Towards Energy Efficient Mobile Wireless Receivers Above 100 GHz

Wireless communication above 100 GHz offers the potential for massive data rates and has attracted considerable attention for Beyond 5G and 6G systems. A key challenge in the receiver design in these bands is power consumption, particularly for mobile and portable devices. This paper provides a gene...

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Veröffentlicht in:	IEEE access 2021, Vol.9, p.20704-20716
Hauptverfasser:	Skrimponis, Panagiotis, Hosseinzadeh, Navid, Khalili, Abbas, Erkip, Elza, Rodwell, Mark J. W., Buckwalter, James F., Rangan, Sundeep
Format:	Artikel
Sprache:	eng
Schlagworte:	Analog to digital converters Array signal processing Circuit design Critical components Design standards Electronic devices Energy efficiency Low noise millimeter wave Mixers mobile communication Noise reduction nonlinear systems Optimization optimization methods Portable equipment Power consumption Power demand Power management power optimization Radio frequency Receivers Receiving antennas Signal to noise ratio Terahertz Wireless communications
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description	Wireless communication above 100 GHz offers the potential for massive data rates and has attracted considerable attention for Beyond 5G and 6G systems. A key challenge in the receiver design in these bands is power consumption, particularly for mobile and portable devices. This paper provides a general methodology for understanding the trade-offs of power consumption and end-to-end performance of a large class of potential receivers for these frequencies. The framework is applied to the design of a fully digital 140 GHz receiver with a 2 GHz sample rate, targeted for likely 6G cellular applications. Design options are developed for key RF components including the low noise amplifier (LNA), mixer, local oscillator (LO) and analog-digital converter (ADC) in 90 nm SiGe BiCMOS. The proposed framework, combined with detailed circuit and system simulations, is then used to select among the design options for the overall optimal end-to-end performance and power tradeoff. The analysis reveals critical design choices and bottlenecks. It is shown that optimizing these critical components can enable a dramatic 70 to 80% power reduction relative to a standard baseline design enabling fully-digital 140 GHz receivers with RF power consumption less than 2 W.
doi_str_mv	10.1109/ACCESS.2020.3044849
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subjects	Analog to digital converters Array signal processing Circuit design Critical components Design standards Electronic devices Energy efficiency Low noise millimeter wave Mixers mobile communication Noise reduction nonlinear systems Optimization optimization methods Portable equipment Power consumption Power demand Power management power optimization Radio frequency Receivers Receiving antennas Signal to noise ratio Terahertz Wireless communications
title	Towards Energy Efficient Mobile Wireless Receivers Above 100 GHz
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