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J. Semicond. > 2024, Volume 45?>?Issue 1?> 012201

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A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS

Yongran Yi^{1, 2}, Dixian Zhao^{1, 2,} , Jiajun Zhang³, Peng Gu^{1, 2}, Chenyu Xu^{1, 2}, Yuan Chai³, Huiqi Liu^{1, 3} and Xiaohu You^{1, 2,}

+ Author Affiliations + Find other works by these authors

• 1. National Mobile Communication Research Laboratory, Southeast University, Nanjing 211189, ChinaNational Mobile Communication Research Laboratory, Southeast University, Nanjing 211189, China
• 2. Purple Mountain Laboratories, Nanjing 211111, ChinaPurple Mountain Laboratories, Nanjing 211111, China
• 3. Chengdu Xphased Technology Company Ltd., Chengdu 610041, ChinaChengdu Xphased Technology Company Ltd., Chengdu 610041, China

Author Bio:

• Yongran Yi (Graduate Student Member, IEEE) received a BS degree in Information Science and Engineering from Southeast University, Nanjing, China, in 2017, where he is currently pursuing a PhD degree. His current research interests include millimeter-wave integrated circuits, transceivers, and phased array systems for 5G and SATCOM applications.
• Dixian Zhao (Member, IEEE) received a BSc degree in Microelectronics from Fudan University, Shanghai, China, in 2006, a MSc degree in Microelectronics from Delft University of Technology (TU Delft), the Netherlands, in 2009, and a PhD degree in Electrical Engineering at University of Leuven (KU Leuven), Belgium, in 2015. Since April 2015, he has joined Southeast University, China, where he is now a full professor. His current research interests include millimeter-wave integrated circuits, transceivers, and phased-array systems for 5G, satellite, radar, and wireless power transfer applications.
• Xiaohu You (Fellow, IEEE) received a MS and PhD degrees in Electrical Engineering from Southeast University, Nanjing, China, in 1985 and 1988, respectively. Since 2013, he has been the Principal Investigator of the China National 863 5G Project. He has contributed over 200 IEEE journal articles and two books in the areas of adaptive signal processing and neural networks and their applications to communication systems. His research interests include mobile communication systems, and signal processing and its applications.

• Yongran Yi
• Dixian Zhao
• Jiajun Zhang
• Peng Gu
• Chenyu Xu
• Yuan Chai
• Huiqi Liu
• Xiaohu You

 Corresponding author: Dixian Zhao, dixian.zhao@seu.edu.cn; Xiaohu You, xhyu@seu.edu.cn

DOI: 10.1088/1674-4926/45/1/012201

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Abstract: This article presents an 8-element dual-polarized phased-array transceiver (TRX) front-end IC for millimeter-wave (mm-Wave) 5G new radio (NR). Power enhancement technologies for power amplifiers (PA) in mm-Wave 5G phased-array TRX are discussed. A four-stage wideband high-power class-AB PA with distributed-active-transformer (DAT) power combining and multi-stage second-harmonic traps is proposed, ensuring the mitigated amplitude-to-phase (AM-PM) distortions across wide carrier frequencies without degrading transmitting (TX) power, gain and efficiency. TX and receiving (RX) switching is achieved by a matching network co-designed on-chip T/R switch. In each TRX element, 6-bit 360° phase shifting and 6-bit 31.5-dB gain tuning are respectively achieved by the digital-controlled vector-modulated phase shifter (VMPS) and differential attenuator (ATT). Fabricated in 65-nm bulk complementary metal oxide semiconductor (CMOS), the proposed TRX demonstrates the measured peak TX/RX gains of 25.5/21.3 dB, covering the 24?29.5 GHz band. The measured peak TX OP1dB and power-added efficiency (PAE) are 20.8 dBm and 21.1%, respectively. The measured minimum RX NF is 4.1 dB. The TRX achieves an output power of 11.0?12.4 dBm and error vector magnitude (EVM) of 5% with 400-MHz 5G NR FR2 OFDM 64-QAM signals across 24?29.5 GHz, covering 3GPP 5G NR FR2 operating bands of n257, n258, and n261.

