The use of machine learning in boron-based geopolymers: Function approximation of compressive strength by ANN and GP
Created by W.Langdon from
gp-bibliography.bib Revision:1.8081
- @Article{BAGHERI:2019:Measurement,
-
author = "Ali Bagheri and Ali Nazari and Jay Sanjayan",
-
title = "The use of machine learning in boron-based
geopolymers: Function approximation of compressive
strength by {ANN} and {GP}",
-
journal = "Measurement",
-
volume = "141",
-
pages = "241--249",
-
year = "2019",
-
ISSN = "0263-2241",
-
DOI = "doi:10.1016/j.measurement.2019.03.001",
-
URL = "http://www.sciencedirect.com/science/article/pii/S0263224119302106",
-
keywords = "genetic algorithms, genetic programming,
Boron-activated geopolymer, Artificial intelligence,
Aluminosilicate, Machine learning, Energy and
resources",
-
abstract = "This paper employs artificial intelligence methods in
order to create a function for compressive strength of
the boroaluminosilicate geopolymers based on mixture
proportion variables. Boroaluminosilicate geopolymers
(BASGs), a group of boron-based alkali-activated
materials, not only minimise the carbon footprint in
the construction industry but also decrease the
consumption of energy and natural resources. Australian
fly ash and iron making slag are activated in sodium
and boron-based alkaline medium in order to produce the
geopolymer binders. The current study employs
artificial neural network in order to classify the
collected data into train, test, and validation
followed by genetic programming for developing a
function to approximate the compressive strength of
BASGs. The independent variables comprise the
percentage of fly ash and slag as well as ratios of
boron, silicon, and sodium ions in the alkaline
solution. The performance of each method is assessed by
the acquired regression and the error parameters. The
obtained results show that the percent of silicon and
boron ions, with positive direct correlation and the
largest power in the function respectively, have the
most significant effects on the compressive strength of
BASG. The assessment factors, including R-squared 0.95
and root-mean-square error 0.07 in the testing data,
indicate that the model explains all the variability of
the response data around its mean. It implies a high
level of accuracy and reliability for the model",
- }
Genetic Programming entries for
Ali Bagheri
Ali Nazari
Jay G Sanjayan
Citations