Anh-Duc Pham scite author profile

Advanced data mining techniques are potential tools for solving civil engineering (CE) problems. This study proposes a novel smart artificial firefly colony algorithm-based support vector regression (SAFCA-SVR) system that integrates firefly algorithm (FA), chaotic maps, adaptive inertia weight, Lévy flight, and least squares support vector regression (LS-SVR). First, adaptive approach and randomization methods are incorporated in FA to construct a novel and highly effective metaheuristic algorithm for global optimization. The enhanced FA is then used to optimize parameters in LS-SVR model. The proposed system is validated by comparing its performance with those of empirical methods and previous works via crossvalidation algorithm and hypothesis test through the realworld engineering cases. Specifically, high-performance concrete, resilient modulus of subgrade soils, and building cooling load are used as case studies. The SAFCA-SVR achieved 8.8%-91.3% better error rates than those of previous works. Analytical results confirm that using the proposed hybrid system significantly improves the accuracy in solving CE problems.

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Shear Strength Prediction in Reinforced Concrete Deep Beams Using Nature-Inspired Metaheuristic Support Vector Regression

Chou

Ngo

Pham

2016

J. Comput. Civ. Eng.

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Bidding strategy to support decision-making by integrating fuzzy AHP and regression-based simulation

Chou

Pham

Wang

2013

Automation in Construction

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Project Management Knowledge of Construction Professionals: Cross-Country Study of Effects on Project Success

Chou

Irawan

Pham

2013

J. Constr. Eng. Manage.

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Optimizing parameters of support vector machine using fast messy genetic algorithm for dispute classification

Chou

Cheng

et al. 2014

Expert Systems with Applications

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Predicting energy consumption in multiple buildings using machine learning for improving energy efficiency and sustainability

Pham

Ngo

Truong

et al. 2020

Journal of Cleaner Production

164

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Predicting Compressive Strength of High-Performance Concrete Using Metaheuristic-Optimized Least Squares Support Vector Regression

Pham

Hoang

Nguyen

2016

J. Comput. Civ. Eng.

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Anh-Duc Pham

Enhanced artificial intelligence for ensemble approach to predicting high performance concrete compressive strength

Smart Artificial Firefly Colony Algorithm‐Based Support Vector Regression for Enhanced Forecasting in Civil Engineering

Shear Strength Prediction in Reinforced Concrete Deep Beams Using Nature-Inspired Metaheuristic Support Vector Regression

Bidding strategy to support decision-making by integrating fuzzy AHP and regression-based simulation

Project Management Knowledge of Construction Professionals: Cross-Country Study of Effects on Project Success

Optimizing parameters of support vector machine using fast messy genetic algorithm for dispute classification

Predicting energy consumption in multiple buildings using machine learning for improving energy efficiency and sustainability

Predicting Compressive Strength of High-Performance Concrete Using Metaheuristic-Optimized Least Squares Support Vector Regression

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