Influential Parameters in Estimating Soil Properties from Cone Penetrating Test: An Artificial Neural Network Study
The Cone Penetration Test (CPT) is a common in-situ
test which generally investigates a much greater volume of soil more
quickly than possible from sampling and laboratory tests. Therefore,
it has the potential to realize both cost savings and assessment of soil
properties rapidly and continuously. The principle objective of this
paper is to demonstrate the feasibility and efficiency of using
artificial neural networks (ANNs) to predict the soil angle of internal
friction (Φ) and the soil modulus of elasticity (E) from CPT results
considering the uncertainties and non-linearities of the soil. In
addition, ANNs are used to study the influence of different
parameters and recommend which parameters should be included as
input parameters to improve the prediction. Neural networks discover
relationships in the input data sets through the iterative presentation
of the data and intrinsic mapping characteristics of neural topologies.
General Regression Neural Network (GRNN) is one of the powerful
neural network architectures which is utilized in this study. A large
amount of field and experimental data including CPT results, plate
load tests, direct shear box, grain size distribution and calculated data
of overburden pressure was obtained from a large project in the
United Arab Emirates. This data was used for the training and the
validation of the neural network. A comparison was made between
the obtained results from the ANN's approach, and some common
traditional correlations that predict Φ and E from CPT results with
respect to the actual results of the collected data. The results show
that the ANN is a very powerful tool. Very good agreement was
obtained between estimated results from ANN and actual measured
results with comparison to other correlations available in the
literature. The study recommends some easily available parameters
that should be included in the estimation of the soil properties to
improve the prediction models. It is shown that the use of friction
ration in the estimation of Φ and the use of fines content in the
estimation of E considerable improve the prediction models.
[1] Robertson, P.K.., Guide to Cone Penetration Testing. Signal Hill: Gregg
Drilling & Testing, 2010.
[2] Zervogiannis, C.S. and Kalteziotis, N.A. (1988), “Experience and
Relationships from Penetration Testing in Greece”, International
Symposium on Penetration Testing, ISOPT-1, Orlando, 2, 1063-71,
Balkema Pub., Rotterdam.
[3] Burt Look, "Handbook of Geotechnical Investigation and Design
Tables." (2007)
[4] Cem Ozan July 2003, "Estimation of Grain Characteristics of Soils by
Using Cone Penetration Test (Cpt) Data." MSc. Thesis, The Graduate
School of Natural and Applied Sciences of The Middle East Technical
University, Turkey.
[5] Salehzadeh H., Hozouri A., Golestani A.R., "Correlation between Cone
and Standard Penetration tests." 5th SASTech 2011, Khavaran Highereducation
Institute, Mashhad, Iran. May 12-14.
[6] Abu Kiefa M.A (1997), “Prediciting The Driven Pile Capacity on
Cohessionless Soil by Neural Networks. Pro. Of 3rd Int. Geotechnical
Eng. Cof., Cairo University, 5-8 January, Cairo Egypt, pp.227-240.
[7] Abu Kiefa M.A (1998a), “General Regression Neural Networks for
Driven Piles in Cohessionless Soil.” Journal of Geotechnical and
Geoenvironmental Engineering, ASCE, Vol. 124, No. 12, Dec., pp.
1177-1185. [8] Abu Kiefa M.A (1998b), “Artificial Neural Networks: A New Tool for
Solving Geotechnical Engineering Problems.” 8th Int. Colloquium on
Structural and Geotechnical Engineering, Ain Shams University, Dec.
15-17, Vol. III, pp. 16-26.
[9] Abu Kiefa M.A (1998c), “Evaluation of Bearing Capacity Failure
Modes in Shallow Foundations using Fuzzy Logic” 8th Int. Colloquium
on Structural and Geotechnical Engineering, Ain Shams University,
Cairo, Egypt, pp. 39-50.
[10] Abu Kiefa M.A (2000a), “Stage Construction Control of Embankment
on Soft Subsoil by Neural Network. ” 4th Int. Geotechnical Eng. Conf.,
Cairo University, 24-27 January, Cairo, Egypt.
[11] Abu Kiefa M.A (2000a), “Applications of Networks in Geotechnical
Engineering,” State of Art Research Submitted to obtain Scientific
degree of Professorship, Cairo University.
