A 60-GHz 144-element phased-array transceiver for backhaul application

Tirdad Sowlati; Saikat Sarkar; Bevin George Perumana; Wei Liat Chan; Anna Papio Toda; Bagher Afshar; Michael Boers; Donghyup Shin; Timothy R. Mercer; Wei-Hong Chen; Alfred Grau Besoli; Seunghwan Yoon; Sissy Kyriazidou; Phil Yang; Vipin Aggarwal; Nooshin Vakilian; Dmitriy Rozenblit; Masoud Kahrizi; Joy Zhang; Alan Wang; Padmanava Sen; David Murphy; Ali Sajjadi; Alireza Mehrabani; Evangelos Kornaros; Khim Low; Koji Kimura; Vincent Roussel; Hongyu Xie; Venkat Kodavati

doi:10.1109/JSSC.2018.2874048

A 60-GHz 144-element phased-array transceiver for backhaul application

Tirdad Sowlati^*, Saikat Sarkar, Bevin George Perumana, Wei Liat Chan, Anna Papio Toda, Bagher Afshar, Michael Boers, Donghyup Shin, Timothy R. Mercer, Wei-Hong Chen, Alfred Grau Besoli, Seunghwan Yoon, Sissy Kyriazidou, Phil Yang, Vipin Aggarwal, Nooshin Vakilian, Dmitriy Rozenblit, Masoud Kahrizi, Joy Zhang, Alan WangPadmanava Sen, David Murphy, Ali Sajjadi, Alireza Mehrabani, Evangelos Kornaros, Khim Low, Koji Kimura, Vincent Roussel, Hongyu Xie, Venkat Kodavati

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

114 Citations (Scopus)

Abstract

A 144-element phased array transceiver is realized using a modular tiled approach that supports 802.11ad, MCS12 single carrier 16-quadratic-amplitude modulation (QAM) 4.6 Gbps, in the 60-GHz band. It consists of a system-on-a chip (SOC) (MAC/PHY/BB to IF) in 28-nm CMOS, and one IF-to-60-GHz transceiver master chip driving twelve 60-GHz phased array transceiver slave chips fabricated in a 40-nm CMOS. Using the master-slave configuration, the 60-GHz transceiver with 12 phase-controlled TX/RX slices is expanded to 144 phase-controlled slices. Each final TX/RX slice is then connected to two patch antennas on LTCC substrate. A tiled approach is used to create the 288 patch antenna array out of six identical tiles each with two slave 60-GHz transceivers connected to a 48-element antenna array. The single tile phased array with 48 antennas has a measured beam steering scan angle of 60° in azimuth and 10° in elevation. The full phased array transceiver with 288 antennas has a measured over the air (OTA) max effective isotropic radiated power (EIRP) of 51 dBm at saturated power (PSAT), and EIRP of 44.8 dBm with -22 dB EVM for MCS12 (16QAM-4.6 Gbps) at broadside. It has an OTA measured sensitivity of -87.3 and -80.4 dBm for MCS9 (QPSK-2.5 Gbps) and MCS12, respectively, at broadside. A packet error rate of 10^-5 was measured for MCS9 and MCS12 with an OTA input power of -85 and -77.5 dBm, respectively, for the full phased array transceiver at broadside.

Original language	English
Pages (from-to)	3640-3659
Number of pages	20
Journal	IEEE Journal of Solid-State Circuits
Volume	53
Issue number	12
DOIs	https://doi.org/10.1109/JSSC.2018.2874048
Publication status	Published - Dec 2018
Externally published	Yes

Keywords

60 GHz
802.11ad
CMOS integrated circuits
millimeter-wave integrated circuits
patch antenna arrays
phased array transceivers
RF self-calibration
RF-built-in self-test (RF-BIST)
wireless backhaul
wireless communication

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10.1109/JSSC.2018.2874048

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Sowlati, T., Sarkar, S., Perumana, B. G., Chan, W. L., Papio Toda, A., Afshar, B., Boers, M., Shin, D., Mercer, T. R., Chen, W.-H., Grau Besoli, A., Yoon, S., Kyriazidou, S., Yang, P., Aggarwal, V., Vakilian, N., Rozenblit, D., Kahrizi, M., Zhang, J., ... Kodavati, V. (2018). A 60-GHz 144-element phased-array transceiver for backhaul application. IEEE Journal of Solid-State Circuits, 53(12), 3640-3659. https://doi.org/10.1109/JSSC.2018.2874048