Key words: fifth-generation (5G), power amplifier, millimeter-wave, transceiver, phased-array

References

[1]	Yi Y R, Zhao D X, Zhang J J, et al. 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. IEEE J Solid-State Circuits, 2022, 57, 2702 doi: 10.1109/JSSC.2022.3169588
[2]	Pang J, Li Z, Luo X T, et al. A CMOS dual-polarized phased-array beamformer utilizing cross-polarization leakage cancellation for 5G MIMO systems. IEEE J Solid-State Circuits, 2021, 56, 1310 doi: 10.1109/JSSC.2020.3045258
[3]	Park H C, Kang D, Lee S M, et al. 4.1 A 39GHz-band CMOS 16-channel phased-array transceiver IC with a companion dual-stream IF transceiver IC for 5G NR base-station applications. 2020 IEEE International Solid-State Circuits Conference-(ISSCC), San Francisco, CA, USA, 2020, 76 doi: 10.1109/ISSCC19947.2020.9063006
[4]	Dunworth J D, Homayoun A, Ku B H, et al. A 28GHz bulk-CMOS dual-polarization phased-array transceiver with 24 channels for 5G user and basestation equipment. 2018 IEEE International Solid-State Circuits Conference-(ISSCC), San Francisco, CA, USA, 2018, 70 doi: 10.1109/ISSCC.2018.8310188
[5]	Sadhu B, Paidimarri A, Liu D X, et al. A 24–30-GHz 256-element dual-polarized 5G phased array using fast on-chip beam calculators and magnetoelectric dipole antennas. IEEE J Solid-State Circuits, 2022, 57, 3599 doi: 10.1109/JSSC.2022.3204807
[6]	Verma A, Bhagavatula V, Singh A, et al. A 16-channel, 28/39GHz dual-polarized 5G FR2 phased-array transceiver IC with a quad-stream IF transceiver supporting non-contiguous carrier aggregation up to 1.6GHz BW. 2022 IEEE International Solid-State Circuits Conference (ISSCC), San Francisco, CA, USA, 2022, 1 doi: 10.1109/ISSCC42614.2022.9731664
[7]	Zhao D X, Gu P, Zhong J C, et al. Millimeter-wave integrated phased arrays. IEEE Trans Circuits Syst I, 2021, 68, 3977 doi: 10.1109/TCSI.2021.3093093
[8]	Wang Y, Wu R, Pang J, et al. A 39-GHz 64-element phased-array transceiver with built-In phase and amplitude calibrations for large-array 5G NR in 65-nm CMOS. IEEE J Solid-State Circuits, 2020, 55, 1249 doi: 10.1109/JSSC.2020.2980509
[9]	Liu H Q, Zhao D X, Yi Y R, et al. A 24.25-27.5 GHz 128-element dual-polarized 5G integrated phased array with 5.6%-EVM 400-MHz 64-QAM and 50-dBm EIRP. Sci China Inf Sci, 2022, 65, 214301 doi: 10.1007/s11432-022-3584-6
[10]	3GPP Specification series. Technical specification 38.104 (V17.6. 0) base station (BS) radio transmission and reception.
[11]	Haldi P, Chowdhury D, Reynaert P, et al. A 5.8 GHz 1 V linear power amplifier using a novel on-chip transformer power combiner in standard 90 nm CMOS. IEEE J Solid-State Circuits, 2008, 43, 1054 doi: 10.1109/JSSC.2008.920347
[12]	Aoki I, Kee S D, Rutledge D B, et al. Distributed active transformer-a new power-combining and impedance-transformation technique. IEEE Trans Microw Theory Tech, 2002, 50, 316 doi: 10.1109/22.981284
[13]	Aoki I, Kee S D, Rutledge D B, et al. Fully integrated CMOS power amplifier design using the distributed active-transformer architecture. IEEE J Solid-State Circuits, 2002, 37, 371 doi: 10.1109/4.987090
[14]	Yao T, Gordon M Q, Tang K K W, et al. Algorithmic design of CMOS LNAs and PAs for 60-GHz radio. IEEE J Solid-State Circuits, 2007, 42, 1044 doi: 10.1109/JSSC.2007.894325
[15]	Li Q, Zhang Y P. CMOS T/R switch design: Towards ultra-wideband and higher frequency. IEEE J Solid-State Circuits, 2007, 42, 563 doi: 10.1109/JSSC.2006.891442
[16]	Long J R. Monolithic transformers for silicon RF IC design. IEEE J Solid-State Circuits, 2000, 35, 1368 doi: 10.1109/4.868049
[17]	Gu P, Zhao D X, You X H. A DC-50 GHz CMOS switched-type attenuator with capacitive compensation technique. IEEE Trans Circuits Syst I, 2020, 67, 3389 doi: 10.1109/TCSI.2020.2999094
[18]	Park J S, Wang H. A transformer-based poly-phase network for ultra-broadband quadrature signal generation. IEEE Trans Microw Theory Tech, 2015, 63, 4444 doi: 10.1109/TMTT.2015.2496187

