Temperature-Dependent Gain Variation Reduction in$C$-Band Erbium-Doped Fiber Amplifier Using Phosphorus-Erbium-Doped Silica Fiber

“…Temperature-dependent gain and noise figure (NF) performances for EDFAs are due to the thermal effect on the re-distribution of ions in the sublevels of the ground and metastable states according to Boltzmann's law, resulting in the temperature-dependent absorption and emission cross-sections [5]. It was reported that EDFAs are more temperature-sensitive when pumped at 1480nm than 980nm [6,7] and more temperature-sensitive in the L-band than in the C-band [8,9]. However, there are few reports on the temperature dependence of EDFAs covering the longer wavelength side of the L-band (up to 1625nm) and few comparative discussions on different pump wavelengths for the L-band EDFAs.…”

Temperature-Dependent Study on L-Band EDFA Characteristics Pumped at 980 nm and 1480 nm in Phosphorus and Aluminum-Rich Erbium-Doped Silica Fibers

“…Temperature-dependent gain and noise figure (NF) performances for EDFAs are due to the thermal effect on the re-distribution of ions in the sublevels of the ground and metastable states according to Boltzmann's law, resulting in the temperature-dependent absorption and emission cross-sections [5]. It was reported that EDFAs are more temperature-sensitive when pumped at 1480nm than 980nm [6,7] and more temperature-sensitive in the L-band than in the C-band [8,9]. However, there are few reports on the temperature dependence of EDFAs covering the longer wavelength side of the L-band (up to 1625nm) and few comparative discussions on different pump wavelengths for the L-band EDFAs.…”

Temperature-Dependent Study on L-Band EDFA Characteristics Pumped at 980 nm and 1480 nm in Phosphorus and Aluminum-Rich Erbium-Doped Silica Fibers

On the Temperature-Dependent Gain and Noise Figure Analysis of C-Band High-Concentration EDFAs With the Effect of Cooperative Upconversion