Laser Technology, Volume. 48, Issue 5, 719(2024)
Study of reconfigurable microwave photonics multi-beamforming technology
References(29)
[1] [1] MAILLOUX R J. Phased array antenna handbook[M]. 2nd ed. Norwood (MA), USA: Artech House Co, 2017: 1-79.
[2] [2] BALANIS C A. Antenna theory: Analysis and design[M]. 3rd ed. Hoboken (NJ), USA: Wiley, 2005: 1-5.
[3] [3] SEEDS A J, WILLIAMS K J. Microwave photonics[J]. Journal of Lightwave Technology, 2007, 24(12): 4628-4641.
[4] [4] YAO J P. Microwave photonics[J]. Journal of Lightwave Technology, 2009, 27(3): 314-335.
[5] [5] JOSé C, NOVAK D. Microwave photonics combines two worlds[J]. Nature Photonics, 2007, 1(6): 319-330.
[6] [6] HONG W, JIANG Zh H, YU Ch, et al. Multibeam antenna technologies for 5G wireless communications[J]. IEEE Transactions on Antennas and Propagation, 2017, 65(12): 6231-6249.
[7] [7] YEGNANARAYANAN S, TRINH P D, COPPINGER F, et al. Compact silicon-based integrated optic time delays[J]. IEEE Photonics Technology Letters, 1997, 9(5): 634-635.
[8] [8] HOWLEY B, WANG X L, CHEN M, et al. Reconfigurable delay time polymer planar lightwave circuit for an X-band phased-array antenna demonstration[J]. Journal of Lightwave Technology, 2007, 25(3): 883-890.
[9] [9] TSOKOS C, MYLONAS E, GROUMAS P, et al. Optical beamforming network for multi-beam operation with continuous angle selection[J]. IEEE Photonics Technology Letters, 2019, 31(2): 177-180.
[10] [10] CHENG Q M, ZHENG Sh L, ZHANG Q, et al. An integrated optical beamforming network for two-dimensional phased array radar[J]. Optics Communications, 2021, 489: 126809.
[11] [11] LIN D D, SHI Sh Q, CHENG W, et al. A high performance silicon nitride optical delay line with good expansibility[J]. Journal of Lightwave Technology, 2023, 41(1): 209-217.
[12] [12] MEIJERINK A, ROELOFFZEN C G H, MEIJERINK R, et al. Novel ring resonator-based integrated photonic beamformer for broadband phased array receive antennas—part Ⅰ: Design and performance analysis[J]. Journal of Lightwave Technology, 2010, 28(1): 3-18.
[13] [13] ZHUANG L M, ROELOFFZEN C G H, MEIJERINK A, et al. Novel ring resonator-based integrated photonic beamformer for broadband phased array receive antennas—part Ⅱ: Experimental prototype[J]. Journal of Lightwave Technology, 2010, 28(1): 19-31.
[14] [14] XUE X X, XUAN Y, BAO Ch Y, et al. Microcomb-based true-time-delay network for microwave beamforming with arbitrary beam pattern control[J]. Journal of Lightwave Technology, 2018, 36(12): 2312-2321.
[15] [15] WANG G Ch, DAI T G, JIANG J F, et al. Continuously tunable true-time delay lines based on a one-dimensional grating waveguide for beam steering in phased array antennas[J]. Applied Optics, 2018, 57(18): 4998-5003.
[17] [17] ZHANG X B, ZHAO M Y, JIAO Y Q, et al. integrated wavelength-tuned optical mm-wave beamformer with doubled delay resolution[J]. Journal of Lightwave Technology, 2020, 38(8): 2353-2359.
[18] [18] YARON L, ROTMAN R, ZACH S, et al. Photonic beamformer receiver with multiple beam capabilities[J]. IEEE Photonics Technology Letters, 2010, 22(23): 1723-1725.
[19] [19] ZHAO J, YANG F, DING Z, et al. Configurable photonic true-time delay network and its application in multi-beamforming[J]. Laser Physics Letters, 2019, 16(12): 126203.
[20] [20] SANTACRUZ J P, ROMMEL S, ROELOFFZEN C G H, et al. Incoherent optical beamformer for AROF fronthaul in mm-wave 5G/6G networks[J]. Journal of Lightwave Technology, 2023, 41(5): 1325-1334.
[21] [21] SONG Q Q, HU Zh F, CHEN K X. Scalable and reconfigurable true time delay line based on an ultra-low-loss silica waveguide[J]. Applied Optics, 2018, 57(16): 4434-4439.
[22] [22] SHAFI M, MOLISCH A F, SMITH P J, et al. 5G: A tutorial overview of standards, trials, challenges, deployment, and practice[J]. IEEE Journal on Selected Areas in Communications, 2017, 35(6): 1201-1221.
[23] [23] BENES V E. Mathematical theory of connecting networks and telephone traffic[M]. New York, USA: Academic Press, 1965.
[24] [24] SPANKE R A, BENES V E. N-stage planar optical permutation network[J]. Applied Optics, 1987, 26(7): 1226-1229.
[25] [25] HINTON H S. A nonblocking optical interconnection network using directional couplers[DB/OL].(1984-01)[2023-11-23]. https://www.researchgate.net/publication/243674935_A_Nonblocking_Optical_Interconnection_Network_Using_Directional_Couplers.
[26] [26] SULIMAN F M, MOHAMMAD A B, SEMAN K. A new nonblocking photonic switching network[C]// GLOBECOM’01. IEEE Global Telecommunications Conference. San Antonio, TX, USA: IEEE, 2001, 4: 2071-2076.
[27] [27] SULIMAN F M, MOHAMMAD A B, SEMAN K. A space dilated lightwave network-a new approach[C]// 10th International Conference on Telecommunications, 2003. Papeete, France: IEEE, 2003: 1675-1679.
[28] [28] LU Ch Ch, THOMPSON R A. The double-layer network architecture for photonic switching[J]. Journal of Lightwave Technology, 1994, 12(8): 1482-1489.
[29] [29] SPANKE R. Architectures for large nonblocking optical space switches[J]. IEEE Journal of Quantum Electronics, 1986, 22(6): 964-967.
[30] [30] JAJSZCZYK A. A class of directional-coupler-based photonic switching networks[J]. IEEE Transactions on Communications, 1993, 41(4): 599-603.
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LIN Yue, SU Jun, FAN Zhiqiang, WANG Yunxiang, SHI Shuangjin, QIU Qi. Study of reconfigurable microwave photonics multi-beamforming technology[J]. Laser Technology, 2024, 48(5): 719
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Received: Oct. 17, 2023
Accepted: Dec. 2, 2024
Published Online: Dec. 2, 2024
The Author Email: QIU Qi (qqiu@uestc.edu.cn)
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