Learning decision boundaries for cone penetration test classification

Georg H. Erharter; Simon Oberhollenzer; Anna Fankhauser; Roman Marte; Thomas Marcher

doi:10.1111/mice.12662

Learning decision boundaries for cone penetration test classification

Georg H. Erharter^*, Simon Oberhollenzer, Anna Fankhauser, Roman Marte, Thomas Marcher

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

In geotechnical field investigations, cone penetration tests (CPT) are increasingly used for ground characterization of fine-grained soils. Test results are different parameters that are typically visualized in CPT based data interpretation charts. In this paper we propose a novel methodology which is based on supervised machine learning that permits a redefinition of the boundaries within these charts to account for unique soil conditions. We train ensembles of randomly generated artificial neural networks to classify six soil types based on a database of hundreds of CPT tests from Austria and Norway. After training we combine the multiple unique solutions for this classification problem and visualize the new decision boundaries in between the soil types. The generated boundaries between soil types are comprehensible and are a step towards automatically adjusted CPT interpretation charts for specific local conditions.

Original language	English
Pages (from-to)	489-503
Number of pages	15
Journal	Computer-Aided Civil and Infrastructure Engineering
Volume	36
Issue number	4
DOIs	https://doi.org/10.1111/mice.12662
Publication status	Published - Apr 2021

Keywords

CPT
Machine Learning
Supervised Learning
Soil Mechanics

ASJC Scopus subject areas

Civil and Structural Engineering
Computer Science Applications
Computer Graphics and Computer-Aided Design
Computational Theory and Mathematics

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10.1111/mice.12662Licence: CC BY 4.0

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title = "Learning decision boundaries for cone penetration test classification",

abstract = "In geotechnical field investigations, cone penetration tests (CPT) are increasingly used for ground characterization of fine-grained soils. Test results are different parameters that are typically visualized in CPT based data interpretation charts. In this paper we propose a novel methodology which is based on supervised machine learning that permits a redefinition of the boundaries within these charts to account for unique soil conditions. We train ensembles of randomly generated artificial neural networks to classify six soil types based on a database of hundreds of CPT tests from Austria and Norway. After training we combine the multiple unique solutions for this classification problem and visualize the new decision boundaries in between the soil types. The generated boundaries between soil types are comprehensible and are a step towards automatically adjusted CPT interpretation charts for specific local conditions.",

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T1 - Learning decision boundaries for cone penetration test classification

AU - Erharter, Georg H.

AU - Oberhollenzer, Simon

AU - Fankhauser, Anna

AU - Marte, Roman

AU - Marcher, Thomas

PY - 2021/4

Y1 - 2021/4

N2 - In geotechnical field investigations, cone penetration tests (CPT) are increasingly used for ground characterization of fine-grained soils. Test results are different parameters that are typically visualized in CPT based data interpretation charts. In this paper we propose a novel methodology which is based on supervised machine learning that permits a redefinition of the boundaries within these charts to account for unique soil conditions. We train ensembles of randomly generated artificial neural networks to classify six soil types based on a database of hundreds of CPT tests from Austria and Norway. After training we combine the multiple unique solutions for this classification problem and visualize the new decision boundaries in between the soil types. The generated boundaries between soil types are comprehensible and are a step towards automatically adjusted CPT interpretation charts for specific local conditions.

AB - In geotechnical field investigations, cone penetration tests (CPT) are increasingly used for ground characterization of fine-grained soils. Test results are different parameters that are typically visualized in CPT based data interpretation charts. In this paper we propose a novel methodology which is based on supervised machine learning that permits a redefinition of the boundaries within these charts to account for unique soil conditions. We train ensembles of randomly generated artificial neural networks to classify six soil types based on a database of hundreds of CPT tests from Austria and Norway. After training we combine the multiple unique solutions for this classification problem and visualize the new decision boundaries in between the soil types. The generated boundaries between soil types are comprehensible and are a step towards automatically adjusted CPT interpretation charts for specific local conditions.

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KW - Machine Learning

KW - Supervised Learning

KW - Soil Mechanics

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JO - Computer-Aided Civil and Infrastructure Engineering

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Learning decision boundaries for cone penetration test classification

Abstract

Keywords

ASJC Scopus subject areas

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