[12] Abu El Naga, H.M. (2001), “Calibration of Dynamic Con Results in
Cohessionless Soils Using Artificial Neural Network,” M. Sc. Thesis,
Cairo University, Egypt.
[13] Gribb, M.M., and Gribb, G.W.(1994), “Use of Neural Networks for
Hydraulic Conductivity Determination in Unsaturated Soil.” Proc. 2nd
International Conference on Ground Water Ecology, Atlanta (eds.
Standford, J.A Vallet H.M.), Bethesda MD: Amer, Water Resources.,
pp.155-163.
[14] V. Varghese, S. S. Babu, R. Bijukumar, S. Cyrus _ B. M. Abraham,
"Artificial Neural Networks: A Solution to the Ambiguity in Prediction
of Engineering Properties of Fine-Grained Soils", Springer Science,
Geotech Geol Eng (2013) 31, April 2013.
[15] F. Isik, G. Ozden, "Estimating compaction parameters of fine- and
coarse-grained", Springer-Verlag Berlin Heidelberg 2012, Environ Earth
Sci (2013) 69:2287–2297, Oct. 2012.
[16] Bozbey, E. Togrol, "Correlation of standard penetration test and
pressuremeter data: a case study from Istanbul, Turkey", Springer-
Verlag 2009, Bull Eng Geol Environ (2010) 69:505–515, Oct. 2009.
[17] Bojana Dolinar, "Predicting the normalized, undrained shear strength of
saturated fine-grained soils using plasticity-value correlations soils by
means of artificial neural networks", 2009 Elsevier B.V, University of
Maribor.
[18] D. Singh, M.Zaman and s. Commuri, "Artificial Neural Network
Modeling for Dynamic Modulus of Hot Mix Asphalt Using Aggregate
Shape Properties", Journal of Geotechnical and Geoenvironmental
Engineering, ASCE, Civ. Eng. 2013.25, Jan. 2013, pp 54-62.
[19] Ceryan, N, Okkan, U, and Kesimal, A. (2012) "Application of
Generalized Regression Neural Networks in Predicting the Unconfined
Compressive Strength of Carbonate Rocks" Rock Mech Rock Eng, V45:
1055-1072.
[20] Hasanadehshooiili, H. Lakirouhani, A. and Medzvieckas, J. (2012)
"Superiority of Artificial Neural Networks over Statistical methods in
prediction of the optimal length of Rock Bolts", V18(5):655-661.
[21] Akca, N. 2003. Correlation of SPT-CPT Data From United Arab
Emarites. Engineering Geology. V67. 219-231.
[22] Chin, C.T., Duann, S.W. and Kao, T.C. (1988), “SPT-CPT Correlations
for Granular Soils”, International Symposium on Penetration Testing,
ISOPT-1, Orlando, 1, 335-9.
[23] Danziger, F.A.B. et al. 1998. "CPT-SPT Correlations for some
Barazilian Residual Soils." In Rebertson & Mayne (eds), Geotechnical
site characterization: 907-912. Rotterdam: Balkema.
[24] Mahmoud Elbanna and Joseph Quinn (2011), "SPT – CPT Correlations
for Oilsands Tailings Sand." Klohn Crippen Berger Ltd., Canada.
[25] Hykin, S. (1994), “Neural Networks: A Comprehesive Foundation” NY:
Macmillan, pp. 2.
[26] Lin, Lee, "Neuro-fuzzy synergism to intelligent systems", National
Chiao Tung University, 1996.
[27] Goh, A.T.C. (1995a), “Back propagation Neural Networks for Modeling
Complex System,” Artificial Intelligence in Engineering, Vol.9, no.3,
PP.143-151.
[28] Goh, A.T.C. (1995b), “Empirical Design in Geotechnics using Neural
Networks,” Geotechnique, Vol.45, no.4, pp.709-714.
[29] Goh, A.T.C. (1995c), “Modeling Soil Correlations using Neural
Networks” Journal of Computing in Civil Engineering, Vol.9, no.4,
pp.275-278.
[30] Specht, D.F. 1991. "A general regression neural network." IEEE Trans.
Neural Networks, 2(6), 568-576.
[1] Robertson, P.K.., Guide to Cone Penetration Testing. Signal Hill: Gregg
Drilling & Testing, 2010.
