Frontiers of Optoelectronics, Volume. 15, Issue 4, 12200(2022)

A “light chaser” and his dream of Optics Valley of China - To commemorate Prof. Dexiu Huang

Wei Hong*, Zhen Wang, and Jianji Dong
Author Affiliations
  • Wuhan National Laboratory for Optoelectronics, Huazhong University of Science and Technology, Wuhan 430074, China
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    References(71)

    [1] [1] Macleod, H.: Program of the 1982 Annual Meeting of the Optical Society of America, Tucson Community Center, Tucson, Arizona October 18-22, 1982. J. Opt. Soc. Am. 72, 1718-1838 (1982)

    [2] [2] Elliott, R.A., Huang, D., DeFreez, R.K., Hunt, J.M., Rickman, P.G.: Picosecond optical pulse generation by impulse train current modulation of a semiconductor laser. Appl. Phys. Lett. 42(12), 1012-1014 (1983)

    [3] [3] Wei, H., Huang, D., Sun, J., Liu, D.: Numerical simulation of recovery enhancement by a CW pump light in semiconductor optical amplifiers. Opt. Commun. 214(1-6), 335-341 (2002)

    [4] [4] Huang, L., Huang, D., Sun, J., Liu, D.: Spectral broadening of ultrashort optical pulse due to birefringence in semiconductor optical amplifiers. Opt. Commun. 223(4-6), 295-300 (2003)

    [5] [5] Dong, J., Zhang, X., Huang, D.: Experimental and theoretical study on gain dynamics of SOA. Acta Phy. Sinica 54(2), 763-767 (2005)

    [6] [6] Huang, L., Huang, D., Chen, J., Liu, D., Zhang, X.: Analysis of a semiconductor optical amplifier with polarization-insensitive gain and polarization-insensitive phase modulation. Semicond. Sci. Technol. 21(12), 1643-1650 (2006)

    [7] [7] Zhou, E., Zhang, X., Huang, D.: Analysis on dynamic characteristics of semiconductor optical amplifiers with certain facet reflection based on detailed wideband model. Opt. Express 15(14), 9096-9106 (2007)

    [8] [8] Zhou, E., Ohman, F., Cheng, C., Zhang, X., Hong, W., Mork, J., Huang, D.: Reduction of patterning effects in SOA-based wavelength converters by combining cross-gain and cross-absorption modulation. Opt. Express 16(26), 21522-21528 (2008)

    [9] [9] Huang, L., Yu, Y., Tian, P., Huang, D.: Polarization-insensitive quantum-dot coupled quantum-well semiconductor optical amplifier. Semicond Sci. Technol. 24(1), 015009 (2009)

    [10] [10] Tian, P., Huang, L., Hong, W., Huang, D.: Pattern effect reduction in all-optical wavelength conversion using a two-electrode semiconductor optical amplifier. Appl. Opt. 49(26), 5005-5012 (2010)

    [11] [11] Huang, X., Qin, C., Huang, D., Zhang, X.: Local carrier recovery acceleration in quantum well semiconductor optical amplifiers. IEEE J. Quantum Electron. 46(10), 1407-1413 (2010)

    [12] [12] Yi, Y., Huang, L., Meng, X., Peng, T., Huang, D.: Enhancement of gain recovery rate and cross-gain modulation bandwidth using a two-electrode quantum-dot semiconductor optical amplifier. J. Opt. Soc. Am. B 27(11), 2211-2217 (2010)

    [13] [13] Zhang, X., Sun, J., Liu, D., Huang, D., Yi, H.: Study on conversion characteristics of wavelength converters based on cross-gain modulation in semiconductor optical amplifiers. Acta Phy. Sinica 49(4), 741-746 (2000)

    [14] [14] Zhang, X., Huang, D., Sun, J., Liu, D.: A novel scheme for XGM wavelength conversion based on single-port-coupled SOA. Chin. Phys. 10(2), 124 (2001)

    [15] [15] Zhang, X., Huang, D., Sun, J., Liu, D.: Single to 16-channel wavelength conversion at 10 Gb/s based on cross-gain modulation of ASE spectrum in SOA. Opt. Quantum Electron. 36(7), 627-634 (2004)

    [16] [16] Fan, X., Zhang, X., Huang, D.: Theoretical and experimental investigations on a novel tunable all-optical wavelength converter. Acta Phy. Sinica 53(7), 2165-2169 (2004)

    [17] [17] Li, P.L., Huang, D.X., Zhang, X.L., Chen, J., Huang, L.R.: Theoretical analysis of tunable wavelength conversion based on FWM in a semiconductor fiber ring laser. IEEE J. Quantum Electron. 41(4), 581-588 (2005)