Fig. 1.  (Color online) (a) Beam squint of the phased array across different pointed beam angles and (b) ?1-dB and ?3-dB beamwidth of URA with respect to the number of elements.

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Fig. 2.  (Color online) Power-combining PA in TRX: (a) series-combining in TX mode, (b) parallel-combining in TX mode, (c) series-combining in RX mode and (d) parallel-combining in RX mode.

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Fig. 3.  (Color online) The series-combing power amplifier based on the distributed-active transformer.

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Fig. 4.  (Color online) Schematic of differential four-stage two-way power-combining power amplifier.

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Fig. 5.  (Color online) Schematic of the power amplifier output stage in common mode.

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Fig. 6.  (Color online) Simulated AM–PM of the proposed cascode cell across frequencies.

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Fig. 7.  (Color online) Schematic of the DAT power-combining network.

DownLoad: Full-Size Img PowerPoint

Fig. 8.  (Color online) Schematics of (a) the low-noise amplifier and the T/R switch and (b) the three-stacked resistive body-floating switch transistor M_SWT.

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Fig. 9.  (Color online) Simplified power amplifier AC model in RX mode.

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Fig. 10.  (Color online) RX leakage contours with different L_S1 and Q_LS1.

DownLoad: Full-Size Img PowerPoint

Fig. 11.  (Color online) EM-simulated (a) S21 and OP1dB of PA, (b) S21 and NF of LNA.

DownLoad: Full-Size Img PowerPoint

Fig. 12.  (Color online) Block diagram of the mm-Wave 5G 8-element dual-polarized phased-array TRX IC.

DownLoad: Full-Size Img PowerPoint

Fig. 13.  Simplified schematic of the 6-bit differential switched attenuator.

DownLoad: Full-Size Img PowerPoint

Fig. 14.  (Color online) Schematic of the 6-bit differential vector modulated phase shifter.

DownLoad: Full-Size Img PowerPoint

Fig. 15.  (Color online) Phase-invariant VGA in the I/Q paths of the VMPS.

DownLoad: Full-Size Img PowerPoint

Fig. 16.  (Color online) A micrograph of the mm-Wave 5G 8-element dual-polarized phased-array transceiver IC.

DownLoad: Full-Size Img PowerPoint

Fig. 17.  (Color online) Small-signal CW measurement results in TX mode: (a) S-parameters. (b) Phase shifting. (c) Gain tuning.

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Fig. 18.  (Color online) Small-signal CW measurement results in RX mode: (a) S-parameters. (b) Phase shifting. (c) Gain tuning.

DownLoad: Full-Size Img PowerPoint

Fig. 19.  (Color online) Large-signal measurement results in TX mode: (a) OP1dB and P_sat. (b) PAE. (c) Output power in 5G NR FR2 64-QAM and 256-QAM signals.

DownLoad: Full-Size Img PowerPoint

Fig. 20.  (Color online) Measured constellations, EVM and spectrum with 400-MHz 5G NR FR2 OFDM signal in TX mode: (a) 64-QAM and (b) 256-QAM.

DownLoad: Full-Size Img PowerPoint

Table 1.   Comparison of state-of-the-art silicon-based phased-array TRX IC for mm-Wave 5G.

