Razavi, S.V. and Jumaat, Mohd Zamin and Ei-Shafie, A.H. and Mohammadi, P. (2011) Artificial neural networks for mechanical strength prediction of lightweight mortar. Scientific Research and Essays, 6 (16). pp. 3406-3417. ISSN 19922248, DOI https://doi.org/10.5897/SRE11.311.
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Abstract
In this paper, the practical results of mechanical strength of different lightweight mortars made with 0, 5,10, 15, 20, 25, 30, 35, 40, 45, 50,55, 60, 65, 70, 75, 80, 85, 90, 95 and 100 of scoria instead of sand and 0.55 water-cement ratio and 350 kg/m3 cement content have been used to generate artificial neural networks (ANNs). Totally, 52 feed-forward back-propagation neural networks (FFBNN) with different parameters have been investigated in the case of 80 data for training, 15 data for verifying, and 10 data for testing. The performance for producing networks was evaluated by root mean squared error (RMSE) and the correlation coefficient between data. The two selected networks, N1 (Net Architecture 2-10-2) and N2 (Net Architecture 2-10-5-2) had (0.020, 0.027) and (0.017, 0.018) as (Training, Testing) RMSE set and 0.997 and 0.982 as testing correlation coefficient.
Item Type: | Article |
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Funders: | UNSPECIFIED |
Additional Information: | Cited By (since 1996): 1 Export Date: 6 January 2013 Source: Scopus Language of Original Document: English Correspondence Address: Razavi, S. V.; Civil Engineering Department, University MalaysiaMalaysia; email: Vahidrazavy@yahoo.com References: Abedi, J., Mollahi, A., An Investigation in Mechanical Property of Lightweight Concrete with Rice Stalk (2005) 2nd International Conferences on Concrete & Development, p. 112. , Tehran. Iran; Ahmet, O., Murat, P., Erdog, O., Erdog, K., Naci, Ã�., Asghar, M.B., Predicting the compressive strength and slump of high strength concrete using neural network (2006) Constr. Building Mater, 9, pp. 769-775; Aydin, A.C., Karakoç, M.B., Düzgün, O.A., Bayraktutan, M.S., Effect of low quality aggregates on the mechanical properties of lightweight concrete (2010) Scientific Research and Essays, 5, pp. 1133-1140; Ayman, A.S., A neural network model for predicting maximum shear capacity of concrete beams without transverse reinforcement (2005) Canadian J. Civil Eng., 32, pp. 44-57; (1996) Eurocode 6 - Design of Masonry Structures, , BRITISH STANDARDS INSTITUTION. BS EN; Carpenter, W.C., Barthelemy, J.F., Common Misconceptions about Neural Networks as Approximators (1994) ASCE J. Comput. Civil Eng., 8, pp. 345-358; Carpenter, W., Hoffman, M., Training backprop neural networks (1995) JAI Expert, pp. 30-33; Dias, W.P.S., Pooliyadda, S.P., Neural networks for predicting properties of concretes with admixtures (2001) Constr Build Mater, 15, pp. 371-379; Famili, H., (1997) A Project About Lightweight Concrete, , University of Elmo-sanat publishers. Iran. Tehran; Gadea, J., RodrÃguez, A., Campos, P.L., Garabito, J., Calderón, V., Lightweight mortar made with recycled polyurethane foam (2010) Cement and Concrete Composites, 32, pp. 672-677; Guang, N.H., Zong, W.J., Prediction of compressive strength of concrete by neural networks (2000) Cem Concr Res, 30, pp. 1245-1250; Haykin, S., (1999) Neural Networks: A Comprehensive Foundation, , Prentice Hall Inc. Englewood Cliffs.N.J; Hornik, K., Maxwell, S., White, H., Universal Approximation of an Unknown Mapping and its Derivative using Multilayer Feedforward Networks (1990) Neural Networks, 3, pp. 551-560; Ilker, B.T., Mustafa, S., Prediction of properties of waste AAC aggregate concrete using artificial neural network (2007) Computational Materials Sci, 41 (1), pp. 117-125. , EskiÅ�ehir Osmangazi University. Department of Civil Engineering. Turkey; Joachim, S., Influence of water-cement ratio and cement content on the properties of polymer-modified mortars (1999) Cement Concr. Res., 29, pp. 909-915; Kasperkiewics, J., Racz, J., Dubrawski, A., HPC strength prediction using ANN (1995) ASCE J. Comput. Civil Eng., 9, pp. 279-284; Lai, S., Sera, M., Concrete strength prediction by means of neural network (1997) Constr Build Mater, 11, pp. 93-98; Lee, S.C., Prediction of concrete strength using artificial neural Networks (2003) Eng Struct, 25, pp. 