CLC number: TN92; TN43
On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 2020-01-27
Cited: 0
Clicked: 6341
Citations: Bibtex RefMan EndNote GB/T7714
Yi-Ming Yu , Kai Kang . Analysis and design of transformer-based CMOS ultra-wideband millimeter-wave circuits for wireless applications[J]. Frontiers of Information Technology & Electronic Engineering, 2020, 21(1): 97-115.
@article{title="Analysis and design of transformer-based CMOS ultra-wideband millimeter-wave circuits for wireless applications",
author="Yi-Ming Yu , Kai Kang ",
journal="Frontiers of Information Technology & Electronic Engineering",
volume="21",
number="1",
pages="97-115",
year="2020",
publisher="Zhejiang University Press & Springer",
doi="10.1631/FITEE.1900491"
}
%0 Journal Article
%T Analysis and design of transformer-based CMOS ultra-wideband millimeter-wave circuits for wireless applications
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%A Kai Kang
%J Frontiers of Information Technology & Electronic Engineering
%V 21
%N 1
%P 97-115
%@ 2095-9184
%D 2020
%I Zhejiang University Press & Springer
%DOI 10.1631/FITEE.1900491
TY - JOUR
T1 - Analysis and design of transformer-based CMOS ultra-wideband millimeter-wave circuits for wireless applications
A1 - Yi-Ming Yu
A1 - Kai Kang
J0 - Frontiers of Information Technology & Electronic Engineering
VL - 21
IS - 1
SP - 97
EP - 115
%@ 2095-9184
Y1 - 2020
PB - Zhejiang University Press & Springer
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DOI - 10.1631/FITEE.1900491
Abstract: With a lot of millimeter-wave (mm-Wave) applications being issued, wideband circuits and systems have attracted much attention because of their strong applicability and versatility. In this paper, four transformer-based ultra-wideband mm-Wave circuits demonstrated in CMOS technologies are reviewed from theoretical analysis, implementation, to performance. First, we introduce a mm-Wave low-noise amplifier with transformer-based Gm-boosting and pole-tuning techniques. It achieves wide operating bandwidth, low noise figure, and good gain performance. Second, we review an injection-current-boosting technique which can significantly increase the locking range of mm-Wave injection-locked frequency triplers. Based on the injection locked principle, we also discuss an ultra-wideband mm-Wave divider with the transformer-based high-order resonator. Finally, an E-band up-conversion mixer is presented; using the two-path transconductance stage and transformer-based load, it obtains good linearity and a large operating band.
[1]Byeon CW, Lee JH, Lee DY, et al., 2015. A high linearity, image/LO-rejection I/Q up-conversion mixer for 5G cellular communications. European Microwave Conf, p.345-348.
[2]Chan WL, Long JR, 2008. A 56-65 GHz injection-locked frequency tripler with quadrature outputs in 90-nm CMOS. IEEE J Sol-State Circ, 43(12):2739-2746.
[3]Chao Y, Luong HC, 2013. Analysis and design of a 2.9-mW 53.4-79.4-GHz frequency-tracking injection-locked frequency divider in 65-nm CMOS. IEEE J Sol-State Circ, 48(10):2403-2418.
[4]Chen WL, Shiao YSJ, Yen HD, et al., 2013. A 53.6 GHz direct injection-locked frequency divider with a 72% locking range in 65 nm CMOS technology. IEEE MTT-S Int Microwave Symp Digest, p.1-3.
[5]Chen ZL, Liu HH, Liu ZQ, et al., 2019. A 62-85-GHz high linearity upconversion mixer with 18-GHz IF bandwidth. IEEE Microw Wirel Compon Lett, 29(3):219-221.
[6]Chen ZM, Wang CC, Yao HC, et al., 2012. A BiCMOS W-band 2×2 focal-plane array with on-chip antenna. IEEE J Sol-State Circ, 47(10):2355-2371.
[7]Deng W, Siriburanon T, Musa A, et al., 2013. A sub-harmonic injection-locked quadrature frequency synthesizer with frequency calibration scheme for millimeter-wave TDD transceivers. IEEE J Sol-State Circ, 48(7):1710-1720.
[8]Feng GY, Boon CC, Meng FY, et al., 2017. Pole-converging intrastage bandwidth extension technique for wideband amplifiers. IEEE J Sol-State Circ, 52(3):769-780.
[9]Fritsche D, Tretter G, Carta C, et al., 2015. Millimeter-wave low-noise amplifier design in 28-nm low-power digital CMOS. IEEE Trans Microw Theory Techn, 63(6):1910-1922.