	This work	SEU JSSC’22[1]	Tokyo Tech. JSSC’21[2]	Samsung ISSCC’20[3]	Qualcomm ISSCC’18[4]	IBM ISSCC’22[5]
Technology	65 nm CMOS	65 nm CMOS	65 nm CMOS	28 nm CMOS	28 nm CMOS	130 nm SiGe BiCMOS
Frequency (GHz)	24?29.5	24?29.5	28	37?40	26.5?29.5	24?30
Integration	8CH TRX	4CH TRX	8CH TRX	16CH TRX	24CH TRX	16CH TRX
Supply (V)	1.0/1.8	1.0/1.8	1.0	0.9/1.8	1.0/1.8	1.5/2.7
TX gain (dB)	22.5?25.5	23.0?25.5	25	60a	34?44	25?31
TX Psat (dBm)	20.3?21.2	16.8?18.0	16.1	16.5	14	16.9?17.1
TX P1dB (dBm)	19.2?20.8	16.0?17.6	13.7	N/A	12	15.9?16.1
TX PAEmax (%)	22.0	20.8	N/A	N/A	20	22.1?23.9
TX PAE1dB (%)	21.1	20.4	N/A	N/A	N/A	N/A
TX PDC/CH (mW)	568(@P1dB)	272(@P1dB)	186(@Psat)	105(@6dBm)	119(@11dBm)	200(@Psat)
RX gain (dB)	19.5?21.3	12.3?14.2	18	59a	32?34	29?30
RX NF (dB)	4.1?5.2	4.3?6.0	4.9 (28 GHz)	4.2?4.6	3.8?4.6	3?3.8
RX PDC/CH (mW)	89	82	88	39	42	90
Gain range (dB)	31.5	31.5	8	30a (T)/43a (R)	7(T)/9(R)	20(T)/27(R)
Gain step (dB)	0.5	0.5	0.5	1	1	0.25
RMS gain error (dB)	0.21?0.34(TX) 0.16?0.26(RX)	<0.35(TX) <0.22(RX)	N/A	N/A	N/A	N/A
Phase step (°)	5.625(6 bits)	5.625(6 bits)	11.25(5 bits)	22.5(4 bits)	45(3 bits)	<5.6(~6 bits)
RMS phase error (°)	0.8?2.4(TX) 0.6?2.5(RX)	<1.9(TX) <1.8(RX)	2	3.3	N/A	1.2
a Conversion gain.

