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    Journals >Journal of Semiconductors >Volume 40 >Issue 5 >Page 050301 > Article
    • Journal of Semiconductors
    • Vol. 40, Issue 5, 050301 (2019)
    Precision photonic integration for future large-scale photonic integrated circuits
    Xiangfei Chen
    Author Affiliations
  • College of Engineering and Applied Sciences, Nanjing University, Nanjing 210093, China
    • show less
    DOI: 10.1088/1674-4926/40/5/050301 Cite this Article
    Xiangfei Chen. Precision photonic integration for future large-scale photonic integrated circuits[J]. Journal of Semiconductors, 2019, 40(5): 050301 Copy Citation Text show less
    References

    [1] R Nagarajan, C H Joyner, R P Schneider et al. Large-scale photonic integrated circuits. IEEE J Sel Top Quantum Electron, 11, 50(2005).

    [2] D F Welch, F A Kish, R Nagarajan et al. The realization of large-scale photonic integrated circuits and the associated impact on fiber-optic communication systems. J Lightwave Technol, 24, 4674(2006).

    [3] T L Koch, U Koren. Semiconductor photonic integrated circuits. IEEE J Quantum Electron, 27, 641(1991).

    [4] T P Lee, C E Zah, R Bhat et al. Multiwavelength DFB laser array transmitters for ONTC reconfigurable optical network testbed. J Lightwave Technol, 14, 967(1996).

    [5] M Zanola, M J Strain, G Giuliani et al. Post-growth fabrication of multiple wavelength DFB laser arrays with precise wavelength spacing. IEEE Photonics Technol Lett, 24, 1063(2012).

    [6] S X Chew, X Yi, S Song et al. Silicon-on-insulator dual-ring notch filter for optical sideband suppression and spectral characterization. J Lightwave Technol, 34, 4705(2016).

    [7] Y Dai, X Chen. DFB semiconductor lasers based on reconstruction-equivalent-chirp technology. Opt Express, 15, 2348(2007).

    [8] J Li, H Wang, X Chen et al. Experimental demonstration of distributed feedback semiconductor lasers based on reconstruction-equivalent-chirp technology. Opt Express, 17, 5240(2009).

    [9] Y Shi, X Chen, Y Zhou et al. Experimental demonstration of eight-wavelength distributed feedback semiconductor laser array using equivalent phase shift. Opt Lett, 37, 3315(2012).

    [10] Y Shi, S Li, L Li et al. Study of the multiwavelength DFB semiconductor laser array based on the reconstruction-equivalent-chirp technique. J Lightwave Technol, 31, 3243(2013).

    [11] H Onji, S Takeuchi, Y Tatsumoto et al. 35 ns wavelength switching with +/-1 GHz wavelength accuracy using tunable distributed amplification (TDA-) DFB lasers. Advanced Photonics for Communications, OSA Technical Digest, PW4B.3(2014).

    [12] M R Billah, M Blaicher, T Hoose et al. Hybrid integration of silicon photonics circuits and InP lasers by photonic wire bonding. Optica, 5, 876(2018).

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    Xiangfei Chen. Precision photonic integration for future large-scale photonic integrated circuits[J]. Journal of Semiconductors, 2019, 40(5): 050301
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