[1] Jacomb-Hood A, Lier E. Multibeam active phased arrays for communications satellites[J]. IEEE Microwave Magazine, 1, 40-47(2000).

[2] Brookner E. Phased array radars-past, present and future[C], 104-113(2002).

[3] Hong W, Jiang Z H, Yu C et al. Multibeam antenna technologies for 5G wireless communications[J]. IEEE Transactions on Antennas and Propagation, 65, 6231-6249(2017).

[4] Huang J. Crucial integration technology of T/R module for millimeter-wave active phased array[J]. Telecommunication Engineering, 51, 1-6(2011).

[5] Zhou Z P. Millimeter wave active phased array antenna technology[J]. Journal of Microwaves, 34, 1-5(2018).

[6] Xiao C Y, Zhang B, Liu G et al. Highly integrated active phased array antenna[J]. Journal of Microwaves, 34, 1-5(2018).

[7] He L T, Zhang K F, Hu J Y. Thermal design of millimeter-wave active phased array antenna[J]. Machinery and Electronics, 36, 23-27(2018).

[8] Herd J S, Conway M D. The evolution to modern phased array architectures[J]. Proceedings of the IEEE, 104, 519-529(2016).

[9] Zhang Y P, Liu D. Antenna-on-chip and antenna-in-package solutions to highly integrated millimeter-wave devices for wireless communications[J]. IEEE Transactions on Antennas and Propagation, 57, 2830-2841(2009).

[10] Khalilsarai M B, Yang T, Haghighatshoar S et al. Dual-polarized FDD massive MIMO: a comprehensive framework[J]. IEEE Transactions on Wireless Communications, 21, 840-854(2022).

[11] Zihir S, Gurbuz O D, Kar-Roy A et al. 60-GHz 64- and 256-elements wafer-scale phased-array transmitters using full-reticle and subreticle stitching tchniques[J]. IEEE Transactions on Microwave Theory and Techniques, 64, 4701-4719(2016).

[12] Kodak U, Rupakula B, Zihir S et al. 60-GHz 64- and 256-element dual-polarized dual-beam wafer-scale phased-array transceivers with reticle-to-reticle stitching[J]. IEEE Transactions on Microwave Theory and Techniques, 68, 2745-2767(2020).

[13] Li S, Zhang Z, Rupakula B et al. An eight-element 140-GHz wafer-scale IF beamforming phased-array receiver with 64-QAM operation in CMOS RFSOI[J]. IEEE Journal of Solid-State Circuits, 57, 385-399(2022).

[14] Cohen E, Ruberto M, Cohen M et al. A CMOS bidirectional 32-element phased-array transceiver at 60 GHz with LTCC antenna[J]. IEEE Transactions on Microwave Theory and Techniques, 61, 1359-1375(2013).

[15] Sowlati T, Sarkar S, Perumana B et al. A 60GHz 144-element phased-array transceiver with 51dBm maximum EIRP and ±60° beam steering for backhaul application[C], 66-68(2018).

[16] Gu X, Liu D, Baks C et al. Development, implementation, and characterization of a 64-element dual-polarized phased-array antenna module for 28-GHz high-speed data communications[J]. IEEE Transactions on Microwave Theory and Techniques, 67, 2975-2984(2019).

[17] Rupakula B, Zihir S, Rebeiz G M. Low complexity 54–63-GHz transmit/receive 64- and 128-element 2-D-scanning phased-arrays on multilayer organic substrates with 64-QAM 30-Gbps data rates[J]. IEEE Transactions on Microwave Theory and Techniques, 67, 5268-5281(2019).

[18] Yin Y, Zihir S, Kanar T et al. A 37–42-GHz 8 × 8 phased-array with 48–51-dBm EIRP, 64–QAM 30-Gb/s data rates, and EVM analysis versus channel RMS errors[J]. IEEE Transactions on Microwave Theory and Techniques, 68, 4753-4764(2020).

[19] Aljuhani A H, Kanar T, Zihir S et al. A 256-element Ku-band polarization agile SATCOM transmit phased array with wide-scan angles, low cross polarization, deep nulls, and 36.5-dBW EIRP per polarization[J]. IEEE Transactions on Microwave Theory and Techniques, 69, 2594-2608(2021).

[20] Balanis C[M]. Antenna theory analysis and design, 800-805(2016).

[21] Liu N W, Zhu L, Choi W W et al. A low-profile aperture-coupled microstrip antenna with enhanced bandwidth under dual resonance[J]. IEEE Transactions on Antennas and Propagation, 65, 1055-1062(2017).

[22] Xia R L. Research on wide-angle wideband scanning phased array antennas[D](2017).

[23] Granholm J, Woelders K. Dual polarization stacked microstrip patch antenna array with very low cross-polarization[J]. IEEE Transactions on Antennas and Propagation, 49, 1393-1402(2001).