Utilizing Optimized Machine Learning Techniques to Predict the Compressive Strength of Concrete through Non-Destructive Testing Methodologies

Swati, Rajesh Gupta, Ravindra Nagar
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Abstract

Examining the concrete quality in its original location and optimizing machine learning models for precise forecasting of concrete compressive strength(fc) is crucial. Current research advocates the fine tuning of hyperparameters within machine learning methodologies in tandem with non-destructive testing techniques to forecast the compressive strength of concrete. This study aimsto incorporate age as a crucial factor by utilizing data spanning from 3 days to 365 days. This approach enhances the study’s applicability for real-time forecasting purposes. In the methodology of this current research, three machine learning (ML) models— specifically, Multi-Linear Regression (MLR), Decision Tree Regressor (DTR), and Random Forest Regressor (RFR)—are introduced within the context of age as a significant factor influencing measurements obtained from the Rebound Hammer (RN) and Ultra Sonic Pulse Velocity (UPV). These ML models were sequentially applied, followed by a meticulous process of hyperparameter finetuning conducted through grid search Cross-Validation (CV). To gain insights into the predictive results, the study also employed SHapley Additive exPlanations (SHAP) for interpretation purposes. The results of this study reveal the development of an empirical relationship using Multi- Linear Regression, which yielded an R2 value of 0.88. Furthermore, the evaluation showed that Random Forest Regression outperformed other models with an R2 value of 0.95 in the training and 0.92 in the testing datasets. These models hold promise for facilitating decisions about qualitative analyses based on UPV and Rebound Hammer measurements relative to the age of the concrete. Rigorous validation of the models was conducted through standard cross-validation techniques. The research has created and validated hyper tunned machine learning models with the help of grid search cross-validation function, with Random Forest Regression being the most effective. These models can potentially guide decisions regarding qualitative analyses using UPV and Rebound Hammer measurements concerning concrete age. They provide a valuable tool for on-site assessments in construction and structural evaluations. The primary objective of the research is to introduce age as a significant feature. To achieve this, data ranging from 3 days to 365 days was integrated. This inclusion aims to enhance real-time decision-making in construction processes, facilitating actions like the prompt removal of formwork in high-speed construction projects.
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利用优化的机器学习技术通过无损检测方法预测混凝土的抗压强度
在原址检测混凝土质量并优化机器学习模型以精确预测混凝土抗压强度(fc)至关重要。目前的研究主张在机器学习方法中结合非破坏性测试技术对超参数进行微调,以预测混凝土的抗压强度。本研究旨在利用 3 天至 365 天的数据,将龄期作为一个关键因素纳入其中。在本研究的方法论中,引入了三种机器学习(ML)模型,即多线性回归模型(MLR)、决策树回归模型(DTR)和随机森林回归模型(RFR),将龄期作为影响回弹仪(RN)和超音速脉冲速度(UPV)测量结果的重要因素。我们依次应用了这些模型,然后通过网格搜索交叉验证(CV)对超参数进行了细致的微调。为了深入了解预测结果,研究还采用了 SHapley Additive exPlanations(SHAP)进行解释。研究结果表明,使用多线性回归建立了经验关系,R2 值为 0.88。此外,评估结果表明,随机森林回归在训练数据集和测试数据集上的 R2 值分别为 0.95 和 0.92,优于其他模型。这些模型有助于根据与混凝土龄期相关的 UPV 和回弹锤测量结果做出定性分析决策。通过标准的交叉验证技术对模型进行了严格的验证。该研究在网格搜索交叉验证功能的帮助下创建并验证了超调机器学习模型,其中随机森林回归最为有效。它们为建筑和结构评估中的现场评估提供了宝贵的工具。研究的主要目的是将龄期作为一个重要特征。为此,我们整合了从 3 天到 365 天的数据。纳入这些数据的目的是加强施工过程中的实时决策,促进在高速施工项目中及时拆除模板等操作。
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来源期刊
Recent Patents on Engineering
Recent Patents on Engineering Engineering-Engineering (all)
CiteScore
1.40
自引率
0.00%
发文量
100
期刊介绍: Recent Patents on Engineering publishes review articles by experts on recent patents in the major fields of engineering. A selection of important and recent patents on engineering is also included in the journal. The journal is essential reading for all researchers involved in engineering sciences.
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Current Status of Research on Fill Mining Systems Overview of Patents on Diamond Polishing Apparatus Evaluation of Land Subsidence Susceptibility in Kunming Basin Based on Remote Sensing Interpretation and Convolutional Neural Network Development and Prospects of Lander Vibration-Damping Structures Recent Patents on Closed Coal Storage Systems and Research of Similar Experimental
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