On the Thermal Conductivity Assessment of Oil-Based Hybrid Nanofluids using Extended Kalman Filter integrated with feed-forward neural network
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- @Article{JAMEI:2021:IJHMT,
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author = "Mehdi Jamei and Ismail Adewale Olumegbon and
Masoud Karbasi and Iman Ahmadianfar and Amin Asadi and
Mehdi Mosharaf-Dehkordi",
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title = "On the Thermal Conductivity Assessment of Oil-Based
Hybrid Nanofluids using Extended Kalman Filter
integrated with feed-forward neural network",
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journal = "International Journal of Heat and Mass Transfer",
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volume = "172",
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pages = "121159",
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year = "2021",
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ISSN = "0017-9310",
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DOI = "doi:10.1016/j.ijheatmasstransfer.2021.121159",
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URL = "https://www.sciencedirect.com/science/article/pii/S0017931021002623",
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keywords = "genetic algorithms, genetic programming, Nanofluids,
thermal conductivity, oil-based hybrid nanofluids,
Kalman filter, response surface methodology",
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abstract = "Regarding their ability to enhance conventional
thermal oils' thermophysical properties, oil-based
hybrid nanofluids have recently been widely
investigated by researchers, especially on lubrication
and cooling application in the automotive industry.
Thermal conductivity is one of the most crucial
thermophysical properties of oil-based hybrid
nanofluids, which has been studied in a minimal case of
studies on the specific types of them. In this
research, for the first time, a comprehensive
data-intelligence analysis performed on 400 gathered
data points of various types of oil-based hybrid
nanofluids using a novel hybrid machine learning
approach; the Extended Kalman Filter-Neural network
(EKF-ANN). The genetic programming (GP) and response
surface methodology (RSM) approaches were examined to
appraise the main paradigm. In this research, the best
subset regression analysis, as a novel feature
selection scheme, was provided for finding the best
input parameter among all existing predictive variables
(the volume fraction, temperature, thermal conductivity
of the base fluid, mean diameter, and bulk density of
nanoparticles). The provided models were examined using
several statistical metrics, graphical tools and
trends, and sensitivity analysis. The results
assessment indicated that the EKF-ANN in terms of (R =
0.9738, RMSE = 0.0071 W/m.K, and KGE = 0.9630)
validation phase outperformed the RSM (R = 0.9671, RMSE
= 0.0079 W/m.K, and KGE = 0.9593) and GP (R = 0.9465,
RMSE = 0.010 W/m.K, and KGE = 0.9273), for accurate
estimation of the thermal conductivity of oil-based
hybrid nanofluids",
- }
Genetic Programming entries for
Mehdi Jamei
Ismail Adewale Olumegbon
Masoud Karbasi
Iman Ahmadianfar
Amin Asadi
Mehdi Mosharaf-Dehkordi
Citations