Generating Mathematical Expressions for Estimation of Atomic Coordinates of Carbon Nanotubes Using Genetic Programming Symbolic Regression
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- @Article{andelic:2023:Technologies,
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author = "Nikola Andelic and Sandi {Baressi Segota}",
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title = "Generating Mathematical Expressions for Estimation of
Atomic Coordinates of Carbon Nanotubes Using Genetic
Programming Symbolic Regression",
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journal = "Technologies",
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year = "2023",
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volume = "11",
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number = "6",
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pages = "Article No. 185",
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keywords = "genetic algorithms, genetic programming",
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ISSN = "2227-7080",
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URL = "https://www.mdpi.com/2227-7080/11/6/185",
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DOI = "doi:10.3390/technologies11060185",
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abstract = "The study addresses the formidable challenge of
calculating atomic coordinates for carbon nanotubes
(CNTs) using density functional theory (DFT), a process
that can endure for days. To tackle this issue, the
research leverages the Genetic Programming Symbolic
Regression (GPSR) method on a publicly available
dataset. The primary aim is to assess if the resulting
Mathematical Equations (MEs) from GPSR can accurately
estimate calculated atomic coordinates obtained through
DFT. Given the numerous hyperparameters in GPSR, a
Random Hyperparameter Value Search (RHVS) method is
devised to pinpoint the optimal combination of
hyperparameter values, maximizing estimation accuracy.
Two distinct approaches are considered. The first
involves applying GPSR to estimate calculated
coordinates (uc, vc, wc) using all input variables
(initial atomic coordinates u, v, w, and integers n, m
specifying the chiral vector). The second approach
applies GPSR to estimate each calculated atomic
coordinate using integers n and m alongside the
corresponding initial atomic coordinates. This results
in the creation of six different dataset variations.
The GPSR algorithm undergoes training via a 5-fold
cross-validation process. The evaluation metrics
include the coefficient of determination (R2), mean
absolute error (MAE), root mean squared error (RMSE),
and the depth and length of generated MEs. The findings
from this approach demonstrate that GPSR can
effectively estimate CNT atomic coordinates with high
accuracy, as indicated by an impressive R2?1.0. This
study not only contributes to the advancement of
accurate estimation techniques for atomic coordinates
but also introduces a systematic approach for
optimising hyperparameters in GPSR, showcasing its
potential for broader applications in materials science
and computational chemistry.",
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notes = "also known as \cite{technologies11060185}",
- }
Genetic Programming entries for
Nikola Andelic
Sandi Baressi Segota
Citations