[2] Zervogiannis, C.S. and Kalteziotis, N.A. (1988), “Experience and
Relationships from Penetration Testing in Greece”, International
Symposium on Penetration Testing, ISOPT-1, Orlando, 2, 1063-71,
Balkema Pub., Rotterdam.
[3] Burt Look, "Handbook of Geotechnical Investigation and Design
Tables." (2007)
[4] Cem Ozan July 2003, "Estimation of Grain Characteristics of Soils by
Using Cone Penetration Test (Cpt) Data." MSc. Thesis, The Graduate
School of Natural and Applied Sciences of The Middle East Technical
University, Turkey.
[5] Salehzadeh H., Hozouri A., Golestani A.R., "Correlation between Cone
and Standard Penetration tests." 5th SASTech 2011, Khavaran Highereducation
Institute, Mashhad, Iran. May 12-14.
[6] Abu Kiefa M.A (1997), “Prediciting The Driven Pile Capacity on
Cohessionless Soil by Neural Networks. Pro. Of 3rd Int. Geotechnical
Eng. Cof., Cairo University, 5-8 January, Cairo Egypt, pp.227-240.
[7] Abu Kiefa M.A (1998a), “General Regression Neural Networks for
Driven Piles in Cohessionless Soil.” Journal of Geotechnical and
Geoenvironmental Engineering, ASCE, Vol. 124, No. 12, Dec., pp.
1177-1185. [8] Abu Kiefa M.A (1998b), “Artificial Neural Networks: A New Tool for
Solving Geotechnical Engineering Problems.” 8th Int. Colloquium on
Structural and Geotechnical Engineering, Ain Shams University, Dec.
15-17, Vol. III, pp. 16-26.
[9] Abu Kiefa M.A (1998c), “Evaluation of Bearing Capacity Failure
Modes in Shallow Foundations using Fuzzy Logic” 8th Int. Colloquium
on Structural and Geotechnical Engineering, Ain Shams University,
Cairo, Egypt, pp. 39-50.
[10] Abu Kiefa M.A (2000a), “Stage Construction Control of Embankment
on Soft Subsoil by Neural Network. ” 4th Int. Geotechnical Eng. Conf.,
Cairo University, 24-27 January, Cairo, Egypt.
[11] Abu Kiefa M.A (2000a), “Applications of Networks in Geotechnical
Engineering,” State of Art Research Submitted to obtain Scientific
degree of Professorship, Cairo University.
[12] Abu El Naga, H.M. (2001), “Calibration of Dynamic Con Results in
Cohessionless Soils Using Artificial Neural Network,” M. Sc. Thesis,
Cairo University, Egypt.
[13] Gribb, M.M., and Gribb, G.W.(1994), “Use of Neural Networks for
Hydraulic Conductivity Determination in Unsaturated Soil.” Proc. 2nd
International Conference on Ground Water Ecology, Atlanta (eds.
Standford, J.A Vallet H.M.), Bethesda MD: Amer, Water Resources.,
pp.155-163.
[14] V. Varghese, S. S. Babu, R. Bijukumar, S. Cyrus _ B. M. Abraham,
"Artificial Neural Networks: A Solution to the Ambiguity in Prediction
of Engineering Properties of Fine-Grained Soils", Springer Science,
Geotech Geol Eng (2013) 31, April 2013.
[15] F. Isik, G. Ozden, "Estimating compaction parameters of fine- and
coarse-grained", Springer-Verlag Berlin Heidelberg 2012, Environ Earth
Sci (2013) 69:2287–2297, Oct. 2012.
[16] Bozbey, E. Togrol, "Correlation of standard penetration test and
pressuremeter data: a case study from Istanbul, Turkey", Springer-
Verlag 2009, Bull Eng Geol Environ (2010) 69:505–515, Oct. 2009.
[17] Bojana Dolinar, "Predicting the normalized, undrained shear strength of
saturated fine-grained soils using plasticity-value correlations soils by
means of artificial neural networks", 2009 Elsevier B.V, University of
Maribor.
[18] D. Singh, M.Zaman and s. Commuri, "Artificial Neural Network
Modeling for Dynamic Modulus of Hot Mix Asphalt Using Aggregate
Shape Properties", Journal of Geotechnical and Geoenvironmental
Engineering, ASCE, Civ. Eng. 2013.25, Jan. 2013, pp 54-62.
