MIMO Processing for 4G and Beyond

"Preface: Evolution of Wireless Systems--The Roots of MIMO and its Future In the transmission of information over a wireless channel the channel is modeled classically as a linear system black box with an input and output, that is, a single input and a single output (SISO). The input is the connection point from the power amplifier of the transmitter to the transmitting antenna terminal and the output is the connection point from the receiving antenna terminal to the radio frequency (RF) front-end filterof the receiver. The antennas are modeled as a structure that radiates EM waves that propagate through space. The simplest such antenna structure is a radiating electric dipole element. With the presence of multipath propagation in the channel it becomesevident that the electric field at the receiver location undergoes variations in amplitude over distances in space in the order of a wavelength. As a result, variations of the classical wireless channel were employed, where multiple receiving antenna elements were introduced, or in other words, antenna structures with multiple interconnection points to the receiver. These antennas were designed to achieve the so-called receiver diversity. The channel could then be modeled as having a single input and multiple outputs, or in the current terminology SIMO (single input multiple output). Classical receiver techniques to process the multiple outputs were referred to as combining techniques"--

Auteur

Mário Marques da Silva is an associate professor at the Universidade Autónoma de Lisboa, and a researcher at Instituto de Telecomunicações in Lisbon, Portugal. He received his BSc in electrical engineering in 1992, and MSc and PhD in telecommunications/electrical engineering in 1999 and 2005, respectively, both from Instituto Superior Técnico, University of Lisbon.

Between 2005 and 2008, he was with NATO Air Command Control & Management Agency (NACMA) in Brussels (Belgium), where he managed the deployable communications of the new Air Command and Control System Program. He has been involved in several telecommunications projects. His research interests include networking and mobile communications, namely, block transmission techniques (OFDM, SC-FDE), interference cancellation, spacetime coding, MIMO systems, smart and adaptive antennas, channel estimation, software defined radio, IP technologies, and network security. Mário Marques da Silva is also a Cisco certified CCNA instructor.

He has authored books such as Multimedia Communications and Networking (CRC Press), Transmission Techniques for Emergent Multicast and Broadcast Systems (CRC Press), and Transmission Techniques for 4G Systems (CRC Press), as well as authored several dozens of journal and conference papers. He is a member of IEEE and AFCEA, as well as reviewer for a number of international scientific IEEE journals and conferences. Finally, he has chaired many conference sessions and has been serving in the organizing committee of relevant EURASIP and IEEE conferences.

Francisco A. Monteiro is an assistant professor at ISCTEUniversity Institute of Lisbon and a researcher at Instituto de Telecomunicações in Lisbon, Portugal. In the past, he has been a teaching assistant at the Department of Electrical and Computer Engineering at Instituto Superior Técnico, University of Lisbon. He obtained his PhD in engineering from the University of Cambridge, United Kingdom, in 2012, and had previously received both the Licenciatura degree and an MSc in electrical and computer engineering from Instituto Superior Técnico, University of Lisbon, in 1999 and 2003, respectively. His research has always been focused on signal processing for wireless communications. He acts as a frequent reviewer for a number of IEEE journals and conferences, and has been serving in the organizing committee of relevant EURASIP and IEEE conferences.

In 2008, Dr. Monteiro was a visiting researcher at the Department of Electrical and Computer Engineering of the University of Toronto for four months, with scholarships from the Royal Academy of Engineering, the Calouste Gulbenkian Foundation and the Cambridge Philosophical Society. At Cambridge, he was a member of Fitzwilliam College (where he received a College Senior Scholarship in 2007/2008), and carried out his research in the Digital Technology Group at the Computer Laboratory, while being affiliated with the Department of Engineering. He received the Best Paper Award (Conference Prize) at the European Conference on Wireless Technology 2007 in Munich, Germany. He was also awarded the Young Engineer Best Paper Award at the European Conference on Wireless Technology 2004, in Amsterdam, the Netherlands. His MSc thesis was awarded 3rd place at the Innovation Young Engineer Competition presented by the Portuguese Engineers Institution in 2002.

Dr. Monteiro is a member of several societies of the IEEE, a life member of Fitzwilliam College, a Fellow of the Cambridge Philosophical Society, a junior member of the Isaac Newton Institute for Mathematical Sciences, and a life member of student societies for the promotion of science and technology (namely, the Trinity Mathematical Society, and the Cambridge University Scientific Society).

Texte du rabat

This book offers a cutting-edge look at multiple-input multiple-output (MIMO) signal processing, namely its detection and precoding. It examines its combination with OFDM, UWB, and CDMA, along with the impact of these combinations at the system level. Massive MIMO and network coding at the physical layer are very recent topics which are also addressed. The book presents the work of contributing authors from first-class institutions who are highly cited in the MIMO field. These experts examine ongoing R&D activities in the field of MIMO systems and its associated signal processing that is expected to be employed in 4G and 5G systems.

Résumé

MIMO Processing for 4G and Beyond: Fundamentals and Evolution offers a cutting-edge look at multiple-input multiple-output (MIMO) signal processing, namely its detection (in both time and frequency domains) and precoding. It examines its integration with OFDM, UWB, and CDMA, along with the impact of these combinations at the system level. Massive MIMO and network coding at the physical layer are very recent topics which are also addressed, and which are expected to play an important role in 5G systems.

The book brings together contributing authors from first-class institutions who have been working in international research and development (R&D) projects and are highly cited in the MIMO field. These experts examine ongoing R&D activities in the field of MIMO systems and its associated signal processing that is expected to be employed in 4G and 5G systems.

• Covers the various wireless communication standards that make use of MIMO systems
• Explains the receiver processing associated with MIMO signal detection (including the case of massive MIMO systems) and presents the optimal precoding techniques
• Considers optimized MIMO schemes and processing for block transmission techniques, for orthogonal frequency division multiplexing (OFDM) transmission techniques, and for single carrier-frequency domain equalization
• Examines MIMO processing and optimization for wideband code division multiple access (WCDMA)
• Describes the ultra-wideband (UWB) transmission technique and the corresponding MIMO processing and optimizations
• Explains physical layer network coding techniques From basic receiver design to more advanced processing, the book covers the spectrum of topics associated with MIMO systems and MIMO processing. It provides a comprehensive description of MIMO fundamentals and theory that is ideal for anyone looking to sharpen their skills on the subject, such as corporate/industrial employees or graduate students.

The book summarizes the most impor…