Litcius/Paper detail

A Single-Board Integrated Millimeter-Wave Asymmetric Full-Digital Beamforming Array for B5G/6G Applications

Qingqing Lin, Jun Xu, Kai Chen, Long Wang, Wei Li, Zhiqiang Yu, Guangqi Yang, Jianyi Zhou, Zhe Chen, Jixin Chen, Xiao‐Wei Zhu, Wei Hong

2024Engineering15 citationsDOIOpen Access PDF

Abstract

In this article, a single-board integrated millimeter-wave (mm-Wave) asymmetric full-digital beamforming (AFDBF) array is developed for beyond-fifth-generation (B5G) and sixth-generation (6G) communications. The proposed integrated array effectively addresses the challenge of arranging a large number of ports in a full-digital array by designing vertical connections in a three-dimensional space and successfully integrating full-digital transmitting (Tx) and receiving (Rx) arrays independently in a single board. Unlike the traditional symmetric array, the proposed asymmetric array is composed of an 8 × 8 Tx array arranged in a square shape and an 8 + 8 Rx array arranged in an L shape. The center-to-center distance between two adjacent elements is 0.54λ0 for both the Tx and Rx arrays, where λ0 is the free-space wavelength at 27 GHz. The proposed AFDBF array possesses a more compact structure and lower system hardware cost and power consumption compared with conventional brick-type full-digital arrays. In addition, the energy efficiency of the proposed AFDBF array outperforms that of a hybrid beamforming array. The measurement results indicate that the operating frequency band of the proposed array is 24.25–29.50 GHz. An eight-element linear array within the Tx array can achieve a scanning angle ranging from −47° to +47° in both the azimuth and the elevation planes, and the measured scanning range of each eight-element Rx array is –45° to +45°. The measured maximum effective isotropic radiated power (EIRP) of the eight-element Tx array is 43.2 dBm at 28.0 GHz (considering the saturation point). Furthermore, the measured error vector magnitude (EVM) is less than 3% when 64-quadrature amplitude modulation (QAM) waveforms are used.

Topics & Concepts

Array gainBeamformingAntenna arrayArray data structurePhased arrayCollinear antenna arrayEffective radiated powerSensor arrayAzimuthExtremely high frequencyPower (physics)OpticsAcousticsElectrical engineeringEngineeringElectronic engineeringPhysicsComputer scienceAntenna (radio)Dipole antennaSmart antennaOptoelectronicsQuantum mechanicsMachine learningMillimeter-Wave Propagation and ModelingMicrowave Engineering and WaveguidesPower Line Communications and Noise