    [18] [18] Fu, S., Dong, J., Shum, P., Zhang, L., Zhang, X., Huang, D.: Experimental demonstration of both inverted and non-inverted wavelength conversion based on transient cross phase modulation of SOA. Opt. Express 14(17), 7587-7593 (2006)

    [19] [19] Dong, J., Fu, S., Zhang, X., Shum, P., Zhang, L., Huang, D.: Analytical solution for SOA-based all-optical wavelength conversion using transient cross-phase modulation. IEEE Photonics Technol. Lett. 18(24), 2554-2556 (2006)

    [20] [20] Dong, J., Zhang, X., Fu, S., Ping, S., Huang, D.: Theoretical study of SOA-based wavelength conversion with NRZ and RZ format at 40 Gb/s. Chin. Phys. Lett. 24(4), 990-993 (2007)

    [21] [21] Dong, J., Zhang, X., Fu, S., Xu, J., Shum, P., Huang, D.: Ultrafast all-optical signal processing based on single semiconductor optical amplifier and optical filtering. IEEE J. Sel. Top. Quantum Electron. 14(3), 770-778 (2008)

    [22] [22] Hong, W., Li, M., Zhang, X., Sun, J., Huang, D.: Dynamic analysis of all-optical wavelength conversion of differential phase-shift keyed signals based on semiconductor optical amplifier Mach-Zehnder interferometer. J. Lightwave Technol. 27(24), 5580-5589 (2009)

    [23] [23] Hong, W., Huang, D., Cai, F., Wang, Y.: Simultaneous clock component extraction and wavelength conversion of NRZ signal using an SOA loop mirror. IEEE Photonics Technol. Lett. 16(4), 1116-1118 (2004)

    [24] [24] Yu, Y., Zhang, X., Huang, D.: All-optical clock recovery from NRZ-DPSK signal. IEEE Photonics Technol. Lett. 18(22), 2356-2358 (2006)

    [25] [25] Yu, Y., Zhang, X., Zhou, E., Huang, D.: All-optical clock recovery from NRZ signals at different bit rates via preprocessing by an optical filter. IEEE Photonics Technol. Lett. 19(24), 2039-2041 (2007)

    [26] [26] Hong, W., Li, M., Zhang, X., Sun, J., Huang, D.: Noise suppression mechanisms in regenerators based on XGC in an SOA with subsequent optical filtering. IEEE J. Sel. Top. Quantum Electron. 18(2), 935-949 (2012)

    [27] [27] Yang, W., Cao, T., Yu, Y., Shi, L., Zhang, X., Huang, D.: Theoretical analysis and experimental investigation of degenerate phasesensitive amplification in a semiconductor optical amplifier. J. Lightwave Technol. 33(19), 4001-4007 (2015)

    [28] [28] Zhang, X., Wang, Y., Sun, J., Liu, D., Huang, D.: All-optical AND gate at 10 Gbit/s based on cascaded single-port-couple SOAs. Opt. Express 12(3), 361-366 (2004)

    [29] [29] Zhang, X., Dong, J., Ying, W., Huang, D.: Experimental and theoretical investigation on novel all-optical logic AND gates. Acta Phy. Sinica 54(5), 2066-2071 (2005)

    [30] [30] Zhao, C., Zhang, X., Liu, H., Liu, D., Huang, D.: Tunable alloptical NOR gate at 10 Gb/s based on SOA fiber ring laser. Opt. Express 13(8), 2793-2798 (2005)

    [31] [31] Xu, J., Zhang, X., Liu, D., Huang, D.: Ultrafast all-optical NOR gate based on semiconductor optical amplifier and fiber delay interferometer. Opt. Express 14(22), 10708-10714 (2006)

    [32] [32] Li, P.L., Huang, D.X., Zhang, X.L., Zhu, G.X.: Ultrahigh-speed all-optical half adder based on four-wave mixing in semiconductor optical amplifier. Opt. Express 14(24), 11839-11847 (2006)

    [33] [33] Wang, Y., Zhang, X., Dong, J., Huang, D.: Simultaneous demonstration on all-optical digital encoder and comparator at 40 Gb/s with semiconductor optical amplifiers. Opt. Express 15(23), 15080-15085 (2007)

    [34] [34] Dong, J., Fu, S., Zhang, X., Shum, P., Zhang, L., Xu, J., Huang, D.: Single SOA based all-optical adder assisted by optical bandpass filter: theoretical analysis and performance optimization. Opt. Commun. 270(2), 238-246 (2007)

    [35] [35] Xu, J., Zhang, X., Dong, J., Liu, D., Huang, D.: High-speed alloptical differentiator based on a semiconductor optical amplifier and an optical filter. Opt. Lett. 32(13), 1872-1874 (2007)

    [36] [36] Xu, J., Zhang, X., Dong, J., Liu, D., Huang, D.: All-optical differentiator based on cross-gain modulation in semiconductor optical amplifier. Opt. Lett. 32(20), 3029-3031 (2007)

