Title :
Effects of intermodulation distortion on the performance of a hybrid radio/fiber system employing a self-pulsating laser diode transmitter
Author :
Kaszubowska, A. ; Barry, L.P. ; Anandarajah, P.
Author_Institution :
Sch. of Electron. Eng., Dublin City Univ., Ireland
fDate :
6/1/2003 12:00:00 AM
Abstract :
A self-pulsating laser is used to generate a multicarrier (five radio frequency (RF) channels) microwave optical signal for use in a hybrid radio/fiber system. The self-pulsation is achieved by external light injection into the laser diode. By varying the RF channel spacing, we have been able to estimate the degradation in system performance due to intermodulation distortion (caused by the nonlinear dynamic response of the laser). The power penalty on the central RF channel is found to be 3.2 dB for operation at the RF band around the laser self-pulsation frequency of 18.5 GHz. We have also characterized the performance of the multicarrier hybrid radio/fiber system in the frequency band corresponding to the inherent relaxation frequency of the laser.
Keywords :
channel spacing; intermodulation distortion; microwave links; microwave photonics; optical fibre networks; optical transmitters; 18.5 GHz; RF band; RF channel spacing; broad-band networks; central RF channel; degradation; external light injection; frequency band; hybrid radio/fiber system; inherent relaxation frequency; intermodulation distortion; laser self-pulsation frequency; microwave optical data signal; multicarrier hybrid radio/fiber system; multicarrier microwave optical signal; nonlinear dynamic response; power penalty; radio frequency channels; radio over fiber distribution network; self-pulsating laser diode transmitter; self-pulsation; Diode lasers; Fiber lasers; Intermodulation distortion; Laser noise; Masers; Microwave generation; Optical transmitters; Radio frequency; Radio transmitters; Signal generators;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2003.811330
