Abstract
Concrete is the most commonly used construction material. The physical properties of concrete vary with the type of concrete, such as high and ultra-high-strength concrete, fibre-reinforced concrete, polymer-modified concrete, and lightweight concrete. The precise prediction of the properties of concrete is a problem due to the design code, which typically requires specific characteristics. The emergence of a new category of technology has motivated researchers to develop mechanical strength prediction models using Artificial Intelligence (AI). Empirical and statistical models have been extensively used. These models require a huge amount of laboratory data and still provide inaccurate results. Sometimes, these models cannot predict the properties of concrete due to complexity in the concrete mix design and curing conditions. To conquer such issues, AI models have been introduced as another approach for predicting the compressive strength and other properties of concrete. This article discusses machine learning algorithms, such as Gaussian Progress Regression (GPR), Support Vector Machine Regression (SVMR), Ensemble Learning (EL), and optimized GPR, SVMR, and EL, to predict the compressive strength of Lightweight Concrete (LWC). The simulation approaches of these trained models indicate that AI can provide accurate prediction models without undertaking extensive laboratory trials. Each model’s applicability and performance were rigorously reviewed and assessed. The findings revealed that the optimized GPR model (R = 0.9803) used in this study had the greatest accuracy. In addition, the optimized SVMR and GPR model showed good performance, with R-values 0.9777 and 0.9740, respectively. The proposed model is economic and efficient, and can be adopted by researchers and engineers to predict the compressive strength of LWC.
Highlights
This article is an open access articleConcrete is the world’s most popular artificial building material and comprises four simple ingredients: cement, water, coarse and fine aggregates
Based on the training process of the machine learning (ML) algorithms, the data were divided into two parts
To where kernel functions are denoted by K(xi, xj ), and the non-negative Lagrange multipliers are represented by ai and ai∗
Summary
Concrete is the world’s most popular artificial building material and comprises four simple ingredients: cement, water, coarse and fine aggregates. Fine and coarse aggregates make approximately 60−75% of the concrete volume, and significantly impact the concrete’s newly mixed and cured characteristics, mixing proportions, and economy. The majority of the present research work has focused on using waste material in concrete distributed under the terms and conditions of the Creative Commons. Sustainability 2022, 14, 2404 dams, tall chimneys, bridges, and multi-storey buildings. Lightweight concrete is extremely important for new construction, as well as repair and rehabilitation projects, among all kinds of concrete. The conventional technique ‘concrete jacketing’ is mainly used to strengthen/retrofit the concrete structures. Replacing the ordinary concrete with lightweight concrete with the same compressive strength can be an alternative solution
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