Abstract
A mid-IR amplifier consisting of a tapered chalcogenide fiber coupled to an Er 3+ -doped chalcogenide microsphere has been optimized via a particle swarm optimization (PSO) approach. More precisely, a dedicated three-dimensional numerical model, based on the coupled mode theory and solving the rate equations, has been integrated with the PSO procedure. The rate equations have included the main transitions among the erbium energy levels, the amplified spontaneous emission, and the most important secondary transitions pertaining to the ion-ion interactions. The PSO has allowed the optimal choice of the microsphere and fiber radius, taper angle, and fiber-microsphere gap in order to maximize the amplifier gain. The taper angle and the fiber-microsphere gap have been optimized to efficiently inject into the microsphere both the pump and the signal beams and to improve their spatial overlapping with the rare-earth-doped region. The employment of the PSO approach shows different attractive features, especially when many parameters have to be optimized. The numerical results demonstrate the effectiveness of the proposed approach for the design of amplifying systems. The PSO-based optimization approach has allowed the design of a microsphere-based amplifying system more efficient than a similar device designed by using a deterministic optimization method. In fact, the amplifier designed via the PSO exhibits a simulated gain G=33.7 dB , which is higher than the gain G=6.9 dB of the amplifier designed via the deterministic method.
Highlights
Optical microresonators are key elements for fabrication of a great variety of photonic devices applied in both linear and nonlinear optics
The amplifier designed via the particle swarm optimization (PSO) exhibits a simulated gain G 1⁄4 33.7 dB, which is higher than the gain G 1⁄4 6.9 dB of the amplifier designed via the deterministic method. © The Authors
Their surprising properties are related to the resonance of the well-known whispering gallery modes (WGMs), exhibiting high quality factors Qð105 ÷ 109Þ and small mode volumes
Summary
Optical microresonators are key elements for fabrication of a great variety of photonic devices applied in both linear and nonlinear optics. An accurate three-dimensional mathematical model for Er3þ-doped chalcogenide microspheres[26,27] is employed for calculating the fitness function of the PSO procedure.[23,24,25] The core of the developed numerical code is based on the coupled mode theory and the rate equations model It includes the modal distribution of the optical waves in both tapered fiber and microsphere, and takes into account the most relevant active phenomena in Er3þ-doped chalcogenide glasses, such as the absorption rates at both pump and signal wavelengths, the stimulated emission rate at signal wavelength, the amplified spontaneous emission noise, the lifetime and branching ratios of the considered energy levels, the ion-ion energy transfers, and the excited state absorption. The numerical results underline that due to the high number of design parameters to be optimized, a deterministic solution searching strategy does not allow an efficient design in these kinds of problems
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