[10]Gao ZZ, Kang K, Zhao CX, et al., 2015. A broadband and equivalent-circuit model for millimeter-wave on-chip M:N six-port transformers and baluns. IEEE Trans Microw Theory Techn, 63(10):3109-3121.
[11]Ghilioni A, Mazzanti A, Svelto F, 2013. Analysis and design of mm-Wave frequency dividers based on dynamic latches with load modulation. IEEE J Sol-State Circ, 48(8):1842-1850.
[12]Guo ST, Xi TZ, Gui P, et al., 2016. A transformer feedback Gm-boosting technique for gain improvement and noise reduction in mm-Wave cascode LNAs. IEEE Trans Microw Theory Techn, 64(7):2080-2090.
[13]Hussein AI, Paramesh J, 2017. Design and self-calibration techniques for inductor-less millimeter-wave frequency dividers. IEEE J Sol-State Circ, 52(6):1521-1541.
[14]Imani A, Hashemi H, 2017. Distributed injection-locked frequency dividers. IEEE J Sol-State Circ, 52(8):2083-2093.
[15]Jang SL, Chang CW, Wun JY, et al., 2011. Quadrature injection-locked frequency dividers using dual-resonance resonator. IEEE Microw Wirel Compon Lett, 21(1):37-39.
[16]Khanzadi MR, Kuylenstierna D, Panahi A, et al., 2014. Calculation of the performance of communication systems from measured oscillator phase noise. IEEE Trans Circ Syst I, 61(5):1553-1565.
[17]Kim HT, Park BS, Song SS, et al., 2018. A 28-GHz CMOS direct conversion transceiver with packaged 2×4 antenna array for 5G cellular system. IEEE J Sol-State Circ, 53(5):1245-1259.
[18]Lee JG, Lee HJ, Kim SH, et al., 2017. 60GHz direct up- conversion mixer with wide IF bandwidth and high linearity in 65nm CMOS. IEEE Int Symp on Radio-Frequency Integration Technology, p.74-76.
[19]Levinger R, Sheinman B, Katz O, et al., 2014. A 71-86GHz multi-tanh up-conversion mixer achieving +1dBm OP1dB in 0.13 μm SiGe technology. IEEE MTT-S Int Microwave Symp, p.1-4.
[20]Li A, Zheng SY, Yin J, et al., 2014. A 21-48 GHz subharmonic injection-locked fractional-N frequency synthesizer for multiband point-to-point backhaul communications. IEEE J Sol-State Circ, 49(8):1785-1799.
[21]Li XY, Shekhar S, Allstot DJ, 2005. Gm-boosted common-gate LNA and differential colpitts VCO/QVCO in 0.18-μm CMOS. IEEE J Sol-State Circ, 40(12):2609-2619.
[22]Lin BL, Liu SI, 2011. Analysis and design of D-band injection-locked frequency dividers. IEEE J Sol-State Circ, 45(6): 1250-1264.
[23]Lin YH, Wang H, 2016. A 35.7-64.2 GHz low power Miller divider with weak inversion mixer in 65 nm CMOS. IEEE Microw Wirel Compon Lett, 26(11):948-950.
[24]Lin YS, Wen WC, Wang CC, 2014. 13.6 mW 79 GHz CMOS up-conversion mixer with 2.1 dB gain and 35.9 dB LO-RF isolation. IEEE Microw Wirel Compon Lett, 24(2): 126-128.
[25]Liu G, Schumacher H, 2013. Broadband millimeter-wave LNAs (47-77 GHz and 70-140 GHz) using a T-type matching topology. IEEE J Sol-State Circ, 48(9):2022-2029.
[26]Liu ZQ, Dong JY, Chen ZL, et al., 2018. A 62-90 GHz high linearity and low noise CMOS mixer using transformer-coupling cascode topology. IEEE Access, 6:19338-19344.
[27]Luo TN, Chen YJE, 2008. A 0.8-mW 55-GHz dual-injection-locked CMOS frequency divider. IEEE Trans Microw Theory Techn, 56(3):620-625.
[28]Mangraviti G, Khalaf K, Parvais B, et al., 2015. Design and tuning of coupled-LC mm-wave subharmonically injection-locked oscillators. IEEE Trans Microw Theory Techn, 63(7):2301-2312.
[29]Razavi B, 2004. A study of injection locking and pulling in oscillators. IEEE J Sol-State Circ, 39(9):1415-1424.
[30]Razavi B, 2011. RF Microelectronics (2nd Ed.). Prentice-Hall, Englewood Cliffs, NJ, USA.