[19] Ceryan, N, Okkan, U, and Kesimal, A. (2012) "Application of
Generalized Regression Neural Networks in Predicting the Unconfined
Compressive Strength of Carbonate Rocks" Rock Mech Rock Eng, V45:
1055-1072.
[20] Hasanadehshooiili, H. Lakirouhani, A. and Medzvieckas, J. (2012)
"Superiority of Artificial Neural Networks over Statistical methods in
prediction of the optimal length of Rock Bolts", V18(5):655-661.
[21] Akca, N. 2003. Correlation of SPT-CPT Data From United Arab
Emarites. Engineering Geology. V67. 219-231.
[22] Chin, C.T., Duann, S.W. and Kao, T.C. (1988), “SPT-CPT Correlations
for Granular Soils”, International Symposium on Penetration Testing,
ISOPT-1, Orlando, 1, 335-9.
[23] Danziger, F.A.B. et al. 1998. "CPT-SPT Correlations for some
Barazilian Residual Soils." In Rebertson & Mayne (eds), Geotechnical
site characterization: 907-912. Rotterdam: Balkema.
[24] Mahmoud Elbanna and Joseph Quinn (2011), "SPT – CPT Correlations
for Oilsands Tailings Sand." Klohn Crippen Berger Ltd., Canada.
[25] Hykin, S. (1994), “Neural Networks: A Comprehesive Foundation” NY:
Macmillan, pp. 2.
[26] Lin, Lee, "Neuro-fuzzy synergism to intelligent systems", National
Chiao Tung University, 1996.
[27] Goh, A.T.C. (1995a), “Back propagation Neural Networks for Modeling
Complex System,” Artificial Intelligence in Engineering, Vol.9, no.3,
PP.143-151.
[28] Goh, A.T.C. (1995b), “Empirical Design in Geotechnics using Neural
Networks,” Geotechnique, Vol.45, no.4, pp.709-714.
[29] Goh, A.T.C. (1995c), “Modeling Soil Correlations using Neural
Networks” Journal of Computing in Civil Engineering, Vol.9, no.4,
pp.275-278.
[30] Specht, D.F. 1991. "A general regression neural network." IEEE Trans.
Neural Networks, 2(6), 568-576.
@article{"International Journal of Architectural, Civil and Construction Sciences:69329", author = "Ahmed G. Mahgoub and Dahlia H. Hafez and Mostafa A. Abu Kiefa", title = "Influential Parameters in Estimating Soil Properties from Cone Penetrating Test: An Artificial Neural Network Study", abstract = "The Cone Penetration Test (CPT) is a common in-situ
test which generally investigates a much greater volume of soil more
quickly than possible from sampling and laboratory tests. Therefore,
it has the potential to realize both cost savings and assessment of soil
properties rapidly and continuously. The principle objective of this
paper is to demonstrate the feasibility and efficiency of using
artificial neural networks (ANNs) to predict the soil angle of internal
friction (Φ) and the soil modulus of elasticity (E) from CPT results
considering the uncertainties and non-linearities of the soil. In
addition, ANNs are used to study the influence of different
parameters and recommend which parameters should be included as
input parameters to improve the prediction. Neural networks discover
relationships in the input data sets through the iterative presentation
of the data and intrinsic mapping characteristics of neural topologies.
General Regression Neural Network (GRNN) is one of the powerful
neural network architectures which is utilized in this study. A large
amount of field and experimental data including CPT results, plate
load tests, direct shear box, grain size distribution and calculated data
of overburden pressure was obtained from a large project in the
United Arab Emirates. This data was used for the training and the
validation of the neural network. A comparison was made between
the obtained results from the ANN's approach, and some common
traditional correlations that predict Φ and E from CPT results with
respect to the actual results of the collected data. The results show
that the ANN is a very powerful tool. Very good agreement was
obtained between estimated results from ANN and actual measured
results with comparison to other correlations available in the
literature. The study recommends some easily available parameters
that should be included in the estimation of the soil properties to
improve the prediction models. It is shown that the use of friction
ration in the estimation of Φ and the use of fines content in the
estimation of E considerable improve the prediction models.
", keywords = "Angle of internal friction, Cone penetrating test,
General regression neural network, Soil modulus of elasticity.", volume = "9", number = "2", pages = "177-8", }
