Your search keyword '"Yi, Yongran"' showing total 3 results

1. A 24–29.5-GHz Highly Linear Phased-Array Transceiver Front-End in 65-nm CMOS Supporting 800-MHz 64-QAM and 400-MHz 256-QAM for 5G New Radio.

Author

Yi, Yongran, Zhao, Dixian, Zhang, Jiajun, Gu, Peng, Chai, Yuan, Liu, Huiqi, and You, Xiaohu

Subjects

FREQUENCY modulation transmitters, TRANSMITTERS (Communication), ORTHOGONAL frequency division multiplexing, 5G networks, INSERTION loss (Telecommunication), PHASE shifters, POWER amplifiers

Abstract

This article presents a four-element phased-array transceiver (TRX) front-end for millimeter-wave (mm-Wave) 5G new radio (NR). The effects of amplitude-to-phase (AM–PM) and amplitude-to-amplitude (AM–AM) distortions on error vector magnitude (EVM) are detailed. A three-stage highly linear wideband class-AB power amplifier (PA) is described, mitigating AM–PM and AM–AM distortions without degrading other performances. A matching network embedded transmitting/receiving (T/R) switch is proposed to support time division duplex (TDD). With the proposed technique, RF switch insertion losses are reduced in both transmitter (TX) and receiving (RX) modes. In each TRX element, phase and gain controls are achieved by a 6-bit vector-modulated phase shifter (VMPS) with a phase tuning range of 360° and a 6-bit attenuator with a gain tuning range of 31.5 dB, respectively. Fabricated in 65-nm bulk CMOS, the proposed packaged TRX demonstrates the measured peak gains of 25.5/14.2 dB with the gain ripples of less than 2.5/1.9 dB across 24–29.5 GHz in the TX/RX mode. The measured peak $P_{\text {1 dB}}$ is 17.6 dBm with a power added efficiency (PAE) of 20.4%. The measured minimum noise figure (NF) is 4.3 dB. The TRX achieves an output power of 7.9–8.9 dBm and an EVM of −25 dB with 8 $\times $ 100-MHz 5G NR frequency range 2 (FR2) orthogonal frequency division multiplexing (OFDM) 64-quadrature amplitude modulation (QAM) signals across 24–29.5 GHz, covering 3rd generation partnership project (3GPP) 5G NR FR2 operating bands (i.e., n257, n258, and n261) around 26 GHz. [ABSTRACT FROM AUTHOR]

Published

2022

2. Millimeter-Wave Integrated Phased Arrays.

Author

Zhao, Dixian, Gu, Peng, Zhong, Jiecheng, Peng, Na, Yang, Mengru, Yi, Yongran, Zhang, Jiajun, He, Pingyang, Chai, Yuan, Chen, Zhihui, and You, Xiaohu

Subjects

PHASED array antennas, TELECOMMUNICATION satellites, MASS production, BROADBAND antennas, PHASE shifters, INDUSTRIAL costs

Abstract

Large-scale millimeter-wave (mm-Wave) integrated phased array is the key technology to enable broadband 5G and satellite communications. This paper details the design considerations, challenges and trade-offs of mm-Wave integrated phased arrays based on bulk CMOS and multi-layer hybrid PCB technologies. Both technologies attain high yield and low cost for mass production. Important beamforming building blocks are addressed and compared in detail. Demonstrators of integrated phased arrays are presented from circuit to board levels. The 1024- and 4096-element integrated phased arrays achieve the EIRP of 72.5 and 84.0 dBm respectively. Finally, relevant phased-array transceivers and antennas from the recent literature are discussed. [ABSTRACT FROM AUTHOR]

Published

2021

3. Corrections to “Millimeter-Wave Integrated Phased Arrays” [early access, Jul 12, 21 doi: 10.1109/TCSI.2021.3093093].

Author

Zhao, Dixian, Gu, Peng, Zhong, Jiecheng, Peng, Na, Yang, Mengru, Yi, Yongran, Zhang, Jiajun, He, Pingyang, Chai, Yuan, Chen, Zhihui, and You, Xiaohu

Subjects

PHASED array antennas, PHASE shifters, TELECOMMUNICATION satellites, MILLIMETER waves, INTEGRATING circuits

Abstract

In the above article , Table III makes the comparison between the phase shifters with different topologies. The work in is referred in the comparison table, which presents the designs of two active vector-modulated phase shifters (VMPS). In , one of the presented test chips is with relatively small chip size and the other shows increased gain. In Table III of the work in , only the design with small chip size is included. For the completeness of the comparison, the performances of both designs are now shown in. [ABSTRACT FROM AUTHOR]

Published

2021