Optical arbitrary waveform generation based on an array of tunable apodized waveguide Bragg gratings
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Tianjin Key Laboratory of Film Electronic and Communication Devices, Engineering Research Center of Ministry of Education for Optoelectronic Devices and Communication Technology, School of Electrical and Electronic Engineering, Tianjin University of Technology, Tianjin 300384, China

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    Abstract:

    A structure of optical arbitrary waveform generation (OAWG) based on an array of tunable apodized waveguide Bragg gratings (WBGs) is proposed. The WBGs array on lithium niobate (LN) consists of several apodized gratings, waveguides and electrodes deposited on both sides of gratings and waveguides. The properties of OAWG are analyzed using transfer matrix method. Due to the electro-optic effect of LN, the amplitude and phase of incident light source are controlled via adjusting the voltages on electrodes. Consequently, the optical pulses with different waveforms are obtained and the amplitude is linearly tuned. In addition, voltages compensating amplitude and phase distortion are demonstrated.

    Reference
    [1] Binbin Guan, Nicolas K. Fontaine and Roland Ryf, Journal of Lightwave Technology 34, 737 (2016).
    [2] Roberto Proietti, Chuan Qin, Binbin Guan and Nicolas K. Fontaine, Journal of Optical Communications and Networking 8, A171 (2016).
    [3] Y. Park, M.H. Asghari and R. Helsten, IEEE Photonics Journal 2, 1040 (2010).
    [4] Amir R, Yihan L. and Andrew M W, IEEE Journal of Quantum Electronics 52, 1 (2015).
    [5] Steven T. Cundiff and Andrew M. Weiner, Nature Photonics 4, 760 (2010).
    [6] Mittelberger D. E., Muir R. D., Hamamoto M. Y., Prantil M. A. and Heebner J. E., Optics Letters 44, 2863 (2019).
    [7] He Yutong, Jiang Yang and Zi Yuejiao, Optics Express 26, 7829 (2018).
    [8] Zhang Ailing and Li Changxiu, Optics Express 20, 23074 (2012).
    [9] Zhang Ailing and Li Changxiu, Optics & Laser Technology 52, 81 (2013).
    [10] Yang Mengchao and Zhang Ailing, Chinese Journal of Lasers 41, 0105003 (2014).
    [11] Li Peili, Ma Xiaolu, Shi Weihua and Xu Enming, Optics and Laser Technology 94, 228 (2017).
    [12] Cruz J L, Diez A and Andres M A, Electronics Letters 33, 1123 (2010).
    [13] Binfeng Yun, Guohua Hu, Ruohu Zhang and Yiping Cui, Optics Communication 336, 30 (2015).
    [14] Arizmendi L, Physica Status Solidi 201, 253 (2004).
    [15] Shaoqi Feng, Chuan Qin, Kuanping Shang, Shibnath Pathak and S.J. Ben Yoo, Optics Express 25, 8872 (2017).
    [16] Veenhuizen Keith, McAnany Sean and Nolan Daniel, Scientific Reports 7, 44327 (2017).
    [17] Kip D, Hukriede J and Runde D, Infrared Holography for Optical Communications 86, 113 (2002).
    [18] Ghoumid K, Ferriere R and Benkelfat B-E, Journal of Lightwave Technology 28, 3488 (2010).
    [19] Erdogan T, Journal of Lightwave Technology 15, 1277 (1997).
    [20] Arizmendi L, Physica Status Solidi 201, 253 (2004).
    [21] David E. Zelmon, David L. Small and Dieter Jundt, Optical Society of America 14, 3319 (1997).
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ZHANG Ai-ling, CHENG Qi-hang, SONG Hong-yun, PAN Hong-gang. Optical arbitrary waveform generation based on an array of tunable apodized waveguide Bragg gratings[J]. Optoelectronics Letters,2020,16(3):195-199

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History
  • Received:May 30,2019
  • Revised:July 20,2019
  • Online: June 02,2020
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