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    Journals >Acta Optica Sinica >Volume 43 >Issue 23 >Page 2312002 > Article
    • Acta Optica Sinica
    • Vol. 43, Issue 23, 2312002 (2023)
    Linearity Compensation Method for Silicon-Based Modulator Based on Enhanced Maximum Ratio Combined Receiver
    Jun Qin1,2, Yuansheng Tao3, Ming Jin3, Changhao Han3..., Gangwar Rahul Kumar3, Yueqin Li1,2, Jian Sun1,2 and Min Miao1,2,*|Show fewer author(s)
    Author Affiliations
  • 1Key Laboratory of Information and Communication Systems, Ministry of Information Industry, School of Information & Communication Engineering, Beijing Information Science & Technology University, Beijing 100101, China
  • 2Key Laboratory of Optoelectronic Measurement Technology and Instrument, Ministry of Education, School of Information & Communication Engineering, Beijing Information Science & Technology University, Beijing 100101, China
  • 3State Key Laboratory of Advanced Optical Communication Systems and Networks, School of Electronics, Peking University, Beijing 100871, China
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    DOI: 10.3788/AOS231033 Cite this Article Set citation alerts
    Jun Qin, Yuansheng Tao, Ming Jin, Changhao Han, Gangwar Rahul Kumar, Yueqin Li, Jian Sun, Min Miao. Linearity Compensation Method for Silicon-Based Modulator Based on Enhanced Maximum Ratio Combined Receiver[J]. Acta Optica Sinica, 2023, 43(23): 2312002 Copy Citation Text show less
    Framework of NG-PON2 Fronthaul I network employing EMRC-Rx and Si modulator
    Fig. 1. Framework of NG-PON2 Fronthaul I network employing EMRC-Rx and Si modulator
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    Working principle of the system. (a) Working principle of uplink and downlink signal transmission of PON system employing EMRC-Rx and Si modulator; (b) corresponding spectrum of each part and PD internal beat frequency spectrum
    Fig. 2. Working principle of the system. (a) Working principle of uplink and downlink signal transmission of PON system employing EMRC-Rx and Si modulator; (b) corresponding spectrum of each part and PD internal beat frequency spectrum
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    Experiment setup. (a) Confirmatory experimental device with Si modulator and EMRC-Rx; (b) DSP of the QPSK transmitter, DD-Rx, Lite CO-Rx #1, and Lite CO-Rx #2
    Fig. 3. Experiment setup. (a) Confirmatory experimental device with Si modulator and EMRC-Rx; (b) DSP of the QPSK transmitter, DD-Rx, Lite CO-Rx #1, and Lite CO-Rx #2
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    Si MZM chip diagram
    Fig. 4. Si MZM chip diagram
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    Device characterization setup. (a) Bandwidth (S21) testing link of Si modulator; (b) SFDR testing link of Si modulator
    Fig. 5. Device characterization setup. (a) Bandwidth (S21) testing link of Si modulator; (b) SFDR testing link of Si modulator
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    Device performance characterization results. (a) S21 response of the Si MZM at different reverse bias voltages; (b) test result of SHD and IMD3
    Fig. 6. Device performance characterization results. (a) S21 response of the Si MZM at different reverse bias voltages; (b) test result of SHD and IMD3
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    Frequency spectrum captured by oscilloscope after PD
    Fig. 7. Frequency spectrum captured by oscilloscope after PD
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    Measured BERs and constellations for DD-Rx, Lite CO-Rx #1, Lite CO-Rx #2, and EMRC-Rx in the case of BTB
    Fig. 8. Measured BERs and constellations for DD-Rx, Lite CO-Rx #1, Lite CO-Rx #2, and EMRC-Rx in the case of BTB
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    Measured EVM varing with the frequency interval between the downstream signal and upstream LO for the DD-RX, Lite CO-Rx #1, Lite CO-Rx #2, and EMRC-Rx
    Fig. 9. Measured EVM varing with the frequency interval between the downstream signal and upstream LO for the DD-RX, Lite CO-Rx #1, Lite CO-Rx #2, and EMRC-Rx
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    Received sensitivity of the DD-Rx, Lite CO-Rx #1, and EMRC-Rx varing with the fiber optic transmission distance at different BERs, curve coincidence of MRC-Rx and Lite CO-Rx #1 in Fig.10(a). (a) HD-FEC threshold; (b) 1.0×10-4
    Fig. 10. Received sensitivity of the DD-Rx, Lite CO-Rx #1, and EMRC-Rx varing with the fiber optic transmission distance at different BERs, curve coincidence of MRC-Rx and Lite CO-Rx #1 in Fig.10(a). (a) HD-FEC threshold; (b) 1.0×10-4
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    Measured BER of DD-Rx, Lite CO-Rx #1, MRC-Rx, and EMRC-Rx with Si MZM and LN MZM
    Fig. 11. Measured BER of DD-Rx, Lite CO-Rx #1, MRC-Rx, and EMRC-Rx with Si MZM and LN MZM
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    System SSBI analysis. (a) Generation principle of SSBI; (b) impact of SSBI in the proposed system
    Fig. 12. System SSBI analysis. (a) Generation principle of SSBI; (b) impact of SSBI in the proposed system
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    Jun Qin, Yuansheng Tao, Ming Jin, Changhao Han, Gangwar Rahul Kumar, Yueqin Li, Jian Sun, Min Miao. Linearity Compensation Method for Silicon-Based Modulator Based on Enhanced Maximum Ratio Combined Receiver[J]. Acta Optica Sinica, 2023, 43(23): 2312002
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