    [37] [37] Xu, J., Zhang, X., Dong, J., Liu, D., Huang, D.: Simultaneous alloptical and and nor Gates for NRZ differential phase-shift-keying signals. IEEE Photonics Technol. Lett. 20(8), 596-598 (2008)

    [38] [38] Dong, J., Zhang, X., Xu, J., Huang, D.: 40Gb/s all-optical logic NOR and OR gates using a semiconductor optical amplifier: experimental demonstration and theoretical analysis. Opt. Commun. 281(6), 1710-1715 (2008)

    [39] [39] Xu, J., Zhang, X., Zhang, Y., Dong, J., Liu, D., Huang, D.: Reconfigurable all-optical logic gates for multi-input differential phaseshift keying signals: design and experiments. J. Lightwave Technol. 27(23), 5268-5275 (2009)

    [40] [40] Dong, J., Zhang, X., Huang, D.: A proposal for two-input arbitrary Boolean logic gates using single semiconductor optical amplifier by picosecond pulse injection. Opt. Express 17(10), 7725-7730 (2009)

    [41] [41] Li, P.L., Huang, D.X., Zhang, X.L.: SOA-based ultrafast multifunctional all-optical logic gates with PolSK modulated signals. IEEE J. Quantum Electron. 45(12), 1542-1550 (2009)

    [42] [42] Dong, J., Luo, B., Zhang, Y., Huang, D., Zhang, X.: Reconfigurable photonic differentiators based on all-optical phase modulation and linear filtering. Opt. Commun. 284(24), 5792-5797 (2011)

    [43] [43] Wang, J., Sun, J., Sun, Q., Wang, D., Zhou, M., Zhang, X., Huang, D., Fejer, M.M.: All-optical format conversion using a periodically poled lithium niobate waveguide and a reflective semiconductor optical amplifier. Appl. Phys. Lett. 91(5), 051107 (2007)

    [44] [44] Dong, J., Zhang, X., Xu, J., Huang, D., Fu, S., Shum, P.: 40 Gb/s all-optical NRZ to RZ format conversion using single SOA assisted by optical bandpass filter. Opt. Express 15(6), 2907-2914 (2007)

    [45] [45] Da, L., Zhang, X., Huang, D.: Experimental and theoretical investigation on novel all-optical format conversion based on a folded ultrafast nonlinear interferometer. Acta Phy. Sinica 56(4), 2223-2228 (2007)

    [46] [46] Hong, W., Huang, D., Zhang, X., Zhu, G.: Simulation and analysis of OOK-to-BPSK format conversion based on gain-transparent SOA used as optical phase-modulator. Opt. Express 15(26), 18357-18369 (2007)

    [47] [47] Yu, Y., Zhang, X., Rosas-Fernández, J.B., Huang, D., Penty, R.V., White, I.H.: Single SOA based 16 DWDM channels all-optical NRZ-to-RZ format conversions with different duty cycles. Opt. Express 16(20), 16166-16171 (2008)

    [48] [48] Dong, J., Zhang, X., Xu, J., Huang, D., Fu, S., Shum, P.: Ultrawideband monocycle generation using cross-phase modulation in a semiconductor optical amplifier. Opt. Lett. 32(10), 1223-1225 (2007)

    [49] [49] Dong, J., Zhang, X., Xu, J., Huang, D.: All-optical ultrawideband monocycle generation utilizing gain saturation of a dark return-tozero signal in a semiconductor optical amplifier. Opt. Lett. 32(15), 2158-2160 (2007)

    [50] [50] Chen, G., Huang, D., Zhang, X., Cao, H.: Photonic generation of a microwave signal by incorporating a delay interferometer and a saturable absorber. Opt. Lett. 33(6), 554-556 (2008)

    [51] [51] Zhou, L., Zhang, X., Xu, E., Huang, D.: Q value analysis of a first-order IIR microwave photonic filter based on SOA. Acta Phy. Sinica 58(2), 1036-1041 (2009)

    [52] [52] Xu, E., Zhang, X., Zhou, L., Yu, Z., Huang, D.: Hybrid activepassive microwave photonic filter with high quality factor. Chin. Phys. Lett. 26(9), 094208 (2009)

    [53] [53] Lv, H., Yu, Y., Shu, T., Huang, D., Jiang, S., Barry, L.P.: Photonic generation of ultra-wideband signals by direct current modulation on SOA section of an SOA-integrated SGDBR laser. Opt. Express 18(7), 7219-7227 (2010)

    [54] [54] Xu, E., Zhang, X., Zhou, L., Zhang, Y., Yu, Y., Li, X., Huang, D.: Ultrahigh-Q microwave photonic filter with Vernier effect and wavelength conversion in a cascaded pair of active loops. Opt. Lett. 35(8), 1242-1244 (2010)

