Utilization of neural network feedback method to prediction of thermal resistivity of soils

WANG Cai-jin; ZHANG Tao; LUO Jun-hui; MA Chong; DUAN Long-chen

doi:10.11779/CJGE2019S2028

Volume 41 Issue S2

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Chinese Journal of Geotechnical Engineering > 2019 > 41(S2): 109-112. > DOI: 10.11779/CJGE2019S2028

WANG Cai-jin, ZHANG Tao, LUO Jun-hui, MA Chong, DUAN Long-chen. Utilization of neural network feedback method to prediction of thermal resistivity of soils[J]. Chinese Journal of Geotechnical Engineering, 2019, 41(S2): 109-112. DOI: 10.11779/CJGE2019S2028

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Utilization of neural network feedback method to prediction of thermal resistivity of soils

1. Faculty of Engineering,China University of Geosciences, Wuhan 430074, China;
2. Guangxi Communications Design Group Co., Ltd., Nanning 530029, China;
3. School of Mathematics and Physics, China University of Geosciences, Wuhan 430074, China

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Received Date: April 28, 2019
Published Date: July 19, 2019

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Abstract

In order to study the heat transfer characteristics of different soils, the correlation between the thermal resistivity of soil and the main influencing factors is analyzed briefly through the literature data. A prediction model for thermal resistivity of soils by the using neural network is proposed, and the effectiveness and superiority of the proposed model are compared. The measured thermal resistivity is compared with the predicted results of the feedback neural network model. The results show that the feedback neural network can accurately and effectively predict the thermal resistivity of soils. The model adopts dry density, saturation and quartz content as the input parameters, which comprehensively and reasonably reflect the main factors affecting the thermal conductivity of soils. The prediction model has high precision, the correlation coefficient R² of the predicted and measured values is greater than 0.93, the root meansquare error (RMSE) is lower than 28 K∙cm/W, and the variance accounting for (VAF) is greater than 94%. Compared with the traditional empirical relationship, the feedback analysis model has significant advantages in the predicted results in the new environment.
- thermal conduction,
- influencing factors,
- neural network,
- prediction model

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[1]	VAN ROOYEN M.Soil thermal resistivity[D]. New Jersey: Doctoral Thesis, Princeton University, 1958.
[2]	ZHANG T, CAI G J, LIU S Y, el at. Investigation on thermal characteristics and prediction models of soils[J]. International Journal of Heat and Mass Transfer, 2017, 106: 1074-1086.
[3]	KERSTEN M S.Thermal Poperties of Soils[R]. Bulletin: University of MinnesotaInstitute of Technology, Engineering Experiment Station, 28, 1949.
[4]	GANGADHARA RAO M V B B. Soil thermal resistivity[D]. Bombay: Department of Civil Engineering, IIT, 1998.
[5]	DALINAIDU A, SINGH D N.A field probe for measuring thermal resistivity of soils[J], Journal of Geotechnical and Geoenvironmental Engineering, 2004, 130(2): 213-216.
[6]	WANG J, ZHANG X P, DU L Z.A laboratory study of the correlation between the thermal conductivity and electrical resistivity of soil[J]. Journal of Applied Geophysics, 2017, 145: 12-16.
[7]	ORBANIC P, FAJDIGA M.A neural network approach to describing the fretting fatigue in aluminum-steel couplings[J]. International Journal of Fatigue, 2003, 25: 201-207.
[8]	GOH A T C. Back-propagation neural networks for modelling complex systems[J]. Artificial Intelligence in Engineering, 1995, 9: 143-151.
[9]	SHI J J.Reduction prediction error by transforming input data for neural networks[J]. Journal of Computing in Civil Engineering,2000, 18(2): 105-114.
[10]	COTE J, KONRAD J M.A generalized thermal conductivity model for soils and construction materials[J]. Canadian Geotechnical Journal, 2005, 42(2): 443-458.
[11]	JOHANSEN O.Thermal conductivity of soils[D]. Trondheim: University of Trondheim, 1975.

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