DownLoad: CSV

[1]	Yi Y R, Zhao D X, Zhang J J, et al. 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. IEEE J Solid-State Circuits, 2022, 57, 2702 doi: 10.1109/JSSC.2022.3169588
[2]	Pang J, Li Z, Luo X T, et al. A CMOS dual-polarized phased-array beamformer utilizing cross-polarization leakage cancellation for 5G MIMO systems. IEEE J Solid-State Circuits, 2021, 56, 1310 doi: 10.1109/JSSC.2020.3045258
[3]	Park H C, Kang D, Lee S M, et al. 4.1 A 39GHz-band CMOS 16-channel phased-array transceiver IC with a companion dual-stream IF transceiver IC for 5G NR base-station applications. 2020 IEEE International Solid-State Circuits Conference-(ISSCC), San Francisco, CA, USA, 2020, 76 doi: 10.1109/ISSCC19947.2020.9063006
[4]	Dunworth J D, Homayoun A, Ku B H, et al. A 28GHz bulk-CMOS dual-polarization phased-array transceiver with 24 channels for 5G user and basestation equipment. 2018 IEEE International Solid-State Circuits Conference-(ISSCC), San Francisco, CA, USA, 2018, 70 doi: 10.1109/ISSCC.2018.8310188
[5]	Sadhu B, Paidimarri A, Liu D X, et al. A 24–30-GHz 256-element dual-polarized 5G phased array using fast on-chip beam calculators and magnetoelectric dipole antennas. IEEE J Solid-State Circuits, 2022, 57, 3599 doi: 10.1109/JSSC.2022.3204807
[6]	Verma A, Bhagavatula V, Singh A, et al. A 16-channel, 28/39GHz dual-polarized 5G FR2 phased-array transceiver IC with a quad-stream IF transceiver supporting non-contiguous carrier aggregation up to 1.6GHz BW. 2022 IEEE International Solid-State Circuits Conference (ISSCC), San Francisco, CA, USA, 2022, 1 doi: 10.1109/ISSCC42614.2022.9731664
[7]	Zhao D X, Gu P, Zhong J C, et al. Millimeter-wave integrated phased arrays. IEEE Trans Circuits Syst I, 2021, 68, 3977 doi: 10.1109/TCSI.2021.3093093
[8]	Wang Y, Wu R, Pang J, et al. A 39-GHz 64-element phased-array transceiver with built-In phase and amplitude calibrations for large-array 5G NR in 65-nm CMOS. IEEE J Solid-State Circuits, 2020, 55, 1249 doi: 10.1109/JSSC.2020.2980509
[9]	Liu H Q, Zhao D X, Yi Y R, et al. A 24.25-27.5 GHz 128-element dual-polarized 5G integrated phased array with 5.6%-EVM 400-MHz 64-QAM and 50-dBm EIRP. Sci China Inf Sci, 2022, 65, 214301 doi: 10.1007/s11432-022-3584-6
[10]	3GPP Specification series. Technical specification 38.104 (V17.6. 0) base station (BS) radio transmission and reception.
[11]	Haldi P, Chowdhury D, Reynaert P, et al. A 5.8 GHz 1 V linear power amplifier using a novel on-chip transformer power combiner in standard 90 nm CMOS. IEEE J Solid-State Circuits, 2008, 43, 1054 doi: 10.1109/JSSC.2008.920347
[12]	Aoki I, Kee S D, Rutledge D B, et al. Distributed active transformer-a new power-combining and impedance-transformation technique. IEEE Trans Microw Theory Tech, 2002, 50, 316 doi: 10.1109/22.981284
[13]	Aoki I, Kee S D, Rutledge D B, et al. Fully integrated CMOS power amplifier design using the distributed active-transformer architecture. IEEE J Solid-State Circuits, 2002, 37, 371 doi: 10.1109/4.987090
[14]	Yao T, Gordon M Q, Tang K K W, et al. Algorithmic design of CMOS LNAs and PAs for 60-GHz radio. IEEE J Solid-State Circuits, 2007, 42, 1044 doi: 10.1109/JSSC.2007.894325
[15]	Li Q, Zhang Y P. CMOS T/R switch design: Towards ultra-wideband and higher frequency. IEEE J Solid-State Circuits, 2007, 42, 563 doi: 10.1109/JSSC.2006.891442
[16]	Long J R. Monolithic transformers for silicon RF IC design. IEEE J Solid-State Circuits, 2000, 35, 1368 doi: 10.1109/4.868049
[17]	Gu P, Zhao D X, You X H. A DC-50 GHz CMOS switched-type attenuator with capacitive compensation technique. IEEE Trans Circuits Syst I, 2020, 67, 3389 doi: 10.1109/TCSI.2020.2999094
[18]	Park J S, Wang H. A transformer-based poly-phase network for ultra-broadband quadrature signal generation. IEEE Trans Microw Theory Tech, 2015, 63, 4444 doi: 10.1109/TMTT.2015.2496187

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Received: 29 June 2023 Revised: 17 August 2023 Online: Uncorrected proof: 04 December 2023Published: 10 January 2024

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Article Navigation >  Journal of Semiconductors  > 2024  >  45(1): 012201

Yongran Yi, Dixian Zhao, Jiajun Zhang, Peng Gu, Chenyu Xu, Yuan Chai, Huiqi Liu, Xiaohu You. A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS[J]. Journal of Semiconductors, 2024, 45(1): 012201. doi: 10.1088/1674-4926/45/1/012201 ****Y R Yi, D X Zhao, J J Zhang, P Gu, C Y Xu, Y Chai, H Q Liu, X H You. A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS[J]. J. Semicond, 2024, 45(1): 012201. doi: 10.1088/1674-4926/45/1/012201

Citation:

Yongran Yi, Dixian Zhao, Jiajun Zhang, Peng Gu, Chenyu Xu, Yuan Chai, Huiqi Liu, Xiaohu You. A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS[J]. Journal of Semiconductors, 2024, 45(1): 012201. doi: 10.1088/1674-4926/45/1/012201 **** Y R Yi, D X Zhao, J J Zhang, P Gu, C Y Xu, Y Chai, H Q Liu, X H You. A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS[J]. J. Semicond, 2024, 45(1): 012201. doi: 10.1088/1674-4926/45/1/012201

Yongran Yi, Dixian Zhao, Jiajun Zhang, Peng Gu, Chenyu Xu, Yuan Chai, Huiqi Liu, Xiaohu You. A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS[J]. Journal of Semiconductors, 2024, 45(1): 012201. doi: 10.1088/1674-4926/45/1/012201 ****Y R Yi, D X Zhao, J J Zhang, P Gu, C Y Xu, Y Chai, H Q Liu, X H You. A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS[J]. J. Semicond, 2024, 45(1): 012201. doi: 10.1088/1674-4926/45/1/012201

Citation:

Yongran Yi, Dixian Zhao, Jiajun Zhang, Peng Gu, Chenyu Xu, Yuan Chai, Huiqi Liu, Xiaohu You. A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS[J]. Journal of Semiconductors, 2024, 45(1): 012201. doi: 10.1088/1674-4926/45/1/012201 **** Y R Yi, D X Zhao, J J Zhang, P Gu, C Y Xu, Y Chai, H Q Liu, X H You. A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS[J]. J. Semicond, 2024, 45(1): 012201. doi: 10.1088/1674-4926/45/1/012201

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A 24?30 GHz 8-element dual-polarized 5G FR2 phased-array transceiver IC with 20.8-dBm TX OP1dB and 4.1-dB RX NFin 65-nm CMOS

DOI: 10.1088/1674-4926/45/1/012201

• Yongran Yi^{1, 2}, 
• Dixian Zhao^{1, 2,}  , 
• Jiajun Zhang³, 
• Peng Gu^{1, 2}, 
• Chenyu Xu^{1, 2}, 
• Yuan Chai³, 
• Huiqi Liu^{1, 3}, 
• Xiaohu You^{1, 2,} 

• 1.

  National Mobile Communication Research Laboratory, Southeast University, Nanjing 211189, China

• 2.

  Purple Mountain Laboratories, Nanjing 211111, China

• 3.

  Chengdu Xphased Technology Company Ltd., Chengdu 610041, China

More Information

• Yongran Yi (Graduate Student Member, IEEE) received a BS degree in Information Science and Engineering from Southeast University, Nanjing, China, in 2017, where he is currently pursuing a PhD degree. His current research interests include millimeter-wave integrated circuits, transceivers, and phased array systems for 5G and SATCOM applications
• Dixian Zhao (Member, IEEE) received a BSc degree in Microelectronics from Fudan University, Shanghai, China, in 2006, a MSc degree in Microelectronics from Delft University of Technology (TU Delft), the Netherlands, in 2009, and a PhD degree in Electrical Engineering at University of Leuven (KU Leuven), Belgium, in 2015. Since April 2015, he has joined Southeast University, China, where he is now a full professor. His current research interests include millimeter-wave integrated circuits, transceivers, and phased-array systems for 5G, satellite, radar, and wireless power transfer applications
• Xiaohu You (Fellow, IEEE) received a MS and PhD degrees in Electrical Engineering from Southeast University, Nanjing, China, in 1985 and 1988, respectively. Since 2013, he has been the Principal Investigator of the China National 863 5G Project. He has contributed over 200 IEEE journal articles and two books in the areas of adaptive signal processing and neural networks and their applications to communication systems. His research interests include mobile communication systems, and signal processing and its applications
• Corresponding author: dixian.zhao@seu.edu.cn; xhyu@seu.edu.cn
• Received Date: 2023-06-29
  
