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Champagne, A., Lestrade, M., Camel, J., Maciejko, R., Tromborg, B., Adams, D. M., & Kasunic, K. J. (2003, January). Side-mode suppression ratio of DFB lasers in presence of a semiconductor optical amplifier [Paper]. Applications of Photonic Technology 6 - Closing the Gap Between Theory, Development, and Applicaton, Montréal, Québec. External link
Champagne, A., Camel, J., Maciejko, R., Kasunic, K. J., Adams, D. M., & Tromborg, B. Spectral Characteristics of DFB Lasers in Presence of a Semiconductor Optical Amplifier [Paper]. Applications of Photonic Technology 5. External link
Champagne, A., Camel, J., Maciejko, R., Kasunic, K. J., Adams, D. M., & Tromborg, B. (2002). Linewidth broadening in a distributed feedback laser integrated with a semiconductor optical amplifier. IEEE Journal of Quantum Electronics, 38(11), 1493-502. External link
Champagne, A., Maciejko, R., Adams, D. M., Pakulski, G., Takasaki, B., & Makino, T. (1999). Global and Local Effects in Gain-Coupled Multiple-Quantum-Well Dfb Lasers. IEEE Journal of Quantum Electronics, 35(10), 1390-1401. External link
Lestrade, M., Champagne, A., Maciejko, R., Kasunic, K. J., & Adams, D. M. Multi-Electrode Complex-Coupled Dfb Lasers for Reduced Spatial Hole Burning [Paper]. Applications of Photonic Technology 6 - Closing the Gap Between Theory, Development, and Applicaton. External link
Lestrade, M., Champagne, A., Maciejko, R., Kasunic, K. J., & Adams, D. M. (2003, January). Time-domain simulation of a multi-electrode complex-coupled DFB laser for reduced spatial hole burning [Paper]. Photonics North 2003, Montréal, Québec. Unavailable
