RESEARCH ARTICLE

Broadband optical frequency comb generation based on single electro-absorption modulation driven by radio frequency coupled signals

  • Pan Jiang ,
  • Peili Li ,
  • Yiming Fan
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  • College of Electronic and Optical Engineering & College of Microelectronics, Nanjing University of Posts and Telecommunications, Nanjing 210023, China

Received date: 21 Dec 2021

Accepted date: 28 Mar 2022

Published date: 15 Dec 2022

Copyright

2022 The Author(s) 2022

Abstract

Broadband optical frequency comb (OFC) generation based on a single electro-absorption modulator (EAM) is proposed. The EAM is driven by a radio frequency (RF) multi-frequency signal generated by a multiplication coupler composed of an electrical power splitter and an arithmetic circuit. Thus the number of comb-lines of the generated OFC can be increased. A complete theoretical model of OFC generation by an EAM driven by nth power of the RF source is established, and the performance of the OFC is analyzed by using OptiSystem software. The results show that, the number of comb-lines of the OFC is positively correlated with the number of multiplication of the RF source signal. The frequency spacing of the comb-lines is twice the frequency of the RF source signal and is tunable by adjusting the frequency of the RF source signal. Increasing chirp factor and modulation index of EAM could increase the number of comb-lines of the generated OFC. The amplitude of the RF source signal had little impact on the flatness of the OFC and the average OFC power. The scheme developed is not only simple and low-cost, but also can produce a large number of comb-lines.

Cite this article

Pan Jiang , Peili Li , Yiming Fan . Broadband optical frequency comb generation based on single electro-absorption modulation driven by radio frequency coupled signals[J]. Frontiers of Optoelectronics, 2022 , 15(4) : 45 . DOI: 10.1007/s12200-022-00045-0

1
Song, G.B., Wang, T.S., Dong, F., Zhang, Y.: Transmission characteristics of 24.5 Gb/s atmospheric laser communication based on optical frequency comb. Opt. Commun. 465, 125602(2020)

DOI

2
Zhou, X., Zheng, X., Wen, H., Zhang, H., Zhou, B.: Pair-by-pair pulse shaping for optical arbitrary waveform generation by dualcomb heterodyne. Opt. Lett. 38(24), 5331–5333 (2013)

DOI

3
Jiang, Z., Huang, C.B., Leaird, D.E., Weiner, A.M.: Optical arbitrary waveform processing of more than 100 spectral comb lines. Nat. Photonics 1(8), 463–467 (2007)

DOI

4
Vainio, M., Karhu, J.: Fully stabilized mid-infrared frequency comb for high-precision molecular spectroscopy. Opt. Express 25(4), 4190–4200 (2017)

DOI

5
Jang, Y.S., Lee, K., Han, S., Lee, J., Kim, Y.J., Kim, S.W.: Absolute distance measurement with extension of nonambiguity range using the frequency comb of a femtosecond laser. Opt. Eng. 53(12), 122403(2014)

DOI

6
Pelusi, M., Tan, H.N., Trapala, K.S., Inoue, T., Shu, N.: Low noise frequency combs for higher order QAM formats through cross-phase modulation of modelocked laser pulses. IEEE J. Sel. Top. Quantum Electron. 24(3), 1101612(2018)

DOI

7
Hellwig, T., Rieger, S., Fallnich, C.: Toward an all-optically stabilized frequency comb based on a mode-locked fiber laser. Opt. Lett. 39(3), 525–527 (2014)

DOI

8
Melo, S.A.S., Nascimento, A.R.D., Cerqueira, S.A., Carvalho, L.H.H., Pataca, D.M., Oliveira, J.C.R.F., Fragnito, H.L.: Frequency comb expansion based on optical feedback, highly nonlinear and erbium-doped fibers. Opt. Commun. 312, 287–291 (2014)

DOI

9
Xue, X.X., Weiner, A.M.: Microwave photonics connected with microresonator frequency combs. Front. Optoelectron. 9(2), 238–248 (2016)

DOI

10
Huo, L., Wang, Q., Lou, C.: Multifunctional optoelectronic oscillator based on cascaded modulators. IEEE Photonics Technol. Lett. 28(4), 520–523 (2016)

DOI

11
Ullah, R., Ullah, S., Khan, G.Z., Mao, Y., Ren, J., Zhao, J., Chen, S., Li, M., Khan, J.: Ultrawide and tunable self-oscillating optical frequency comb generator based on an optoelectronic oscillator. Results Phys. 22(1), 103849(2021)

DOI

12
Wang, J., Cai, H., Chen, D.J., Qu, R.H.: Generation of ultra-flat optical frequency comb using a balanced driven dual parallel Mach-Zehnder modulator. Chin. Opt. Lett. 13(6), 060604–060607 (2015)

DOI

13
Chen, C., Zhang, F., Pan, S.: Generation of seven-line optical frequency comb based on a single polarization modulator. IEEE Photonics Technol. Lett. 25(22), 2164–2166 (2013)

DOI

14
Mishra, A.K., Schmogrow, R., Tomkos, I., Hillerkuss, D., Koos, C., Freude, W., Leuthold, J.: Flexible RF-based comb generator. IEEE Photonics Technol. Lett. 25(7), 701–704 (2013)

DOI

15
Ozharar, S., Quinlan, F., Ozdur, I., Gee, S., Delfyett, P.J.: Ultraflat optical comb generation by phase-only modulation of continuous-wave light. IEEE Photonics Technol. Lett. 20(1), 36–38 (2008)

DOI

16
Feng, S.C., Fan, Y.Y., Chen, X.Y., Xie, Q., Ren, W.H.: Design of multicarrier optical source using cascaded electro-absorption modulator and phase modulator. Chin. J. Lasers 43(11), 1106001(2016)

DOI

17
Han, Y.S., Zheng, J.W., Fu, C.Y., Zhao, B.S., Lu, M.T.: Design of a light source with ultra wideband and flat multi-carrier. Acta Photonica Sinica 47(5), 0506001(2019)

18
Fan, Y.M., Li, P.L.: Optical frequency comb based on cascaded MZM-EAM with Gaussian-shaped pulse signal. Opt. Eng. 60(5), 056106(2021)

DOI

19
Ujjwal, T.J., Thangaraj, J.: Generation of ultra-wide and flat optical frequency comb based on electro absorption modulator. Optoelectron. Lett. 14(3), 185–188 (2018)

DOI

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