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34. Sverdlov, B., Schmidt, B., Pawlik, S., Mayer, B., and Harder, C., “1 W 980 nm
Pump Modules with Very High Efficiency,” Proceedings of 28th European
Conference on Optical Communications, 5: 1–2, 2002.
35. Bettiati, M., Starck, C., Laruelle, F., Cargemel, V., Pagnod, P., Garabedian,
P., Keller, D., Ughetto, G., Bertreux, J., Raymond, L., Gelly, G., and Capella,
R., “Very High Power Operation of 980-nm Single-Mode InGaAs/AlGaAs
Pump Lasers,” Proc. SPIE, 6104: 61040F-1–61040F-10, 2006.
36. Yang, G., Wong, V., Rossin, V., Xu, L., Everett, M., Hser, J., Zou, D., Skidmore,
J., and Zucker, E., “Grating Stabilized High Power 980 nm Pump Modules,”
Proceedings of Conference on Optical Fiber Communications, JWA30: 1–3, 2007.
37. Bettiati, M., Cargemel, V., Pagnod, P., Hervo, C., Garabedian, P., Issert, P.,
Raymond, L., Ragot, L., Bertreux, J.-C., Reygrobellet, J.-N., Crusson, C., and
Laruelle, F., “Reaching 1W Reliable Output Power on Single-Mode 980 nm
Pump Lasers,” Proc. SPIE, 7198: 71981D-1–71981D-11, 2009.
38. Rossin, V. V., Parke, R., Major, J. S., Perinet, J., Chazan, P., Biet, M., Laffitte, D.,
Sauvage, D., Gulisano, A., Archer, N., and Kendrick, S., “Reliability of 980-nm
Pump Laser Module for Submarine Erbium-Doped Fiber Amplifiers,” Optical
Amplifiers and Their Applications, S. Kinoshita, J. Livas, and G. van den Hoven,
eds., Vol. 30 of Trends in Optics and Photonics, Optical Society of America,
216–219, 1999.
39. Pfeiffer, H.-U., Arlt, S., Jacob, M., Harder, C. S., Jung, I. D., Wilson, F., Oldroyd,
T., and Hext, T., “Reliability of 980 nm Pump Lasers for Submarine, Long Haul
Terrestrial, and Low Cost Metro Applications,” Proceedings of Conference on
Optical Fiber Communications, 483–484, 2002.
40. Van de Casteele, J., Bettiati, M., Laruelle, F., Cargemel, V., Pagnod-Rossiaux,
P., Garabedian, P., Raymond, L., Laffitte, D., Fromy, S., Chambonnet, D., and
Hirtz, J. P., “High Reliability Level on Single-Mode 980 nm–1060 nm Diode
Lasers for Telecommunication and Industrial Application,” Proc. SPIE, 6876:
68760P-1–68760P-8, 2008.
41. Telcordia, Generic Reliability Assurance Requirements for Optoelectronic
Devices Used in Telecommunications Equipment GR-468-CORE, rev 1-2,
December 1998, September 2004, respectively.
42. Wong, V., Rossin, V., Skidmore, J. A., Yalamanchili, P., Qiu, X., Duesterberg,
R., Doussiere, P., Venables, D., Raju, R., Guo, J., Au, M., Zavala, L., Peters,
M., Yang, G., Dai, Y., and Zucker, E. P., “Recent Progress in Fiber-Coupled
Multi-Mode Pump Module and Broad-Area Laser-Diode Performance from
800 to 1500 nm,” Proc. SPIE, 7198: 71980S-1–71980S-8, 2009.
43. Greenhouse, H., Hermeticity of Electronic Packages, Norwich, NY: William
Andrew Publishing, 1999.
44. U. S. Department of Defense, Test Method of Electronic and Electrical Component
Parts, MIL-STD-202G, September 12, 1963.
45. U. S. Department of Defense, Test Method Standard for Microcircuits, MIL-STD-
883E, December 31, 1996.
46. Jakobson, P. A., Sharps, P. J. A., and Hall, D. W., “Requirements to Avert
Packaged Induced Failures (PIF) of High Power 980nm Laser Diodes,” Proc.
LEOS, San Jose, CA, 1993.
47. Gapontsev, V., Moshegov, N., Trubenko, P., Komissarov, A., Berishev, I., Raisky,
O., Strougov, N., Chuyanov, V., Maksimov, O., and Ovtchinnikov, A., “High-
Brightness 9XX-nm Pumps with Wavelength Stabilization,” Proc. SPIE, 7583:
75830A-1–75830A-9, 2010.

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