Learning from Sparse Datasets: Predicting Concrete's Strength by Machine Learning

Despite enormous efforts over the last decades to establish the relationship between concrete proportioning and strength, a robust knowledge-based model for accurate concrete strength predictions is still lacking. As an alternative to physical or chemical-based models, data-driven machine learning (ML) methods offer a new solution to this problem. Although this approach is promising for handling the complex, non-linear, non-additive relationship between concrete mixture proportions and strength, a major limitation of ML lies in the fact that large datasets are needed for model training. This is a concern as reliable, consistent strength data is rather limited, especially for realistic industrial concretes. Here, based on the analysis of a large dataset (>10,000 observations) of measured compressive strengths from industrially-produced concretes, we compare the ability of select ML algorithms to "learn" how to reliably predict concrete strength as a function of the size of the dataset. Based on these results, we discuss the competition between how accurate a given model can eventually be (when trained on a large dataset) and how much data is actually required to train this model.

[1]  Flávio Sanson Fogliatto,et al.  Learning curve models and applications: Literature review and research directions , 2011 .

[2]  Fei Huang,et al.  Brief Introduction of Back Propagation (BP) Neural Network Algorithm and Its Improvement , 2012 .

[3]  Ali Abd Elhakam,et al.  Influence of self-healing, mixing method and adding silica fume on mechanical properties of recycled aggregates concrete , 2012 .

[4]  Mathieu Bauchy,et al.  Predicting Young's modulus of oxide glasses with sparse datasets using machine learning , 2019, Journal of Non-Crystalline Solids.

[5]  Mathieu Bauchy,et al.  Predicting the Young’s Modulus of Silicate Glasses using High-Throughput Molecular Dynamics Simulations and Machine Learning , 2019, Scientific Reports.

[6]  Kimberly E. Kurtis,et al.  Alternative Cementitious Materials: Challenges And Opportunities , 2015 .

[7]  Mathieu Bauchy,et al.  Machine learning for glass science and engineering: A review , 2019, Journal of Non-Crystalline Solids.

[8]  Sandor Popovics,et al.  History of a Mathematical Model for Strength Development of Portland Cement Concrete , 1998 .

[9]  Joseph R. Kasprzyk,et al.  Computational design optimization of concrete mixtures: A review , 2018, Cement and Concrete Research.

[10]  T. C. Powers,et al.  Physical Properties of Cement Paste , 1960 .

[11]  S. E. Chidiac,et al.  Assessment of concrete compressive strength prediction models , 2015, KSCE Journal of Civil Engineering.

[12]  Gemma Rodríguez de Sensale,et al.  Strength development of concrete with rice-husk ash , 2006 .

[13]  I-Cheng Yeh,et al.  Modeling of strength of high-performance concrete using artificial neural networks , 1998 .

[14]  Andy Liaw,et al.  Classification and Regression by randomForest , 2007 .

[15]  Jamal M. Khatib,et al.  Factors influencing strength development of concrete containing silica fume , 1995 .

[16]  Mathieu Bauchy,et al.  Direct Carbonation of Ca(OH)2 Using Liquid and Supercritical CO2: Implications for Carbon-Neutral Cementation , 2015 .

[17]  Mathieu Bauchy,et al.  Predicting the dissolution kinetics of silicate glasses by topology-informed machine learning , 2019, npj Materials Degradation.

[18]  Nemkumar Banthia,et al.  Cements in the 21st Century: Challenges, Perspectives, and Opportunities. , 2017, Journal of the American Ceramic Society. American Ceramic Society.

[19]  A. K. Pani,et al.  Data driven soft sensor of a cement mill using generalized regression neural network , 2012, 2012 International Conference on Data Science & Engineering (ICDSE).

[20]  Puneet Gupta,et al.  Can the compressive strength of concrete be estimated from knowledge of the mixture proportions?: New insights from statistical analysis and machine learning methods , 2019, Cement and Concrete Research.

[21]  Phil Purnell,et al.  Embodied carbon dioxide in concrete: Variation with common mix design parameters , 2012 .

[22]  Saeed Khalaf Rejeb,et al.  Improving compressive strength of concrete by a two-step mixing method , 1996 .

[23]  M. Stone Cross‐Validatory Choice and Assessment of Statistical Predictions , 1976 .

[24]  Hojjat Adeli,et al.  Neural Network, Machine Learning, and Evolutionary Approaches for Concrete Material Characterization , 2016 .

[25]  Samir A. Ashour,et al.  FLEXURAL BEHAVIOR OF HIGH-STRENGTH FIBER REINFORCED CONCRETE BEAMS , 1993 .

[26]  Jeffrey W. Bullard,et al.  Machine learning can predict setting behavior and strength evolution of hydrating cement systems , 2019, Journal of the American Ceramic Society.

[27]  Jayadeva,et al.  Deep learning aided rational design of oxide glasses , 2019, Materials Horizons.

[28]  John L. Provis,et al.  Grand Challenges in Structural Materials , 2015, Front. Mater..

[29]  Muhammad Fauzi Mohd. Zain,et al.  Multiple regression model for compressive strength prediction of high performance concrete , 2009 .

[30]  Han Liu,et al.  Balance between accuracy and simplicity in empirical forcefields for glass modeling: Insights from machine learning , 2019, Journal of Non-Crystalline Solids.

[31]  Philip D. Wasserman,et al.  Advanced methods in neural computing , 1993, VNR computer library.

[32]  M. Bauchy,et al.  Predicting the dissolution kinetics of silicate glasses using machine learning , 2017, 1712.06018.

[33]  Nagesh R. Iyer,et al.  Influence of mixing protocol on fresh and hardened properties of self-compacting concrete , 2015 .