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
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- IEEE Keywords
- Index Terms
- Optical Amplifier ,
- Spontaneous Emission ,
- Amplified Spontaneous Emission ,
- Material Parameters ,
- Spectral Domain ,
- Resonant Modes ,
- Transfer Matrix ,
- Internal Field ,
- Emission Spectra ,
- Transfer Function ,
- Emission Intensity ,
- Input Signal ,
- Reflection Coefficient ,
- Abscissa ,
- Carrier Density ,
- Rate Equation ,
- Active Zone ,
- Optical Parameters ,
- Adjacent Sections ,
- Resonant Cavity ,
- Non-radiative Recombination ,
- Input Field ,
- Wavelength Division Multiplexing ,
- Increase In Carrier Density ,
- Material Gain ,
- Spectral Dependence ,
- Saturation Intensity ,
- Spatial Averaging ,
- Spontaneous Rate ,
- General Case
Keywords assist with retrieval of results and provide a means to discovering other relevant content. Learn more.
- IEEE Keywords
- Index Terms
- Optical Amplifier ,
- Spontaneous Emission ,
- Amplified Spontaneous Emission ,
- Material Parameters ,
- Spectral Domain ,
- Resonant Modes ,
- Transfer Matrix ,
- Internal Field ,
- Emission Spectra ,
- Transfer Function ,
- Emission Intensity ,
- Input Signal ,
- Reflection Coefficient ,
- Abscissa ,
- Carrier Density ,
- Rate Equation ,
- Active Zone ,
- Optical Parameters ,
- Adjacent Sections ,
- Resonant Cavity ,
- Non-radiative Recombination ,
- Input Field ,
- Wavelength Division Multiplexing ,
- Increase In Carrier Density ,
- Material Gain ,
- Spectral Dependence ,
- Saturation Intensity ,
- Spatial Averaging ,
- Spontaneous Rate ,
- General Case
