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    Journals >Infrared and Laser Engineering >Volume 50 >Issue 7 >Page 20211048 > Article
    • Infrared and Laser Engineering
    • Vol. 50, Issue 7, 20211048 (2021)
    Frontiers and prospects of integrated microwave photonics (Invited)
    Ming Li1、2、3, Tengfei Hao1、2、3, Shilong Pan4, Xihua Zou5, Binfeng Yun6, Weiwen Zou7, Wei Li1、2、3, and Lianshan Yan5
    Author Affiliations
  • 1State Key Laboratory on Integrated Optoelectronics, Institute of Semiconductors, Chinese Academy of Sciences, Beijing 100083, China
  • 2School of Electronic, Electrical and Communication Engineering, University of Chinese Academy of Sciences, Beijing 100049, China
  • 3Center of Materials Science and Optoelectronics Engineering, University of Chinese Academy of Sciences, Beijing 100049, China
  • 4College of Electronic and Information Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 211106, China
  • 5School of Information Science and Technology, Southwest Jiaotong University, Chengdu 611756, China
  • 6School of Electronic Science and Engineering, Southeast University, Nanjing 210096, China
  • 7School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai 200240, China
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    DOI: 10.3788/IRLA20211048 Cite this Article
    Ming Li, Tengfei Hao, Shilong Pan, Xihua Zou, Binfeng Yun, Weiwen Zou, Wei Li, Lianshan Yan. Frontiers and prospects of integrated microwave photonics (Invited)[J]. Infrared and Laser Engineering, 2021, 50(7): 20211048 Copy Citation Text show less
    Semiconductor laser with high power and low noise. (a)-(c) are the semiconductor laser made by Emcore[18] in the U.S.A., Apic[19] in the U.S.A. and Z.K. Litecore[20] in China, respectively
    Fig. 1. Semiconductor laser with high power and low noise. (a)-(c) are the semiconductor laser made by Emcore[18] in the U.S.A., Apic[19] in the U.S.A. and Z.K. Litecore[20] in China, respectively
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    Electro-optic modulator with broad bandwidth and low half-wave voltage. (a) Traditional lithium niobate modulator[22]; (b) Thin-film lithium niobate modulator[23]; (c) Plasmonic modulator[14, 21]; (d) InP and silicon modulator with high linearity[24-26]
    Fig. 2. Electro-optic modulator with broad bandwidth and low half-wave voltage. (a) Traditional lithium niobate modulator[22]; (b) Thin-film lithium niobate modulator[23]; (c) Plasmonic modulator[14, 21]; (d) InP and silicon modulator with high linearity[24-26]
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    Photodetector with high saturation power. (a) Product of photodetector by II-VI Incorporated[27]; (b) Chip of InP photodetector[28]; (c) Chip of InP on SOI photodetector[29]; (d) Chip of Ge on SOI photodetector[30]
    Fig. 3. Photodetector with high saturation power. (a) Product of photodetector by II-VI Incorporated[27]; (b) Chip of InP photodetector[28]; (c) Chip of InP on SOI photodetector[29]; (d) Chip of Ge on SOI photodetector[30]
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    Beamformer chips based on path selection to switch different delays. (a) Silicon nitride 5-bit delay chip with 4 channels[31]; (b) Silicon dioxide 5.5-bit delay chip with 8 channels[32]; (c) Silicon 5-bit beam control chip with 8 channels[33]
    Fig. 4. Beamformer chips based on path selection to switch different delays. (a) Silicon nitride 5-bit delay chip with 4 channels[31]; (b) Silicon dioxide 5.5-bit delay chip with 8 channels[32]; (c) Silicon 5-bit beam control chip with 8 channels[33]
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    Beamformer chips based on dispersion tuning of microring resonators. (a) Silicon nitride multi-wavelength tunable delay chip[34]; (b) Silicon nitride tunable delay chip with 4 channels[35]; (c) Silicon beam control chip with 4 channels[36]
    Fig. 5. Beamformer chips based on dispersion tuning of microring resonators. (a) Silicon nitride multi-wavelength tunable delay chip[34]; (b) Silicon nitride tunable delay chip with 4 channels[35]; (c) Silicon beam control chip with 4 channels[36]
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    Integrated microwave photonic filters. (a) Microwave photonic filter based on silicon nitride microring resonator[37]; (b) Microwave photonic filter based on SBS effect[38]; (c) Microwave photonic filter based on cascaded silicon nitride microring resonators[39]; (d) SOI integrated microwave photonic filter[40]; (e) Monolithically integrated InP microwave photonic filter[41]
    Fig. 6. Integrated microwave photonic filters. (a) Microwave photonic filter based on silicon nitride microring resonator[37]; (b) Microwave photonic filter based on SBS effect[38]; (c) Microwave photonic filter based on cascaded silicon nitride microring resonators[39]; (d) SOI integrated microwave photonic filter[40]; (e) Monolithically integrated InP microwave photonic filter[41]
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    Integrated microwave photonic signal generation chips. (a) InP monolithically integrated microwave photonic oscillator chip[42]; (b) SOI integrated microwave photonic oscillator chip[43]; (c) SOI integrated arbitrary microwave waveform generation chip[44]; (d) SOI integrated chip for the generation of linearly chirped microwave signals[45]
    Fig. 7. Integrated microwave photonic signal generation chips. (a) InP monolithically integrated microwave photonic oscillator chip[42]; (b) SOI integrated microwave photonic oscillator chip[43]; (c) SOI integrated arbitrary microwave waveform generation chip[44]; (d) SOI integrated chip for the generation of linearly chirped microwave signals[45]
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    Integrated microwave photonic frequency conversion chips. (a) InP monolithically integrated microwave photonic frequency conversion chip[46]; (b) SOI integrated microwave photonic frequency conversion chip[47]
    Fig. 8. Integrated microwave photonic frequency conversion chips. (a) InP monolithically integrated microwave photonic frequency conversion chip[46]; (b) SOI integrated microwave photonic frequency conversion chip[47]
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    Silicon photonics analog to digital conversion chip[48]
    Fig. 9. Silicon photonics analog to digital conversion chip[48]
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    Programmable microwave photonic signal processing chips. (a) Programmable microwave photonic integrated signal processing chip based on tunable MZI units[52]; (b) Programmable microwave photonic integrated signal processing chip based on tunable microdisks[53]
    Fig. 10. Programmable microwave photonic signal processing chips. (a) Programmable microwave photonic integrated signal processing chip based on tunable MZI units[52]; (b) Programmable microwave photonic integrated signal processing chip based on tunable microdisks[53]
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    Ming Li, Tengfei Hao, Shilong Pan, Xihua Zou, Binfeng Yun, Weiwen Zou, Wei Li, Lianshan Yan. Frontiers and prospects of integrated microwave photonics (Invited)[J]. Infrared and Laser Engineering, 2021, 50(7): 20211048
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