Performance Comparison of Serial and Parallel Hybrid Fiber Amplifier under Optimum Pump Conditions | ||
Engineering and Technology Journal | ||
Article 16, Volume 40, Issue 2, February 2022, Pages 428-432 PDF (774.18 K) | ||
DOI: 10.30684/etj.v40i2.2183 | ||
Authors | ||
Aseel A. Khudhaier* 1; Abdulla K. Abass2; Mudhafer H. Ali3 | ||
1Laser and Opto-electronic Engineering | ||
2Laser and Optoelectronic Engineering Dept., University of Technology-Iraq, Alsina’a Street, 10066 Baghdad, Iraq. | ||
3Computer Engineering Dept, College of Engineering, Al-Iraqia University, Baghdad, Iraq. | ||
Abstract | ||
In this work, two different configurations of hybrid fiber optic amplifiers are investigated and simulated via OptiSystem 7.0 software, namely, serial and parallel hybrid fiber optical amplifiers (S– and P–HFOAs). The investigation involves performance comparison for the S– and P–HFOA under optimum pump conditions to demonstrate the advantages and disadvantages of each configuration. The simulation results show that the serial configuration has a high average gain level of 19.2 dB, an appropriate noise figure about 4.3 dB, but low saturation power, and limited gain bandwidth of approximately 40 nm, which is considered a primary issue in S–HOFA design, in addition to the pump conversion efficiency still insufficient in the Raman amplifier stage. While in P–HFOA design, a wide 3–dB gain bandwidth of more than 60 nm is maintained, along with an average gain level of 13.5 dB, high average noise figure about 8.3 dB and high saturation power due to the absent of cascading effect in parallel configuration | ||
Highlights | ||
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Keywords | ||
Serial hybrid amplifier; Optimum pump power Parallel hybrid amplifier | ||
References | ||
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