Predictive Capabilities of Multilayer Perceptron (MLP) in WEKA Algorithm for High Strength Concrete with Steel Fiber Addition-Reference-Cited by-同舟云学术

Predictive Capabilities of Multilayer Perceptron (MLP) in WEKA Algorithm for High Strength Concrete with Steel Fiber Addition

Published:2020-10-27 Issue:2 Volume:1 Page:13-18
ISSN:
Container-title:Journal of Cement Based Composites
language:en
Short-container-title:CEBACOM

Author:

Abubakar Abdulhameed Umar

Abstract

In this study, a neural network based model available in Weka Algorithms, was utilized to test the predictive capacity of compressive strength in high strength concrete (HSC) with steel fiber addition. Fiber addition levels ranged from 0.19 – 2.0% were utilized obtained from literature with a total of 192 instances (datasets) and 10 attributes. To test the performance of the algorithm, a 10 – fold cross-validation method was used to assess the effectiveness which was later compared with full training sets. Also, seven learning schemes were utilized to determine the optimum using percentage split. Results generated from the model include correlation coefficient, mean absolute error, root mean squared error, and relative absolute error. It was observed a good correlation coefficient was obtained which was close to unity at 70-30 and 80-20% of training to testing, and significant reduction in the associated errors were observed. Results for coefficient of determination are also presented and follow the same trend observed in the percentage split results. Time taken to generate the model was much shorter an indication of efficiency.

Publisher

ACA Publishing

Reference31 articles.

1. Simon, M., Lagergren, E. S., Snyder, K. A. (1997). Concrete mixture optimization using statistical mixture design methods. In Proceedings of the PCI/FHWA International Symposium on High Performance Concrete New Orleans, USA.

2. Abdullahi, M., Al-Mattarneh, H.M.A., & Mohammed, B.S. (2009a). Statistical modelling of lightweight concrete mixtures. European Journal of Scientific Research, 31(1), 124–131.

3. Ahmad, S., & Alghamdi, S.A. (2014). A statistical approach to optimizing concrete mixture design. The Science World Journal. http://dx.doi.org/10.1155/2014/561539.

4. Mosaberpanah, M. A., & Eren, O. (2016). Statistical flexural toughness modeling of ultra-high performance concrete using response surface method. Computers and Concrete, 17(4), 1–12.

5. Chou, J.-S. C., & Tsai, C.-F. (2012). Concrete compressive strength analysis using a combined classification and regression technique. Automation in Construction, 24, 52-60.

Cited by 4 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Application of machine learning algorithms to evaluate the influence of various parameters on the flexural strength of ultra-high-performance concrete;Frontiers in Materials;2023-01-06

2. Random Forest Modeling for Fly Ash-Calcined Clay Geopolymer Composite Strength Detection;Journal of Composites Science;2021-10-13

3. Technical Analysis of Twitter Data in Preparation of Prediction using Multilayer Perceptron Algorithm;2021 4th International Conference on Data Science and Information Technology;2021-07-23

4. Multilayer perceptron modelling of geopolymer composite incorporating fly ash and GGBS for prediction of compressive strength;Advances in Materials and Processing Technologies;2021-07-05