Title :
Adaptive Optical Self-Interference Cancellation Using a Semiconductor Optical Amplifier
Author :
Chang, Matthew P. ; Chia-Lo Lee ; Wu, Ben ; Prucnal, Paul R.
Author_Institution :
Dept. of Electr. Eng., Princeton Univ., Princeton, NJ, USA
Abstract :
We experimentally demonstrate an optical system that uses a semiconductor optical amplifier (SOA) to perform adaptive, analog self-interference cancellation for radio-frequency signals. The system subtracts a known interference signal from a corrupted received signal to recover a weak signal of interest. The SOA uses a combination of slow and fast light and cross-gain modulation to perform precise amplitude and phase matching to cancel the interference. The system achieves 38 dB of cancellation across 60-MHz instantaneous bandwidth and 56 dB of narrowband cancellation, limited by noise. The Nelder-Mead simplex algorithm is used to adaptively minimize the interference power through the control of the semiconductor´s bias current and input optical power.
Keywords :
adaptive optics; light interference; microwave photonics; optical communication equipment; optical information processing; optical modulation; optical noise; semiconductor optical amplifiers; slow light; Nelder-Mead simplex algorithm; SOA; adaptive optical analog self-interference cancellation; amplitude matching; corrupted received signal; cross-gain modulation; fast light; input optical power; interference power; interference signal; noise; optical system; phase matching; radiofrequency signals; semiconductor bias current; semiconductor optical amplifier; slow light; Bandwidth; Delays; Interference; Optical attenuators; Optical receivers; Optical transmitters; Semiconductor optical amplifiers; Self-interference cancellation; co-site interference cancellation; microwave photonics; semiconductor optical amplifier (SOA); slow and fast light;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2015.2405498