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title = "A 60-GHz 144-element phased-array transceiver for backhaul application",

abstract = "A 144-element phased array transceiver is realized using a modular tiled approach that supports 802.11ad, MCS12 single carrier 16-quadratic-amplitude modulation (QAM) 4.6 Gbps, in the 60-GHz band. It consists of a system-on-a chip (SOC) (MAC/PHY/BB to IF) in 28-nm CMOS, and one IF-to-60-GHz transceiver master chip driving twelve 60-GHz phased array transceiver slave chips fabricated in a 40-nm CMOS. Using the master-slave configuration, the 60-GHz transceiver with 12 phase-controlled TX/RX slices is expanded to 144 phase-controlled slices. Each final TX/RX slice is then connected to two patch antennas on LTCC substrate. A tiled approach is used to create the 288 patch antenna array out of six identical tiles each with two slave 60-GHz transceivers connected to a 48-element antenna array. The single tile phased array with 48 antennas has a measured beam steering scan angle of 60° in azimuth and 10° in elevation. The full phased array transceiver with 288 antennas has a measured over the air (OTA) max effective isotropic radiated power (EIRP) of 51 dBm at saturated power (PSAT), and EIRP of 44.8 dBm with -22 dB EVM for MCS12 (16QAM-4.6 Gbps) at broadside. It has an OTA measured sensitivity of -87.3 and -80.4 dBm for MCS9 (QPSK-2.5 Gbps) and MCS12, respectively, at broadside. A packet error rate of 10-5 was measured for MCS9 and MCS12 with an OTA input power of -85 and -77.5 dBm, respectively, for the full phased array transceiver at broadside.",

keywords = "60 GHz, 802.11ad, CMOS integrated circuits, millimeter-wave integrated circuits, patch antenna arrays, phased array transceivers, RF self-calibration, RF-built-in self-test (RF-BIST), wireless backhaul, wireless communication",

author = "Tirdad Sowlati and Saikat Sarkar and Perumana, \{Bevin George\} and Chan, \{Wei Liat\} and \{Papio Toda\}, Anna and Bagher Afshar and Michael Boers and Donghyup Shin and Mercer, \{Timothy R.\} and Wei-Hong Chen and \{Grau Besoli\}, Alfred and Seunghwan Yoon and Sissy Kyriazidou and Phil Yang and Vipin Aggarwal and Nooshin Vakilian and Dmitriy Rozenblit and Masoud Kahrizi and Joy Zhang and Alan Wang and Padmanava Sen and David Murphy and Ali Sajjadi and Alireza Mehrabani and Evangelos Kornaros and Khim Low and Koji Kimura and Vincent Roussel and Hongyu Xie and Venkat Kodavati",

year = "2018",

month = dec,

doi = "10.1109/JSSC.2018.2874048",

language = "English",

volume = "53",

pages = "3640--3659",

journal = "IEEE Journal of Solid-State Circuits",

issn = "0018-9200",

publisher = "Institute of Electrical and Electronics Engineers (IEEE)",

number = "12",

}

Sowlati, T, Sarkar, S, Perumana, BG, Chan, WL, Papio Toda, A, Afshar, B, Boers, M, Shin, D, Mercer, TR, Chen, W-H, Grau Besoli, A, Yoon, S, Kyriazidou, S, Yang, P, Aggarwal, V, Vakilian, N, Rozenblit, D, Kahrizi, M, Zhang, J, Wang, A, Sen, P, Murphy, D, Sajjadi, A, Mehrabani, A, Kornaros, E, Low, K, Kimura, K, Roussel, V, Xie, H & Kodavati, V 2018, 'A 60-GHz 144-element phased-array transceiver for backhaul application', IEEE Journal of Solid-State Circuits, vol. 53, no. 12, pp. 3640-3659. https://doi.org/10.1109/JSSC.2018.2874048

TY - JOUR

T1 - A 60-GHz 144-element phased-array transceiver for backhaul application

AU - Sowlati, Tirdad

AU - Sarkar, Saikat

AU - Perumana, Bevin George

AU - Chan, Wei Liat

AU - Papio Toda, Anna

AU - Afshar, Bagher

AU - Boers, Michael

AU - Shin, Donghyup

AU - Mercer, Timothy R.

