Impact of spontaneously emitted photon on the dynamic behaviors of injection-locked semiconductor lasers

• Autorzy: Fu Y. , Chen J.
• Języki publikacji: EN

Abstrakty

EN

Starting from the mean-field rate equations describing the dynamic behaviors of the slave laser (SL) in the injection-locked master-slave semiconductor laser system (MSL), applying the perturbation method and the Cardan formula, analytical solutions to the evolutions of perturbations from the fixed point have been derived. The dynamic behaviors of the SL perturbed by a spontaneously emitted photon have been analyzed by using the above solutions. Finally, the phase space portraits with different phase between the spontaneously emitted photon and the injection field have also been investigated.

Słowa kluczowe

EN

injection-locked master-slave semiconductor laser; fixed point; dynamic behaviour; phase space portrait; spontaneously emitted photon; analytical solution

• Wydawca: Oficyna Wydawnicza Politechniki Wrocławskiej
• Czasopismo: Optica Applicata
• Rocznik: 2011
• Tom: Vol. 41, nr 1
• Strony: 15--27
• Opis fizyczny: Bibliogr. 21 poz.

Twórcy

autor

Fu Y.

autor

Chen J.

• Department of Optoelectronics, Sichuan University, Chengdu, 610064, China

Bibliografia

• [1] LANG R., Injection locking properties of a semiconductor laser, IEEE Journal of Quantum Electronics 18(6), 1982, pp. 976–983.
• [2] BOCHOVE E.J., Theory of modulation of an injection-locked semiconductor diode laser with applications to laser characterization and communications, Journal of the Optical Society of America B 14(9), 1997, pp. 2381–2391.
• [3] LIU J.M., CHEN H.F., MENG X.J., SIMPSON T.B., Modulation bandwidth, noise, and stability of a semiconductor laser subject to strong injection locking, IEEE Photonics Technology Letters 9(10), 1997, pp. 1325–1327.
• [4] VAINIO M., MERIMAA M., NYHOLM K., Modulation transfer characteristics of injection-locked diode lasers, Optics Communications 267(2), 2006, pp. 455–463.
• [5] GAO X., ZHENG Y., KAN H., SHINODA K., Effective suppression of beam divergence for a high-power laser diode bar by an external-cavity technique, Optics Letters 29(4), 2004, pp. 361–363.
• [6] LAU E.K., SUNG H.K. WU M.C., Scaling of resonance frequency for strong injection-locked lasers,Optics Letters 32(23), 2007, pp. 3373–3375.
• [7] LEE E.K., PANG H.S., PARK J.D., LEE H., Bistability and chaos in an injection-locked semiconductor laser, Physical Review A 47(1), 1993, pp. 736–739.
• [8] TAKIGUCHI Y., OHYAGI K., OHTSUBO J., Bandwidth-enhanced chaos synchronization in strongly injection-locked semiconductor lasers with optical feedback, Optics Letters 28(5), 2003,pp. 319–321.
• [9] XIAOFENG LI, WEI PAN, BIN LUO, DONG MA, YONG WANG, NUOHAN LI, Nonlinear dynamic behaviors of an optically injected vertical-cavity surface-emitting laser, Chaos, Solitons and Fractals 27(5),2006, pp. 1387–1394.
• [10] YUNCAI WANG, GENGWEI ZHANG, ANBANG WANG, Enhancement of chaotic carrier bandwidth in laser diode transmitter utilizing external light injection, Optics Communications 277(1), 2007,pp. 156–160.
• [11] SOMEYA H., OOWADA I., OKUMURA H., KIDA T., UCHIDA A., Synchronization of bandwidth-enhanced chaos in semiconductor lasers with optical feedback and injection, Optics Express 17(22), 2009,pp. 19536–19543.
• [12] HURTADO A., QUIRCE A., VALLE A., PESQUERA L., ADAMS M.J., Nonlinear dynamics induced by parallel and orthogonal optical injection in 1550 nm vertical-cavity surface-emitting lasers (VCSELs),Optics Express 18(9), 2010, pp. 9423–9428.
• [13] YAN SEN LIN, Enhancing the relaxation oscillation frequency of a chaotic semiconductor laser transmitter using optical dual-feedback light, Optics Communications 283(17), 2010,pp. 3305–3309.
• [14] LIPING ZHANG, RUHAI DOU, JIANGUO CHEN, Analysis of the phase-locked laser diode array with an external cavity, Semiconductor Science and Technology 22(12), 2007, pp. 1253–1257.
• [15] TOOMEY J.P., KANE D.M., DAVIDOVIC A., HUNTINGTON E.H., Hybrid electronic/optical synchronized chaos communication system, Optics Express 17(9), 2009, pp. 7556–7561.
• [16] ZHAO Q., WANG Y., WANG A., Eavesdropping in chaotic optical communication using the feedback length of an external-cavity laser as a key, Applied Optics 48(18), 2009, pp. 3515–3520.
• [17] ARGYRIS A., BOGRIS A., HAMACHER M., SYVRIDIS D., Experimental evaluation of subcarrier modulation in chaotic optical communication systems, Optics Letters 35(2), 2010, pp. 199–201.
• [18] KADDOUM G., COULON M., ROVIRAS D., CHARGÉ P., Theoretical performance for asynchronous multi-user chaos-based communication systems on fading channels, Signal Processing 90(11), 2010,pp. 2923–2933.
• [19] VAN TARTWIJK G.H.M., AGRAWAL G.P., Laser instabilities: A modern perspective, Progress inQuantum Electronics 22(2), 1998, pp. 43–122.Impact of spontaneously emitted photon... 27
• [20] AGRAWAL G.P., DUTTA N.K., Semiconductor Lasers, 2nd Edition, Van Nostrand Reinhold, New York, 1993, pp. 238–241.
• [21] MOGENSEN F., OLESEN H., JACOBSEN G., Locking conditions and stability properties for a semiconductor laser with external light injection, IEEE Journal of Quantum Electronics 21(7), 1985,