    [55] [55] Xu, E., Zhang, X., Zhou, L., Zhang, Y., Yu, Y., Li, X., Huang, D.: All-optical microwave filter with high frequency selectivity based on semiconductor optical amplifier and optical filter. J. Lightwave Technol. 28(16), 2358-2365 (2010)

    [56] [56] Dong, J., Yu, Y., Zhang, Y., Li, X., Huang, D., Zhang, X.: Alloptical binary phase-coded UWB signal generation for multiuser UWB communications. Opt. Express 19(11), 10587-10594 (2011)

    [57] [57] Cai, X., Huang, D., Zhang, X.: Numerical analysis of polarization splitter based on vertically coupled microring resonator. Opt. Express 14(23), 11304-11311 (2006)

    [58] [58] Zhang, X., Huang, D., Zhang, X.: Transmission characteristics of dual microring resonators coupled via 3×3 couplers. Opt. Express 15(21), 13557-13573 (2007)

    [59] [59] Ding, Y., Zhang, X., Zhang, X., Huang, D.: Proposal for loadable and erasable optical memory unit based on dual active microring optical integrators. Opt. Commun. 281(21), 5315-5321 (2008)

    [60] [60] Ding, Y., Zhang, X., Zhang, X., Huang, D.: Active microring optical integrator associated with electroabsorption modulators for high speed low light power loadable and erasable optical memory unit. Opt. Express 17(15), 12835-12848 (2009)

    [61] [61] Ding, Y., Zhang, X., Zhang, X., Huang, D.: Elastic polarization converter based on dual microring resonators. IEEE J. Quantum Electron. 45(8), 1033-1038 (2009)

    [62] [62] Ding, Y., Peucheret, C., Pu, M., Zsigri, B., Seoane, J., Liu, L., Xu, J., Ou, H., Zhang, X., Huang, D.: Multi-channel WDM RZto-NRZ format conversion at 50 Gbit/s based on single silicon microring resonator. Opt. Express 18(20), 21121-21130 (2010)

    [63] [63] Ding, Y., Xu, J., Peucheret, C., Pu, M., Liu, L., Seoane, J., Ou, H., Zhang, X., Huang, D.: Multi-channel 40 Gbit/s NRZ-DPSK demodulation using a single silicon microring resonator. J. Lightwave Technol. 29(5), 677-684 (2011)

    [64] [64] Ding, Y., Pu, M., Liu, L., Xu, J., Peucheret, C., Zhang, X., Huang, D., Ou, H.: Bandwidth and wavelength-tunable optical bandpass filter based on silicon microring-MZI structure. Opt. Express 19(7), 6462-6470 (2011)

    [65] [65] Ding, Y., Hu, H., Galili, M., Xu, J., Liu, L., Pu, M., Mulvad, H.C., Oxenlowe, L.K., Peucheret, C., Jeppesen, P., Zhang, X., Huang, D., Ou, H.: Generation of a 640 Gbit/s NRZ OTDM signal using a silicon microring resonator. Opt. Express 19(7), 6471-6477 (2011)

    [66] [66] Dong, J., Zheng, A., Gao, D., Liao, S., Lei, L., Huang, D., Zhang, X.: High-order photonic differentiator employing on-chip cascaded microring resonators. Opt. Lett. 38(5), 628-630 (2013)

    [67] [67] Ding, Y., Huang, B., Peucheret, C., Xu, J., Ou, H., Zhang, X., Huang, D.: Ultra-wide band signal generation using a couplingtunable silicon microring resonator. Opt. Express 22(5), 6078-6085 (2014)

    [68] [68] Huang, D.: Semiconductor Optoelectronics. University of Electronic Science and Technology Press (in Chinese), Chengdu (1989)

    [69] [69] Huang, D.: Semiconductor Optoelectronics, 2nd edn. Publishing House of Electronics Industry (in Chinese), Beijing (2013)

    [70] [70] Huang, D., Huang, L., Hong, W.: Semiconductor Optoelectronics, 3rd edn. Publishing House of Electronics Industry (in Chinese), Beijing (2018)

    [71] [71] Zhou, Z., Huang, D.: Research and development at Wuhan National Laboratory for Optoelectronics. In: Proceedings of SPIE Optoelectronic Materials and Devices for Optical Communications. SPIE, 602009 (2005)

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    Wei Hong, Zhen Wang, Jianji Dong. A “light chaser” and his dream of Optics Valley of China - To commemorate Prof. Dexiu Huang[J]. Frontiers of Optoelectronics, 2022, 15(4): 12200

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    Paper Information

    Category: RECOLLECTION

    Received: Dec. 9, 2022

    Accepted: --

    Published Online: Jan. 22, 2023

    The Author Email: Hong Wei (w.hong@hust.edu.cn)

    DOI:10.1007/s12200-022-00053-0

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