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A 37–42-GHz 8 × 8 Phased-Array With 48–51-dBm EIRP, 64–QAM 30-Gb/s Data Rates, and EVM Analysis Versus Channel RMS Errors

Yusheng Yin, Samet Zihir, Tumay Kanar, Qian Ma, Hyunchul Chung, Li Gao, Gabriel M. Rebeiz

2020IEEE Transactions on Microwave Theory and Techniques67 citationsDOI

Abstract

This article presents a 5G 37-42-GHz 8 × 8 phased array. The array is based on 2 × 2 SiGe transmit/receive (TRX) beamformer chips in the SiGe technology with 6 bits of phase control and 8 bits of gain control. A detailed study is presented, showing the effects of array-level amplitude and phase errors on the radiated error vector magnitude (EVM) of 64-element arrays. The array scans to ±60° in the azimuth plane and ±50° in the elevation plane with low sidelobes. The measured peak effective isotropic radiated power (EIRP) is 51 dBm at Psat with a 3-dB bandwidth of 36-41.5 GHz. A 39-GHz communication system is also demonstrated along with a high-pass filter and an integrated upconverter/downconverter and achieves a local oscillator (LO) and image rejection level of 50 dBc, meeting FCC requirements of <; -13 dBm/MHz of total leakage power. The array achieves <; 5% EVM (-26 dB) using a 64-QAM 200-MHz waveform at an average EIRP of 44 dBm over all scan angles, including the LO and upconverter/downconverter contributions. A 30-Gb/s communication link with 64-QAM modulation is also shown. To our knowledge, this is the first demonstration of a 39-GHz phased-array communication system for 5G applications.

Topics & Concepts

Phased arrayEffective radiated powerdBmPhysicsBeamformingQuadrature amplitude modulationElectrical engineeringImage responseBandwidth (computing)EngineeringOpticsElectronic engineeringRadio frequencyBit error rateIntermediate frequencyTelecommunicationsAntenna (radio)Channel (broadcasting)AmplifierMicrowave Engineering and WaveguidesMillimeter-Wave Propagation and ModelingRadio Frequency Integrated Circuit Design
A 37–42-GHz 8 × 8 Phased-Array With 48–51-dBm EIRP, 64–QAM 30-Gb/s Data Rates, and EVM Analysis Versus Channel RMS Errors | Litcius