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4.3 A 28GHz 4-Element MIMO Beam-Space Array in 65nm CMOS with Simultaneous Spatial Filtering and Single-Wire Frequency-Domain Multiplexing

Robin Garg, Gaurav Sharma, Ali Binaie, Sanket Jain, Sohail Ahasan, Armagan Dascurcu, Harish Krishnaswamy, Arun Natarajan

202042 citationsDOI

Abstract

High-data-rate wireless links at mm-wave have motivated the development of scalable, dense arrays with hundreds of elements [1], [2]. The evolution from “multiple-input-single-output” phased arrays towards multibeam/MIMO arrays presents significant challenges. Firstly, increasing the number of beamforming blocks and outputs to preserve signals from every element increases IC area and makes compact on-package signal routing challenging. This limits a scalable unit-tile approach with λ/2 ×λ /2 spacing. Secondly, it is important to include spatial filtering in such MIMO arrays to mitigate blockers and reduce ADC dynamic-range requirements (Fig. 4.3.1) [4]-[6]. Thirdly, traditional digital beamforming requires the full aggregate IF interface bandwidth and all ADCs to operate irrespective of the number of beams. Given dynamic operating environments, it is desirable to have array architectures that support power-scalable configurability from phased-arrays to multibeam arrays to full-field-of-view (FoV) MIMO arrays.

Topics & Concepts

MIMOBeamformingSpatial multiplexingElectronic engineeringBandwidth (computing)Computer scienceMultiplexingScalabilityPhased arrayCMOSDynamic rangeEngineeringAntenna (radio)TelecommunicationsDatabaseAntenna Design and OptimizationMicrowave Engineering and WaveguidesRadio Frequency Integrated Circuit Design