical chapters that reflect our thoughts and the findings generated in those endeavors. Consequently, we are deeply indebted to our colleagues for their dedication and great contributions to the state of the art which are highlighted in these chapters. In particular, we would like to acknowledge specific inputs to them as follows:
Chapter 2: Ji‐Wei Lian, Visiting Student, University of Technology Sydney (UTS), Australia
Chapter 3: Prof. Ming‐Chun Tang, Chongqing University, China
Chapter 4: Dr. Can Ding, Lecturer, UTS, Australia and Dr. Hai‐Han Sun, postdoctoral researcher, Nanyang Technology University (NTU), Singapore
Chapter 5: Dr. He Zhu, postdoctoral researcher, UTS, Australia
Chapter 6: Dr. Pei‐Yuan Qin, Senior Lecturer, and Ph.D student Li‐Zhao Song, UTS, Australia
Chapter 7: Dr. Stanley (Shulin) Chen, postdoctoral researcher, UTS, Australia; Dr. Debabrata K. Karmokar, Lecturer, University of South Australia, Australia; Prof. José Luis Gómez Tornero, Technical University of Cartagena, Spain; and Ji‐Wei Lian, visiting student at UTS, Australia; Prof. Zheng Li, Beijing Jiaotong University, China.
Chapter 8: Prof. Yanhui Liu, Research Principal, UTS, Australia, and Ming Li, PhD student, UTS, Australia.
We thank them all for their invaluable time and efforts and wish them even greater successes in their future endeavors and careers.
We would also like to express our gratitude to University of Technology Sydney (UTS) for their whole‐hearted support to our antennas research team.
Finally, we happily acknowledge our wives, Clare Guo and Lea Ziolkowski, and thank our lucky stars for their endless understanding, support and patience, particularly when we disappear for uncountable hours on cosmic efforts such as this :-)
1 A Perspective of Antennas for 5G and 6G
The roll‐out of the fifth generation (5G) of wireless and mobile communications systems has commenced, and the technology race on the sixth‐generation (6G) mobile and wireless communications systems has started in earnest [1, 2]. 5G promises significantly increased capacity, massive connections, low latency, and compelling new applications. For example, device‐to‐device (D2D) and vehicle‐to‐vehicle (V2V) communication systems will help facilitate the realization of autonomous transport. The rapid access to and exchange of “Big Data” will increasingly impact real‐time economic and political decisions. Similarly, highly integrated, accessible “infotainment” systems will continue to alter our social relationships and communities. Wireless power transfer will replace cumbersome, weighty, short‐life batteries enabling widespread health, agriculture, and building monitoring sensor networks with much less waste impact on the environment. 6G networks aim to achieve a number of new features such as full global coverage, much greater data rates and mobility, and higher energy and cost efficiency. These will usher in new services based on virtual reality/augmented reality and artificial intelligence [3].
At the core of wireless devices, systems, networks, and ecosystems are their antennas and antenna arrays. Antennas enable the transmission and reception of electromagnetic energy. Antenna arrays enhance our abilities to direct and localize the desired energy and information transfer. To achieve the many stunning and amazing 5G and 6G promises, significant advances in antenna and antenna array technologies must be accomplished.
1.1 5G Requirements of Antenna Arrays
One of the most important features of 5G is the