[31]Reynaert P, Steyaert W, Standaert A, et al., 2017. mm-Wave and THz circuit design in standard CMOS technologies: challenges and opportunities. IEEE Asia Pacific Microwave Conf, p.85-88.
[32]Rong S, Luong HC, 2010. A 0.8 V 57 GHz-to-72 GHz differential input frequency divider with locking range optimization in 0.13-μm CMOS. Proc IEEE Asian Solid-State Circuits Conf, p.1-4.
[33]Sadhu B, Ferriss M, Valdes-Garcia A, 2015. A 52 GHz frequency synthesizer featuring a 2nd harmonic extraction technique that preserves VCO performance. IEEE J Sol-State Circ, 50(5):1214-1223.
[34]Shahramian S, Baeyens Y, Kaneda N, et al., 2013. A 70–100 GHz direct-conversion transmitter and receiver phased array chipset demonstrating 10 Gb/s wireless link. IEEE J Sol-State Circ, 48(5):1113-1125.
[35]Shin D, Koh KJ, 2018. An injection frequency-locked loop— autonomous injection frequency tracking loop with phase noise self-calibration for power-efficient mm-wave signal sources. IEEE J Sol-State Circ, 53(3):825-838.
[36]Takatsu K, Tamura H, Yamamoto T, et al., 2010. A 60-GHz 1.65mW 25.9% locking range multi-order LC oscillator based injection locked frequency divider in 65 nm CMOS. Proc IEEE Custom Integrated Circuits Conf, p.1-4.
[37]Vigilante M, Reynaert P, 2016a. Analysis and design of an E-band transformer-coupled low-noise quadrature VCO in 28-nm CMOS. IEEE Trans Microw Theory Techn, 64(4):1122-1132.
[38]Vigilante M, Reynaert P, 2016b. 20.10 A 68.1-to-96.4 GHz variable-gain low-noise amplifier in 28nm CMOS. IEEE Int Solid-State Circuits Conf, p.360-361.
[39]Vigilante M, Reynaert P, 2018. A wideband class-AB power amplifier with 29-57-GHz AM–PM compensation in 0.9-V 28-nm bulk CMOS. IEEE J Sol-State Circ, 53(5): 1288-1301.
[40]Won YS, Kim CH, Lee SC, 2015. A 24 GHz highly linear up-conversion mixer in CMOS 0.13 μm technology. IEEE Microw Wirel Compon Lett, 25(6):400-402.
[41]Wu QY, Quach T, Mattamana A, et al., 2013. A 10mW 37.8GHz current-redistribution BiCMOS VCO with an average FOMT of −193.5dBc/Hz. IEEE Int Solid-State Circuits Conf Digest of Technical Papers, p.150-151.
[42]Yanay N, Socher E, 2015. Wide tuning-range mm-wave voltage-controlled oscillator employing an artificial magnetic transmission line. IEEE Trans Microw Theory Techn, 63(4):1342-1352.
[43]Yao T, Gordon MQ, Tang KKW, et al., 2007. Algorithmic design of CMOS LNAs and PAs for 60-GHz radio. IEEE J Sol-State Circ, 42(5):1044-1057.
[44]Yeh HC, Chiong CC, Aloui S, et al., 2012. Analysis and design of millimeter-wave low-voltage CMOS cascode LNA with magnetic coupled technique. IEEE Trans Microw Theory Techn, 60(12):4066-4079.
[45]Yoo S, Choi S, Kim J, et al., 2018. A low-integrated-phase noise 27-30-GHz injection-locked frequency multiplier with an ultra-low-power frequency-tracking loop for mm-wave-band 5G transceivers. IEEE J Sol-State Circ, 53(2): 375-388.
[46]Yu YM, Liu HH, Wu YQ, et al., 2017. A 54.4-90 GHz low-noise amplifier in 65-nm CMOS. IEEE J Sol-State Circ, 52(11):2892-2904.
[47]Zhang JZ, Cheng YX, Zhao CX, et al., 2018. Analysis and design of ultra-wideband mm-wave injection-locked frequency dividers using transformer-based high-order resonators. IEEE J Sol-State Circ, 53(8):2177-2189.
[48]Zhang JZ, Liu HH, Wu YQ, et al., 2019. An injection- current-boosting locking-range enhancement technique for ultra-wideband mm-wave injection-locked frequency triplers. IEEE Trans Microw Theory Techn, 67(7):3174-3186.
[49]Zong ZR, Babaie M, Staszewski RB, 2016. A 60 GHz frequency generator based on a 20 GHz oscillator and an implicit multiplier. IEEE J Sol-State Circ, 51(5):1261-1273.
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