• Revised Date: 2023-08-17
Available Online: 2023-12-04

Abstract

• Abstract

  This article presents an 8-element dual-polarized phased-array transceiver (TRX) front-end IC for millimeter-wave (mm-Wave) 5G new radio (NR). Power enhancement technologies for power amplifiers (PA) in mm-Wave 5G phased-array TRX are discussed. A four-stage wideband high-power class-AB PA with distributed-active-transformer (DAT) power combining and multi-stage second-harmonic traps is proposed, ensuring the mitigated amplitude-to-phase (AM-PM) distortions across wide carrier frequencies without degrading transmitting (TX) power, gain and efficiency. TX and receiving (RX) switching is achieved by a matching network co-designed on-chip T/R switch. In each TRX element, 6-bit 360° phase shifting and 6-bit 31.5-dB gain tuning are respectively achieved by the digital-controlled vector-modulated phase shifter (VMPS) and differential attenuator (ATT). Fabricated in 65-nm bulk complementary metal oxide semiconductor (CMOS), the proposed TRX demonstrates the measured peak TX/RX gains of 25.5/21.3 dB, covering the 24?29.5 GHz band. The measured peak TX OP1dB and power-added efficiency (PAE) are 20.8 dBm and 21.1%, respectively. The measured minimum RX NF is 4.1 dB. The TRX achieves an output power of 11.0?12.4 dBm and error vector magnitude (EVM) of 5% with 400-MHz 5G NR FR2 OFDM 64-QAM signals across 24?29.5 GHz, covering 3GPP 5G NR FR2 operating bands of n257, n258, and n261.

   

  Keywords:
  • fifth-generation (5G), 
  • power amplifier, 
  • millimeter-wave, 
  • transceiver, 
  • phased-array
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References(18)

• References

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• Fig. 1. (Color online) (a) Beam squint of the phased array across different pointed beam angles and (b) ?1-dB and ?3-dB beamwidth of URA with respect to the number of elements.
• Fig. 2. (Color online) Power-combining PA in TRX: (a) series-combining in TX mode, (b) parallel-combining in TX mode, (c) series-combining in RX mode and (d) parallel-combining in RX mode.
• Fig. 3. (Color online) The series-combing power amplifier based on the distributed-active transformer.
• Fig. 4. (Color online) Schematic of differential four-stage two-way power-combining power amplifier.
• Fig. 5. (Color online) Schematic of the power amplifier output stage in common mode.
• Fig. 6. (Color online) Simulated AM–PM of the proposed cascode cell across frequencies.
• Fig. 7. (Color online) Schematic of the DAT power-combining network.
• Fig. 8. (Color online) Schematics of (a) the low-noise amplifier and the T/R switch and (b) the three-stacked resistive body-floating switch transistor M_SWT.
• Fig. 9. (Color online) Simplified power amplifier AC model in RX mode.
• Fig. 10. (Color online) RX leakage contours with different L_S1 and Q_LS1.
• Fig. 11. (Color online) EM-simulated (a) S21 and OP1dB of PA, (b) S21 and NF of LNA.
• Fig. 12. (Color online) Block diagram of the mm-Wave 5G 8-element dual-polarized phased-array TRX IC.
• Fig. 13. Simplified schematic of the 6-bit differential switched attenuator.
• Fig. 14. (Color online) Schematic of the 6-bit differential vector modulated phase shifter.
• Fig. 15. (Color online) Phase-invariant VGA in the I/Q paths of the VMPS.
• Fig. 16. (Color online) A micrograph of the mm-Wave 5G 8-element dual-polarized phased-array transceiver IC.
• Fig. 17. (Color online) Small-signal CW measurement results in TX mode: (a) S-parameters. (b) Phase shifting. (c) Gain tuning.
• Fig. 18. (Color online) Small-signal CW measurement results in RX mode: (a) S-parameters. (b) Phase shifting. (c) Gain tuning.
• Fig. 19. (Color online) Large-signal measurement results in TX mode: (a) OP1dB and P_sat. (b) PAE. (c) Output power in 5G NR FR2 64-QAM and 256-QAM signals.
• Fig. 20. (Color online) Measured constellations, EVM and spectrum with 400-MHz 5G NR FR2 OFDM signal in TX mode: (a) 64-QAM and (b) 256-QAM.