Abstract:
We present a theoretical investigation of the spectral properties of spontaneous emission in semiconductor optical amplifiers. We use an extended (3/spl times/3) transfer...Show MoreMetadata
Abstract:
We present a theoretical investigation of the spectral properties of spontaneous emission in semiconductor optical amplifiers. We use an extended (3/spl times/3) transfer matrix formalism to derive in the spectral domain an expression for the total longitudinally averaged internal field, which is valid regardless of the levels of optical input and bias current. The material parameters are saturated not only by the monochromatic signal, but also by the amplified spontaneous emission, filtered into the resonance modes of the structure, and integrated over its whole spectral range.
Published in: IEEE Journal of Quantum Electronics ( Volume: 36, Issue: 6, June 2000)
DOI: 10.1109/3.845728
Citations are not available for this document.
Cites in Papers - |
Cites in Papers - IEEE (11)
Select All
1.
Kazuaki Kiyota, "Theoretical Calculation of Amplified Spontaneous Emission in a Distributed Feedback Laser Diode Assisted by a Semiconductor Optical Amplifier", IEEE Journal of Quantum Electronics, vol.56, no.5, pp.1-10, 2020.
2.
Chuan Qin, Dexing Yang, "Numerical Simulation of Ring Cavity Wavelength-Swept Laser Based on Semiconductor Optical Amplifier", IEEE Journal of Quantum Electronics, vol.50, no.10, pp.1-9, 2014.
3.
Pascal Morel, Ammar Sharaiha, "Wideband Time-Domain Transfer Matrix Model Equivalent Circuit for Short Pulse Propagation in Semiconductor Optical Amplifiers", IEEE Journal of Quantum Electronics, vol.45, no.2, pp.103-116, 2009.
4.
G.-X. Chen, W. Li, C.-L. Xu, W.-P. Huang, S.-S. Jian, "Time and spectral domain properties of distributed-feedback-type gain-clamped semiconductor optical amplifiers", IEEE Photonics Technology Letters, vol.18, no.8, pp.932-934, 2006.
5.
Y.G. Boucher, A.-F. Fares, "Analysis and Design of an Active Integrated Mach-Zehnder Interferometer with Semiconductor Optical Amplifiers and External Feedback Loop for All-Optical Self-Switching", 2006 2nd International Conference on Information & Communication Technologies, vol.2, pp.2042-2046, 2006.
6.
A.J. Vickers, S.P. Higgins, "A new model for complex dynamic laser modeling", IEEE Journal of Selected Topics in Quantum Electronics, vol.11, no.5, pp.1236-1241, 2005.
7.
J. Park, Y. Kawakami, X. Li, W.-P. Huang, "Performance simulation and design optimization of superluminescent emitting diodes", NUSOD '05. Proceedings of the 5th International Conference on Numerical Simulation of Optoelectronic Devices, 2005., pp.117-118, 2005.
8.
W. Li, G.X. Chen, P. Huang, X. Li, "An advanced quasi-3D model for semiconductor optical amplifiers", Canadian Conference on Electrical and Computer Engineering 2004 (IEEE Cat. No.04CH37513), vol.4, pp.2131-2134 Vol.4, 2004.
9.
G. Talli, M.J. Adams, "Gain dynamics of semiconductor optical amplifiers and three-wavelength devices", IEEE Journal of Quantum Electronics, vol.39, no.10, pp.1305-1313, 2003.
10.
Y. Boucher, G.S. Sokolovskii, "Near-threshold spectral and spatial characteristics of a curved-grating distributed Bragg reflector laser (c-DBR)", 2003 Conference on Lasers and Electro-Optics Europe (CLEO/Europe 2003) (IEEE Cat. No.03TH8666), pp.199-, 2003.
11.
B. Viallet, E. Daran, G. Lacoste, F. Carcenac, Y. Boucher, "Conception and realisation of a 1.3 /spl mu/m grating-based Nd/sup 3+/-doped optical amplifier", 2003 Conference on Lasers and Electro-Optics Europe (CLEO/Europe 2003) (IEEE Cat. No.03TH8666), pp.681-, 2003.
Cites in Papers - Other Publishers (9)
1.
Yunhong Ding, Xiaobei Zhang, Xinliang Zhang, Dexiu Huang, "Active microring optical integrator associated with electroabsorption modulators for high speed low light power loadable and erasable optical memory unit", Optics Express, vol.17, no.15, pp.12835, 2009.
2.
Alessandro Marques de Melo, Klaus Petermann, "On the amplified spontaneous emission noise modeling of semiconductor optical amplifiers", Optics Communications, vol.281, no.18, pp.4598, 2008.
3.
Gen-xiang CHEN, Wei LI, Cheng-lin XU, Wei-ping HUANG, Shui-sheng JIAN, "Spectral Properties of Fabry-Pérot Laser Diodes and Conventional Semiconductor Optical Amplifiers", The Journal of China Universities of Posts and Telecommunications, vol.13, no.1, pp.63, 2006.
4.
Pascal Morel, Ammar Sharaiha, Romain Brenot, Bruno Thédrez, "Wideband Gain and Noise Figure Modelling in SOA", Optical and Quantum Electronics, vol.38, no.1-3, pp.231, 2006.
5.
Yann G. Boucher, "Theoretical investigation of amplified spontaneous emission in an active structure by extended (3x3) transfer matrix formalism: the case of a non-uniform longitudinal distribution of emitters", Journal of the European Optical Society: Rapid Publications, vol.1, 2006.
6.
S. Betti, C. Bulli, F. Curti, E. Duca, S. Persia, A. Reale, G. M. Tosi‐Beleffi, "Optical clock recovery from 10‐Gb/s NRZ signal", Microwave and Optical Technology Letters, vol.42, no.6, pp.435, 2004.
7.
Y G Boucher, A G Deryagin, V I Kuchinskii, G S Sokolovskii, "Threshold crossing and spectral properties of a curved-grating distributed Bragg reflector quantum-well laser (c-DBR)", Semiconductor Science and Technology, vol.19, no.8, pp.1010, 2004.
8.
Y Boucher, A G Deryagin, V I Kuchinskii, G S Sokolovskii, "Near-threshold spectral and modal characteristics of a curved-grating quantum-well distributed-feedback laser", Nanotechnology, vol.14, no.6, pp.615, 2003.
9.
Y. Boucher, O. Dellea, "Amplified spontaneous emission and threshold crossing in a distributed-Bragg reflector grating-coupled surface-emitting laser", IEE Proceedings - Optoelectronics, vol.148, no.1, pp.25-30, 2001.
