Author:

Keywords:

Science & Technology, Technology, Computer Science, Information Systems, Engineering, Electrical & Electronic, Computer Science, Engineering, Signal processing, SDR, Transceiver, Moore's law, Digital intensive, Digital assistance, INTENSIVE HARMONIC REJECTION, RADIO, RECEIVER, RF, CIRCUITS, 0906 Electrical and Electronic Engineering, Computer Hardware & Architecture, Networking & Telecommunications, 4006 Communications engineering, 4008 Electrical engineering, 4611 Machine learning

Abstract:

© 2014, Springer Science+Business Media New York. The ever improving cost advantages and processing capabilities of the technology have been happening according to the so-called Moore’s Law. Although digital circuits can significantly benefit from the aggressive scaling, it is very controversial for analog circuit. However, analog circuit still has to follow the scaling trend because a single chip integration offers key commercial advantages. To optimally achieve the best performance/power/cost tradeoff with deeply scaled technology nodes, there is a clear trend and paradigm shift towards digital intensive and digitally assisted transceivers. Successes of such transceivers have been proven for individual transceiver components and narrow band systems. When targeting emerging communication standards, higher carrier frequencies, further technology scaling and reconfigurable radios, required signal processing design and implementation are orders of magnitudes more challenging but potential gains are promising. Based on a variety of transceiver designs implementing emerging architectures for different sub-6 GHz and 60 GHz communication systems, we will highlight the key challenges and opportunities experienced using 40 nm and 28 nm technology nodes.