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This book addresses the true innovation in engineering design that may be promoted by blending together models and methodologies from different disciplines, and, in this book, the target was exactly to follow this approach to deliver a new disruptive architecture to deliver these next-generation mobile small cell technologies. According to this design philosophy, the work within this book resides in the intersection of engineering paradigms that includes “cooperation”, “network coding”, and “smart energy-aware frontends”. These technologies will not only be considered as individual building blocks, but re-engineered according to an inter-design approach resulting in the enabler for energy efficient femtocell-like services on the move. The book aims to narrow the gap between the current networking technologies and the foreseen requirements that are targeted at the future development of the 5G mobile and wireless communications networks in terms of the higher networking capacity, the ability to support more users, the lower cost per bit, the enhanced energy efficiency, and adaptability to new services and devices (for example, smart cities, and the Internet of things (IoT)).

History of engineering & technology --- microstrip --- tuneable filter --- microwave filter --- 5G --- MEMSs --- varactor --- 4G --- CR --- MIMO --- reconfigurable antenna --- switch --- UWB --- WiMAX --- WLAN --- wireless communications --- cooperative NOMA --- multi-points DF relaying nodes --- half-duplex --- full-duplex --- Rayleigh fading channels --- Nakagami-m fading channels --- energy harvesting --- non-orthogonal multiple access --- multiple antenna --- transmit antenna selection --- outage probability --- pattern reconfigurable --- patch antenna --- s-parameters --- frequency reconfigurable --- dual-band Doherty power amplifier --- LTE-advanced --- high-efficiency --- phase offset lines --- impedance inverter network --- phase compensation network --- High power amplifiers --- high efficiency --- Doherty power amplifier --- GaN-HEMT --- small cell --- maximum transmit power --- UE --- open-loop power control --- interference --- ergodic capacity --- non-linear energy harvesting --- NOMA --- monopole antenna --- S-parameters --- 5G, 4/4.5G --- LTE --- ISM --- WiFi --- 5G antenna --- slot antenna --- mobile terminal antenna --- MIMO antenna --- medical applications --- miniaturized antenna --- arc-shaped --- dual-band --- chiral --- Tellegen --- multilayer CPW structure --- dispersion characteristics --- full-GEMT --- Muller’s method --- complex propagation constant --- acceleration procedure --- ISM 2.4 GHz --- isolation --- envelope correlation coefficient (ECC) --- channel capacity loss (CCL) --- 5G technology --- CPW-fed antenna --- diversity antenna --- future smartphones --- MIMO systems --- n/a --- Muller's method

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

This book addresses the true innovation in engineering design that may be promoted by blending together models and methodologies from different disciplines, and, in this book, the target was exactly to follow this approach to deliver a new disruptive architecture to deliver these next-generation mobile small cell technologies. According to this design philosophy, the work within this book resides in the intersection of engineering paradigms that includes “cooperation”, “network coding”, and “smart energy-aware frontends”. These technologies will not only be considered as individual building blocks, but re-engineered according to an inter-design approach resulting in the enabler for energy efficient femtocell-like services on the move. The book aims to narrow the gap between the current networking technologies and the foreseen requirements that are targeted at the future development of the 5G mobile and wireless communications networks in terms of the higher networking capacity, the ability to support more users, the lower cost per bit, the enhanced energy efficiency, and adaptability to new services and devices (for example, smart cities, and the Internet of things (IoT)).

microstrip --- tuneable filter --- microwave filter --- 5G --- MEMSs --- varactor --- 4G --- CR --- MIMO --- reconfigurable antenna --- switch --- UWB --- WiMAX --- WLAN --- wireless communications --- cooperative NOMA --- multi-points DF relaying nodes --- half-duplex --- full-duplex --- Rayleigh fading channels --- Nakagami-m fading channels --- energy harvesting --- non-orthogonal multiple access --- multiple antenna --- transmit antenna selection --- outage probability --- pattern reconfigurable --- patch antenna --- s-parameters --- frequency reconfigurable --- dual-band Doherty power amplifier --- LTE-advanced --- high-efficiency --- phase offset lines --- impedance inverter network --- phase compensation network --- High power amplifiers --- high efficiency --- Doherty power amplifier --- GaN-HEMT --- small cell --- maximum transmit power --- UE --- open-loop power control --- interference --- ergodic capacity --- non-linear energy harvesting --- NOMA --- monopole antenna --- S-parameters --- 5G, 4/4.5G --- LTE --- ISM --- WiFi --- 5G antenna --- slot antenna --- mobile terminal antenna --- MIMO antenna --- medical applications --- miniaturized antenna --- arc-shaped --- dual-band --- chiral --- Tellegen --- multilayer CPW structure --- dispersion characteristics --- full-GEMT --- Muller’s method --- complex propagation constant --- acceleration procedure --- ISM 2.4 GHz --- isolation --- envelope correlation coefficient (ECC) --- channel capacity loss (CCL) --- 5G technology --- CPW-fed antenna --- diversity antenna --- future smartphones --- MIMO systems --- n/a --- Muller's method