Journal ArticleDOI
Low Insertion Loss, Compact 4-bit Phase Shifter in 65 nm CMOS for 5G Applications
Gyeong-Seop Shin,Jae-Sun Kim,Hyun-Myung Oh,Sunkyu Choi,Chul Woo Byeon,Ju Ho Son,Lee Jeongho,Choul-Young Kim +7 more
TLDR
In this paper, the authors presented a 28 GHz low insertion loss and compact size 4-bit phase shifter in 65 nm CMOS technology, which is composed of two types of passive phase shifters, high-pass/low-pass type and switched filter type.Abstract:
This letter presents a 28 GHz low insertion loss and compact size 4-bit phase shifter in 65 nm CMOS Technology. In order to get low insertion loss and compact size, this phase shifter is composed of two types of passive phase shifters, high-pass/low-pass type and switched filter type. Various techniques are used such as triple well body-floating, gate-floating, removal of capacitance of the off-state transistor using resonant inductor, and minimized interconnection line which is based on matching network. This phase shifter has 6.36 dB of average insertion loss over the 27.5–28.35 GHz, and loss variation is about 2 dB. The return loss is higher than 12 dB, RMS phase error is 8.98 $^{\circ}$ , OIP3 is 8.1 dBm at $-$ 10 dBm input power and its core size is 636 $\mu$ m $\times$ 360 $\mu$ m. To the authors' knowledge, these results are the state of the art in CMOS passive phase shifters in K-band frequency.read more
Citations
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Journal ArticleDOI
A 28-GHz CMOS Phased-Array Transceiver Based on LO Phase-Shifting Architecture With Gain Invariant Phase Tuning for 5G New Radio
Jian Pang,Rui Wu,Yun Wang,Masato Dome,Hisashi Kato,Hongye Huang,Aravind Tharayil Narayanan,Hanli Liu,Bangan Liu,Takeshi Nakamura,Takuya Fujimura,Masaru Kawabuchi,Ryo Kubozoe,Tsuyoshi Miura,Daiki Matsumoto,Zheng Li,Naoki Oshima,Keiichi Motoi,Shinichi Hori,Kazuaki Kunihiro,Tomoya Kaneko,Atsushi Shirane,Kenichi Okada +22 more
TL;DR: The proposed transceiver is based on the local-oscillator (LO) phase-shifting architecture, and it achieves quasi-continuous phase tuning with less than 0.2-dB radio frequency (RF) gain variation and 0.3°C phase error.
Journal ArticleDOI
A 28-GHz Low-Power Phased-Array Receiver Front-End With 360° RTPS Phase Shift Range
Robin Garg,Arun Natarajan +1 more
TL;DR: In this paper, a low-power 28 GHz phased-array receiver (RX) front end is presented that incorporates a low power low-noise amplifier (LNA) and a passive reflection-type phase shifter (RTPS) capable of 360° phase shift with 5b phase resolution and low gain variation.
Journal ArticleDOI
A 6-bit CMOS Active Phase Shifter for Ku -Band Phased Arrays
TL;DR: In this paper, a 6-bit active phase shifter was developed in 0.13-μm-m$ CMOS technology for Ku-band phased arrays, where an improved transformer balun with wriggly stub is applied to split the single input to differential and achieve high balance with reduced chip area.
Journal ArticleDOI
A 0.53-THz Subharmonic Injection-Locked Phased Array With 63- $\mu$ W Radiated Power in 40-nm CMOS
TL;DR: The proposed phased array achieves −12-dBm radiated power and 0.24‰ dc-to-terahertz (THz) efficiency without the use of silicon lens, quartz superstrate, or substrate thinning.
Journal ArticleDOI
Millimeter-Wave Integrated Phased Arrays
Dixian Zhao,Peng Gu,Jiecheng Zhong,Na Peng,Mengru Yang,Yongran Yi,Jiajun Zhang,Pingyang He,Yuan Chai,Chen Zhihui,Xiaohu You +10 more
TL;DR: The design considerations, challenges and trade-offs of mm-Wave integrated phased arrays based on bulk CMOS and multi-layer hybrid PCB technologies, which attain high yield and low cost for mass production are detailed.
References
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Journal ArticleDOI
Millimeter wave propagation: spectrum management implications
Michael J. Marcus,B. Pattan +1 more
TL;DR: The characteristics of millimeter wave propagation, including free space propagation and the effects of various physical factors on propagation, are reviewed in this article, where the authors show that these characteristics are not necessarily disadvantageous and that they can permit more densely packed communications links, thus providing very efficient spectrum utilization, and they can increase security of communication transmissions.
Journal ArticleDOI
Single-Ended and Differential Ka-Band BiCMOS Phased Array Front-Ends
Byung-Wook Min,Gabriel M. Rebeiz +1 more
TL;DR: Single-ended and differential phased array front-ends developed for Ka-band applications using a 0.12 mum SiGe BiCMOS process are competitive with GaAs and InP designs, and are building blocks for low-cost millimeter-wave phased arrayFront-ends based on silicon technology.
Journal ArticleDOI
Single and Four-Element $Ka$ -Band Transmit/Receive Phased-Array Silicon RFICs With 5-bit Amplitude and Phase Control
TL;DR: In this article, a single and four-element SiGe BiCMOS single-and multi-element phased array with 5-bit phase and amplitude control is presented, which is based on the All-RF architecture with RF phase shifters and attenuators and a 4:1 passive power combining/dividing network.
Journal ArticleDOI
A compact 5-bit phase-shifter MMIC for K-band satellite communication systems
Charles F. Campbell,S.A. Brown +1 more
TL;DR: In this article, the design and performance of a compact K-band 5-bit phase-shifter monolithic microwave integrated circuit (MMIC) is presented, and extensive electromagnetic simulation and compact circuit design techniques are employed to yield an MMIC with a 1.693 mm/spl times/0.750 mm (1.27 mm/sup 2/) die size.
Journal ArticleDOI
Sources of Phase Error and Design Considerations for Silicon-Based Monolithic High-Pass/Low-Pass Microwave Phase Shifters
TL;DR: In this article, a comprehensive analysis of error sources in monolithic microwave phase shifters due to device size limitations, inductor parasitics, loading effects, and nonideal switches is presented.
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A 28-GHz Low-Power Phased-Array Receiver Front-End With 360° RTPS Phase Shift Range
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