AU - Chen, Wei-Hong

AU - Grau Besoli, Alfred

AU - Yoon, Seunghwan

AU - Kyriazidou, Sissy

AU - Yang, Phil

AU - Aggarwal, Vipin

AU - Vakilian, Nooshin

AU - Rozenblit, Dmitriy

AU - Kahrizi, Masoud

AU - Zhang, Joy

AU - Wang, Alan

AU - Sen, Padmanava

AU - Murphy, David

AU - Sajjadi, Ali

AU - Mehrabani, Alireza

AU - Kornaros, Evangelos

AU - Low, Khim

AU - Kimura, Koji

AU - Roussel, Vincent

AU - Xie, Hongyu

AU - Kodavati, Venkat

PY - 2018/12

Y1 - 2018/12

N2 - A 144-element phased array transceiver is realized using a modular tiled approach that supports 802.11ad, MCS12 single carrier 16-quadratic-amplitude modulation (QAM) 4.6 Gbps, in the 60-GHz band. It consists of a system-on-a chip (SOC) (MAC/PHY/BB to IF) in 28-nm CMOS, and one IF-to-60-GHz transceiver master chip driving twelve 60-GHz phased array transceiver slave chips fabricated in a 40-nm CMOS. Using the master-slave configuration, the 60-GHz transceiver with 12 phase-controlled TX/RX slices is expanded to 144 phase-controlled slices. Each final TX/RX slice is then connected to two patch antennas on LTCC substrate. A tiled approach is used to create the 288 patch antenna array out of six identical tiles each with two slave 60-GHz transceivers connected to a 48-element antenna array. The single tile phased array with 48 antennas has a measured beam steering scan angle of 60° in azimuth and 10° in elevation. The full phased array transceiver with 288 antennas has a measured over the air (OTA) max effective isotropic radiated power (EIRP) of 51 dBm at saturated power (PSAT), and EIRP of 44.8 dBm with -22 dB EVM for MCS12 (16QAM-4.6 Gbps) at broadside. It has an OTA measured sensitivity of -87.3 and -80.4 dBm for MCS9 (QPSK-2.5 Gbps) and MCS12, respectively, at broadside. A packet error rate of 10-5 was measured for MCS9 and MCS12 with an OTA input power of -85 and -77.5 dBm, respectively, for the full phased array transceiver at broadside.

AB - A 144-element phased array transceiver is realized using a modular tiled approach that supports 802.11ad, MCS12 single carrier 16-quadratic-amplitude modulation (QAM) 4.6 Gbps, in the 60-GHz band. It consists of a system-on-a chip (SOC) (MAC/PHY/BB to IF) in 28-nm CMOS, and one IF-to-60-GHz transceiver master chip driving twelve 60-GHz phased array transceiver slave chips fabricated in a 40-nm CMOS. Using the master-slave configuration, the 60-GHz transceiver with 12 phase-controlled TX/RX slices is expanded to 144 phase-controlled slices. Each final TX/RX slice is then connected to two patch antennas on LTCC substrate. A tiled approach is used to create the 288 patch antenna array out of six identical tiles each with two slave 60-GHz transceivers connected to a 48-element antenna array. The single tile phased array with 48 antennas has a measured beam steering scan angle of 60° in azimuth and 10° in elevation. The full phased array transceiver with 288 antennas has a measured over the air (OTA) max effective isotropic radiated power (EIRP) of 51 dBm at saturated power (PSAT), and EIRP of 44.8 dBm with -22 dB EVM for MCS12 (16QAM-4.6 Gbps) at broadside. It has an OTA measured sensitivity of -87.3 and -80.4 dBm for MCS9 (QPSK-2.5 Gbps) and MCS12, respectively, at broadside. A packet error rate of 10-5 was measured for MCS9 and MCS12 with an OTA input power of -85 and -77.5 dBm, respectively, for the full phased array transceiver at broadside.

KW - 60 GHz

KW - 802.11ad

KW - CMOS integrated circuits

KW - millimeter-wave integrated circuits

KW - patch antenna arrays

KW - phased array transceivers

KW - RF self-calibration

KW - RF-built-in self-test (RF-BIST)

KW - wireless backhaul

KW - wireless communication

UR - https://www.scopus.com/pages/publications/85055197698

U2 - 10.1109/JSSC.2018.2874048

DO - 10.1109/JSSC.2018.2874048

M3 - Article

AN - SCOPUS:85055197698

SN - 0018-9200

VL - 53

SP - 3640

EP - 3659

JO - IEEE Journal of Solid-State Circuits

JF - IEEE Journal of Solid-State Circuits

IS - 12

ER -

A 60-GHz 144-element phased-array transceiver for backhaul application

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