Predicting the Strength of Cement Mortars Containing Natural Pozzolan and Silica Fume Using Multivariate Regression Analysis

Dahish, Hany A.; Bakri, Mudthir; Alfawzan, Mohammed

doi:10.21660/2021.82.j2021

Cited by 11 publications

(5 citation statements)

References 21 publications

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“…The appropriateness of the entire quadratic model for projecting the compressive strength of concrete with steel slag substituted for typical coarse aggregate was evaluated; each parameter is shown in squared, interaction (product), linear, and constant terms; Equation 3a depicts the revealed model for data containing steel slag aggregate and Equation 3b indicates the model for steel slag absent. 51,52 There does not seem to be any evidence linking model predictions to mistaken words.…”

Section: Full Quadratic Modelmentioning

confidence: 90%

“…The appropriateness of the entire quadratic model for projecting the compressive strength of concrete with steel slag substituted for typical coarse aggregate was evaluated; each parameter is shown in squared, interaction (product), linear, and constant terms; Equation depicts the revealed model for data containing steel slag aggregate and Equation indicates the model for steel slag absent 51,52 . There does not seem to be any evidence linking model predictions to mistaken words.

{CS}_{slag contain} goodbreak= β_{0} goodbreak+ β_{1} t goodbreak+ β_{2} \frac{true}{w} goodbreak+ β_{3} normalC goodbreak+ β_{4} FA goodbreak+ β_{5} CA goodbreak+ β_{6} SSA goodbreak+ β_{7} t \frac{true}{w} goodbreak+ β_{8} t normalC goodbreak+ β_{9} t FA goodbreak+ β_{10} t CA goodbreak+ β_{11} t SSA goodbreak+ β_{12} \frac{true}{w} normalC goodbreak+ β_{13} \frac{true}{w} FA goodbreak+ β_{14} \frac{true}{w} CA goodbreak+ β_{15} \frac{true}{w} SSA goodbreak+ β_{16} CFA goodbreak+ β_{17} CCA goodbreak+ β_{18} CSSA goodbreak+ β_{19} FACA goodbreak+ β_{20} FASSA goodbreak+ β_{21} CSSA goodbreak+ β_{22} t^{2} goodbreak+ β_{23} {\frac{w}{c}}^{2} goodbreak+ β_{24} C^{2} goodbreak+ β_{25} {FA}^{2} goodbreak+ β_{26} {CA}^{2} goodbreak+ β_{27} {SSA}^{2},

{CS}_{no slag contain} goodbreak= β_{0} goodbreak+ β_{1} t goodbreak+ β_{2} \frac{true}{w} goodbreak+ β_{3} normalC goodbreak+ β_{4} FA goodbreak+ β_{5} normalC goodbreak+ β_{6} t \frac{true}{w} goodbreak+ β_{7} t normalC goodbreak+ β_{8} t FA goodbreak+ <...

…”

Section: Modelsmentioning

confidence: 99%

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Multifunctional computational models to predict the long‐term compressive strength of concrete incorporated with waste steel slag

Piro

Mohammed

Hamad

et al. 2022

Structural Concrete

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To preserve the environment and natural resources, steel slag recovery conserves natural resources and makes landfill space available. Steel slag as a waste material has been partially substituted for fine (sand) and coarse aggregate in concrete (gravel). Compressive strength (CS) is the most significant mechanical attribute for all forms of concrete composites. To save time, energy, and money, it is essential to create accurate models for forecasting the CS of normal concrete (NC). In addition, it offers essential information for organizing the building work and details the ideal time to remove the formwork. In total, 338 data points were gathered, processed, and modeled in total. During the modeling approach, the most influential elements impacting the compressive strength (CS) of concrete with steel slag replacement were addressed. According to the modeling method, the most effective parameter which affects the compressive strength of normal concrete is the curing time. This research employed a Multi Logistic Regression model (MLR), an Artificial Neural Network (ANN), a Full Quadratic model (FQ), an M5P‐tree model, and an Interaction model to predict the compressive strength of normal strength concrete (CS ranged from 10 to 55 MPa) with steel slag aggregate replacement. According to data from the literature, the steel slag concentration enhanced the compressive strength. Based on evaluations with statistical tools like the objective (OBJ) function, the scatter index, and the Taylar diagram, the ANN model with the lowest root mean square error did better at predicting compressive strength than the other models.

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Section: Full Quadratic Modelmentioning

confidence: 90%

“…The appropriateness of the entire quadratic model for projecting the compressive strength of concrete with steel slag substituted for typical coarse aggregate was evaluated; each parameter is shown in squared, interaction (product), linear, and constant terms; Equation depicts the revealed model for data containing steel slag aggregate and Equation indicates the model for steel slag absent 51,52 . There does not seem to be any evidence linking model predictions to mistaken words.