849-857; Lin, Y., Lai, C.P., Yen, T., Prediction of ultrasonic pulse velocity (UPV) in concrete (2003) ACI Materials J, 100, pp. 21-28; Lo, T.Y., Cui, H.Z., Effect of porous lightweight aggregate on strength of concrete (2004) MaterialsLetters.58, pp. 916-919; Marcos, L., GarcÃa-Ruiz, P.A., Lightweight cement mortars: Advantages and inconveniences of expanded perlite and its influence on fresh and hardened state and durability (2008) Construction and Building Materials, 22, pp. 1798-1806; Marcos, L.T., GarcÃa-Ruiz, P.A., Lightweight pozzolanic materials used in mortars: Evaluation of their influence on density (2009) Mechanical strength and water absorption. Cement and Concrete Composites., 31, pp. 114-119; Maru, S., Nagpal, A.K., Neural network for creep and shrinkage deflections in reinforced concrete frames (2004) J. Computing in Civil Engineering. ASCE, 18 (4), pp. 350-359; McCullagh, P., Nelder, J.A., (1989) Generalized Linear Models, , 2nd ed. London: Chapman & Hall; Merikallio, T., Mannonen, R., Drying of Lightweight Concrete Produced From Crushed Expended Clay Aggregates (1996) Com Concer Res, 26, pp. 1423-1433; Mukherjee, A., Deshpande, J.M., Modelling Initial Design Process using Artificial Neural Networks (1995) ASCE Computing in Civil Engineering, 7 (1), pp. 556-559; Oreta, A.W.C., Kawashima, K., Neural network modeling of confined compressive strength (2003) J. Struct Eng., 129, pp. 554-561; Oreta, A.W.C., Kawashima, K., Neural network modeling of confined compressive strength and strain of circular concrete columns (2003) ASCE J. Struct. Eng., 129 (4), pp. 554-561; Rajagopalan, P.R., Prakash, J., Naramimhan, V., Correlation between ultrasonic pulse velocity and strength of concrete (1973) Indian Concrete J, 47, pp. 416-418; Reda, M.M.T., Noureldin, A., El-Sheimy, N., Shrive, N.G., Artificial neural networks for predicting creep with an example application to structural masonry (2003) Canadian J. Civil Eng., 30, pp. 523-532; Ripley, B.D., (1996) Pattern Recognition and Neural Networks, , Cambridge University Press. New York; Sanahi, G., (1998) Application of Perlit in Construction Process, , Master Dissertation. University of Tabriz. Tabriz. Iran; Sari, D., Pasamehmetoglu, A., (2004) The Effect of Grading and Admixture on the Pumice Lightweight Aggregate Concrete, 35 (5), pp. 936-942. , 2nd Department of Civil Engineering. Atilim University. Ankara. Turkey, Cement and Concrete Res; Shideler, J., Lightweight Aggregate Concrete for Structural Use (1975) ACI J, 54, pp. 299-328; Shorabi, M., Rigi, A., Application of Lightweight Concrete Properties with Lightweight Grain of Taftan in Construction Methoh (2005) 2nd International Conferences on Concrete & Development, p. 109. , Tehran. Iran; Short, M., Kinniburgh, W., Lightweight Concrete (1978), pp. 443-455. , Applied Science Publishers LondonTopcu, I.B., Odler, I., Semi lightweight concretes produced by volcanic slags (1996) Cement and Concrete Research, pp. 15-21; Unal, O., Uygunog, T.Y.A., Investigation of properties of low strength lightweight concrete for thermal insulation (2007) Building and Environment, 42, pp. 584-590; Yeh, I.C., Modeling of strength of HPC using ANN (1998) Cem Concr Res, 28 (12), pp. 1797-1808; Yu-Ling, W., Jing-Chiang, Y., Yong-Yang, L., Shih-Yu, C., Paul, H.W., Recycling of harbor sediment as lightweight aggregate (2008) 5th International Conference on Marine Pollution and Ecotoxicology, 57, pp. 867-872. , Marine Pollution Bulletin; Wasserman, R., Bentur, A., Interfacial interactions in lightweight aggregate concretes and their influence on the concrete strength (1996) Cement and Concrete Composites, 18, pp. 67-76; Wu, X., Lim, S.Y., (1993) Prediction Maximum Scour Depth at the Spur Dikes with Adaptive Neural Networks, pp. 61-66. , Neural networks and combinatorial optimization in civil and structural engineering. Civil-Comp Press |
Uncontrolled Keywords: | Artificial neural networks, Feed-forward back-propagation neural networks, Scoria. |
Subjects: | T Technology > TA Engineering (General). Civil engineering (General) |
Divisions: | Faculty of Engineering |
Depositing User: | Mr Jenal S |
Date Deposited: | 29 Apr 2013 02:13 |
Last Modified: | 05 Feb 2020 04:37 |
URI: | http://eprints.um.edu.my/id/eprint/5942 |
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