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Novel Guess Functions for Efficient Analysis of Raman Fiber Amplifiers
- Publication Year :
- 2012
-
Abstract
- PurposeThe aim of the paper is to demonstrate a fast numerical solution for Raman fiber amplifier equations using proposed guess functions and MATLAB intrinsic properties. MATLAB BVP solvers are addressed for the solution.Design/methodology/approachThe guess functions proposed for the solution of RFA equations using MATLAB BVP solvers are derived from Taylor expansion of pump and signal wave near the boundary to specifically obtain convergence for the initial mesh point. The guess functions increase simulation speed significantly. In order to improve the simulation speed further, vectorization and analytical Jacobians are introduced. Comparisons among bvp4c and bvp5c have been made with respect to total pump power, number of signals, vectorization with/without analytical Jacobians, fiber length, relative tolerance and continuation method. The simulations are performed to determine the effect of the run time on the choice of the number of equally spaced mesh points (N) in the initial guess, and thus optimal N values are found.FindingsMATLAB BVP solvers have been proven to be effective for the numerical solution of RFAs with the proposed guess functions. In particular, with vectorizing, run time reduction is between 2.1 and 5.4 times for bvp4c and between 1.6 and 2.1 times for bvp5c and in addition to vectorizing, with the introduction of the analytical Jacobians, the reduction is between 2.4 and 6.2 times for bvp4c and 1.7 and 2.2 times for bvp5c, respectively, depending on the total pump power between 1,000 mW and 2,000 mW and the number of signals. Also, simulation results show that the efficiency of the solution with proposed guess functions is improved more than six times compared with those of previously reported continuation methods. Results show that the proposed guess functions with the vectorization and analytical Jacobians can be used for the performance evaluation of RFAs for the high power systems/long gain fiber span.Practical implicationsThe robust improvement of the solution proposed in this paper lies in the fact that the derived guess functions for the RFAs are highly effective in the sense that they assist the solver to converge to the solution for any total pump power value in a wide range from 1 to 3,000 mW and for any fiber lengths ranging 1 to 200 km which are used in practical applications. Hence, it is practicable for the performance evaluation of the existing RFA networks.Originality/valueThe novelty of this method is that, starting with the co‐propagating single pump and signal RFA schema, the authors derived the guess function specifically for the initial mesh points rather than using its analytical approximations. Moreover, the solution is generalized for co‐/counter propagating pumps/signals with the curve fitted coefficient(s).
- Subjects :
- Simulation speed
Numerical solution
MATLAB BVP solvers
Boundary (topology)
Engineering, electrical & electronic
MATLAB BVP solvers, Guess functions, Raman fiber amplifiers (RFAs), Boundary value problems, Numerical analysis
Boundary value problems
Engineering
Convergence (routing)
Vectorization
Taylor series
MATLAB
computer.programming_language
Mathematics
Applied Mathematics
Fiber amplifiers
Raman fiber amplifiers (RFAs)
Fiber length
Gain fibers
Taylor expansions
Computer Science Applications
Power (physics)
Computational Theory and Mathematics
Initial guess
Raman fiber amplifiers
Vectorization (mathematics)
symbols
Performance evaluation
Intrinsic property
Algorithm
Signal waves
Numerical analysis
Mesh points
N value
symbols.namesake
Runtimes
Electrical and Electronic Engineering
Fiber Amplifiers
Raman
Wavelength Division Multiplexing
Mathematics, applied
Efficient analysis
Computer science, interdisciplinary applications
Fiber (mathematics)
Continuation method
Design/methodology/approach
Computer science
Analytical approximation
High-power systems
Analytical jacobians
Guess functions
Raman spectroscopy
Single pumps
computer
Pump power
Subjects
Details
- Language :
- English
- Database :
- OpenAIRE
- Accession number :
- edsair.doi.dedup.....4024c212af98e624cc7df996aed8f24b