{CS}_{slag contain} goodbreak= β_{0} goodbreak+ β_{1} t goodbreak+ β_{2} \frac{true}{w} goodbreak+ β_{3} normalC goodbreak+ β_{4} FA goodbreak+ β_{5} CA goodbreak+ β_{6} SSA goodbreak+ β_{7} t \frac{true}{w} goodbreak+ β_{8} t normalC goodbreak+ β_{9} t FA goodbreak+ β_{10} t CA goodbreak+ β_{11} t SSA goodbreak+ β_{12} \frac{true}{w} normalC goodbreak+ β_{13} \frac{true}{w} FA goodbreak+ β_{14} \frac{true}{w} CA goodbreak+ β_{15} \frac{true}{w} SSA goodbreak+ β_{16} CFA goodbreak+ β_{17} CCA goodbreak+ β_{18} CSSA goodbreak+ β_{19} FACA goodbreak+ β_{20} FASSA goodbreak+ β_{21} CSSA goodbreak+ β_{22} t^{2} goodbreak+ β_{23} {\frac{w}{c}}^{2} goodbreak+ β_{24} C^{2} goodbreak+ β_{25} {FA}^{2} goodbreak+ β_{26} {CA}^{2} goodbreak+ β_{27} {SSA}^{2},

{CS}_{no slag contain} goodbreak= β_{0} goodbreak+ β_{1} t goodbreak+ β_{2} \frac{true}{w} goodbreak+ β_{3} normalC goodbreak+ β_{4} FA goodbreak+ β_{5} normalC goodbreak+ β_{6} t \frac{true}{w} goodbreak+ β_{7} t normalC goodbreak+ β_{8} t FA goodbreak+ <...

…”

Section: Modelsmentioning

confidence: 99%

Multifunctional computational models to predict the long‐term compressive strength of concrete incorporated with waste steel slag

Piro

Mohammed

Hamad

et al. 2022

Structural Concrete

View full text Add to dashboard Cite

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“…Multilinear regression was used to formulate the response of the tensile strength and crack width to changes in the amount of water to cement (w/c) and PP fibres [V f (%)]. Multiple regression is an extension of ordinary least-squares (OLS) regression (Dahish et al, 2021), and uses more than one variable to describe the tensile strength and crack width in fibrous cementitious mortar.…”

Section: Analysis Methodsmentioning

confidence: 99%

Effect of polypropylene fibre on cementitious mortar early shrinkage cracking using the eccentric-ring test

et al. 2023

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The effects of polypropylene fibres on mortar and cement-paste cracking were investigated using different amounts of fibre fractions and eccentric rings under restrained-shrinkage conditions. Eccentric-ring tests were conducted to investigate early-age shrinkage cracks. The characteristics of restricted cementitious materials were described by evaluating the cracking time and using concrete mixtures that are less likely to crack. Different fibre-volume fractions significantly enhanced the width, area, and age of cracking. Increasing the water-cement ratio and sand percentage increased the cracking age. The eccentric-ring test showed a greater susceptibility to cracking in cement-mortar composites. The mechanical strength was assessed, and the impact of polypropylene fibres was investigated.

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“…e PQ which is none linear generally contains linear variables and constants; it is effective when such a pattern does not appear to be linear, and the relationships of the variables tend to be curvilinear [16]. Table 8 illustrates the PQ models for the prediction of CBR of granular soil.…”

Section: Pq Modelsmentioning

confidence: 99%

Prediction of California Bearing Ratio of Granular Soil by Multivariate Regression and Gene Expression Programming

Bakri

Aldhari

Alfawzan

2022

Advances in Civil Engineering

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This research demonstrates the results of an investigation into the California bearing ratio (CBR) of granular soils from Qassim region, Saudi Arabia, using multilinear regression (MLR), pure quadratic (PQ) models, and gene expression programming (GEP) methods utilized to develop mathematical models for estimating the CBR based on basic soil index properties. In this study, samples were collected from different borrowing pits in the Qassim area. Forty-three samples of soil were taken and transferred to a laboratory for examination. Seven multilinear regressions and seven PQ models were investigated, while four GEP models were made. The selection of each model variable depends on soil indices, grouping into grain size distribution, Atterberg limits, and compaction parameters. The results of this analysis showed that the PQ model had a higher accuracy [coefficient of determination (R2) = 0.89, root mean square error (RMSE) = 16.006, uncertainty (U95) = 16.17, and reliability = 57%] than the multilinear regression model, which has a lower accuracy model [R2 = 0.811, RMSE = 20.791, U95 = 15.569, and reliability = 51%]. The best GEP model yields [R2 = 0.776, RMSE = 22.552, U95 = 15.787, and reliability = 53%]. Furthermore, sensitivity analysis was conducted to distinguish the influences of different input variables on CBR; it was found that fines percentage (F200), maximum dry density (MDD), and optimum moisture content (OMC) are the most influential variables.

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Predicting the Strength of Cement Mortars Containing Natural Pozzolan and Silica Fume Using Multivariate Regression Analysis

Cited by 11 publications

References 21 publications

Multifunctional computational models to predict the long‐term compressive strength of concrete incorporated with waste steel slag

Multifunctional computational models to predict the long‐term compressive strength of concrete incorporated with waste steel slag

Effect of polypropylene fibre on cementitious mortar early shrinkage cracking using the eccentric-ring test

Prediction of California Bearing Ratio of Granular Soil by Multivariate Regression and Gene Expression Programming

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