Interpretable GA-PSO-optimised deep learning for multi-objective geopolymer concrete strength prediction

Q2 Engineering

Asian Journal of Civil Engineering Pub Date : 2025-07-23 DOI:10.1007/s42107-025-01450-4

Neha Sharma, Seema, Sagar Paruthi, Rupesh Kumar Tipu

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Abstract

The study present an interpretable deep-learning framework, optimized using a hybrid Genetic Algorithm-Particle Swarm Optimization (GA-PSO), to predict and enhance the compressive strength of nano-modified geopolymer concrete (GPC). The framework integrates attention-augmented neural networks with SHAP-based explainability, Monte Carlo dropout uncertainty quantification, and surrogate-assisted multi-objective optimisation to simultaneously maximise strength while minimising cost and embodied CO₂ emissions. A curated dataset comprising 234 experimental GPC mixes–incorporating variables such as precursor type, nano-silica dosage, activator content, and curing conditions—was subjected to advanced preprocessing and polynomial feature engineering. A Binary Grey Wolf Optimiser (BGWO) was used for feature selection. The proposed DeepGA-PSO model outperformed conventional regressors (e.g., SVR, Random Forest, XGBoost) with an \(R^2\) of 0.994 and RMSE of 3.86 MPa. Explainability analyses identified curing regime, sodium hydroxide, and nano-silica content as key predictors. Optimisation via NSGA-II yielded Pareto-optimal mix designs suitable for cost-effective and low-carbon construction. A MATLAB-based GUI was developed to facilitate real-time mix design and prediction. This study offers a robust, scalable, and interpretable pipeline for data-driven GPC optimisation and provides a methodological foundation for intelligent infrastructure materials engineering.

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可解释ga - pso优化的深度学习多目标地聚合物混凝土强度预测

该研究提出了一个可解释的深度学习框架，使用混合遗传算法-粒子群优化（GA-PSO）进行优化，以预测和提高纳米改性地聚合物混凝土（GPC）的抗压强度。该框架将注意力增强神经网络与基于shap的可解释性、蒙特卡罗辍学不确定性量化和代理辅助的多目标优化相结合，在最大限度地提高强度的同时，将成本和隐含二氧化碳排放量降至最低。一个由234个实验GPC混合物组成的精心策划的数据集，包括前驱体类型、纳米二氧化硅用量、活化剂含量和固化条件等变量，进行了先进的预处理和多项式特征工程。采用二元灰狼优化器（BGWO）进行特征选择。提出的DeepGA-PSO模型优于传统的回归模型（如SVR、Random Forest、XGBoost），其\(R^2\)为0.994，RMSE为3.86 MPa。可解释性分析确定了固化制度、氢氧化钠和纳米二氧化硅含量是关键的预测因素。通过NSGA-II优化产生了适合于低成本低碳建筑的帕累托最优混合设计。开发了基于matlab的图形用户界面，实现了混合料的实时设计和预测。这项研究为数据驱动的GPC优化提供了一个强大的、可扩展的和可解释的管道，并为智能基础设施材料工程提供了方法论基础。

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来源期刊

Asian Journal of Civil Engineering Engineering-Civil and Structural Engineering

CiteScore

2.70

自引率

0.00%

发文量

121

期刊介绍： The Asian Journal of Civil Engineering (Building and Housing) welcomes articles and research contributions on topics such as:- Structural analysis and design - Earthquake and structural engineering - New building materials and concrete technology - Sustainable building and energy conservation - Housing and planning - Construction management - Optimal design of structuresPlease note that the journal will not accept papers in the area of hydraulic or geotechnical engineering, traffic/transportation or road making engineering, and on materials relevant to non-structural buildings, e.g. materials for road making and asphalt. Although the journal will publish authoritative papers on theoretical and experimental research works and advanced applications, it may also feature, when appropriate: a) tutorial survey type papers reviewing some fields of civil engineering; b) short communications and research notes; c) book reviews and conference announcements.