Cartesian Genetic Programing Applied to Equivalent Electric Circuit Identification
Created by W.Langdon from
gp-bibliography.bib Revision:1.8129
- @InProceedings{Abud-Kappel:2018:EngOpt,
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title = "Cartesian Genetic Programing Applied to Equivalent
Electric Circuit Identification",
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author = "Marco Andre {Abud Kappel} and
Roberto Pinheiro Domingos and Ivan Napoleao Bastos",
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booktitle = "Proceedings of the 6th International Conference on
Engineering Optimization. EngOpt 2018",
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year = "2018",
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editor = "H. C. Rodrigues and J. Herskovits and
C. M. {Mota Soares} and A. L. Araujo and J. M. Guedes and
J. O. Folgado and F. Moleiro and J. F. A. Madeira",
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pages = "913--925",
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address = "Lisbon, Portugal",
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month = "17-19 " # sep,
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organisation = "Instituto Superior Tecnico",
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publisher = "Springer",
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keywords = "genetic algorithms, genetic programming, Cartesian
Genetic Programming, Differential Evolution, Complex
nonlinear optimization, Equivalent electric circuit
identification",
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isbn13 = "978-3-319-97773-7",
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DOI = "doi:10.1007/978-3-319-97773-7_79",
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abstract = "Equivalent electric circuits are widely used in
electrochemical impedance spectroscopy (EIS) data
modeling. EIS modeling involves the identification of
an electrical circuit physically equivalent to the
system under analysis. This equivalence is based on the
assumption that each phenomenon of the electrode
interface and the electrolyte is represented by
electrical components such as resistors, capacitors and
inductors. This analogy allows impedance data to be
used in simulations and predictions related to
corrosion and electrochemistry. However, when no prior
knowledge of the inner workings of the process under
analysis is available, the identification of the
circuit model is not a trivial task. The main objective
of this work is to improve both the equivalent circuit
topology identification and the parameter estimation by
using a different approach than the usual Genetic
Programming. In order to accomplish this goal, a
methodology was developed to unify the application of
Cartesian Genetic Programming to tackle system topology
identification and Differential Evolution for
optimization of the circuit parameters. The performance
and effectiveness of this methodology were tested by
performing the circuit identification on four different
known systems, using numerically simulated impedance
data. Results showed that the applied methodology was
able to identify with satisfactory precision both the
circuits and the values of the components. Results also
indicated the necessity of using a stochastic method in
the optimization process, since more than one electric
circuit can fit the same dataset. The use of
evolutionary adaptive metaheuristics such as the
Cartesian Genetic Programming allows not only the
estimation of the model parameters, but also the
identification of its optimal topology. However, due to
the possibility of multiple solutions, its application
must be done with caution. Whenever possible,
restrictions on the search space should be added,
bearing in mind the correspondence of the model to the
studied physical phenomena.",
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notes = "XVI Encontro de Modelagem Computacional ?",
- }
Genetic Programming entries for
Marco Andre Abud Kappel
Roberto Pinheiro Domingos
Ivan Napoleao Bastos
Citations