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Environmental Earth Sciences

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01-02-2013 | Original Article

Prediction of unconfined compressive strength of carbonate rocks using artificial neural networks

Authors: Nurcihan Ceryan, Umut Okkan, Ayhan Kesimal

Published in: Environmental Earth Sciences | Issue 3/2013

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Abstract

The unconfined compressive strength (UCS) of intact rocks is an important geotechnical parameter for engineering applications. Determining UCS using standard laboratory tests is a difficult, expensive and time consuming task. This is particularly true for thinly bedded, highly fractured, foliated, highly porous and weak rocks. Consequently, prediction models become an attractive alternative for engineering geologists. The objective of study is to select the explanatory variables (predictors) from a subset of mineralogical and index properties of the samples, based on all possible regression technique, and to prepare a prediction model of UCS using artificial neural networks (ANN). As a result of all possible regression, the total porosity and P-wave velocity in the solid part of the sample were determined as the inputs for the Levenberg–Marquardt algorithm based ANN (LM-ANN). The performance of the LM-ANN model was compared with the multiple linear regression (REG) model. When training and testing results of the outputs of the LM-ANN and REG models were examined in terms of the favorite statistical criteria, which are the determination coefficient, adjusted determination coefficient, root mean square error and variance account factor, the results of LM-ANN model were more accurate. In addition to these statistical criteria, the non-parametric Mann–Whitney U test, as an alternative to the Student’s t test, was used for comparing the homogeneities of predicted values. When all the statistics had been investigated, it was seen that the LM-ANN that has been developed, was a successful tool which was capable of UCS prediction.

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Åkesson U, Lindqvist JE, Göransson M, Stigh J (2001) Relationship between texture and mechanical properties of granites, central Sweden, by use of image-analysing techniques. Bull Eng Geol Environ 60:277–284CrossRef

Altindag R, Alyildiz IS, Onargan T (2004) Technical note: mechanical property degradation of ignimbrite subjected to recurrent freeze-thaw cycles. Int J Rock Mech Min Sci 41:1023–1028CrossRef

Alvarez Grima M, Babuska R (1999) Fuzzy model for the prediction of unconfined compressive strength of rock samples. Int J Rock Mech Min Sci 36:339–349CrossRef

Ameen MS, Smart BGD, Somerville JMC, Hammilton S, Naji NA (2009) Predicting rock mechanical properties of carbonates from wireline logs (A case study: Arab-D reservoir, Ghawar field, Saudi Arabia). Mar Petrol Geol 26:430–434CrossRef

Asef MR, Farrokhrouz M (2010) Governing parameters for approximation of carbonates UCS. Electron J Geotech Eng 15:1581–1592

Barton N (2007) Fracture-induced seismic anisotropy when sharing is induced in production from fractured reservoirs. J Seism Explor 16:115–143

Baykasoğlu A, Güllü H, Canakcı H, Ozbakır L (2008) Predicting of compressive and tensile strength of limestone via genetic programming. Expert Syst Appl 35:111–123CrossRef

Bell FG (1978) The physical and mechanical properties of Fell sandstones, North-Umberland, England. Eng Geol 12:1–29CrossRef

Bieniawski ZT (1974) Estimating the strength of rock materials. J S Afr Inst Min Metall 74:312–320

Brooks N (1985) The equivalent core diameter method of size and shape correction in point load test. Int J Rock Mech Min Sci Geomechan Abstr 22:61–70CrossRef

Canakci H, Pala M (2007) Tensile strength of basalt from a neural network. Eng Geol 94:10–18CrossRef

Ceryan S, Tudes S, Ceryan N (2008) A new quantitative weathering classification for igneous rocks. Environ Geol 55:1319–1336CrossRef

Cevik A, Sezer EA, Cabalar AF, Gokceoglu C (2011) Modeling of the unconfined compressive strength of some clay-bearing rocks using neural network. Appl Soft Comput 11:2587–2594CrossRef

Chang C, Zoback MD, Khaksar A (2006) Empirical relations between rock strength and physical properties in sedimentary rocks. J Petrol Sci Eng 51:223–237CrossRef

D’Andrea DV, Fisher RL, Fogelsen DE (1965) Prediction of rock strength from other rock properties. US Bur Min Rep Invest, Washington DC, 6702:5–45

Dehghan S, Sattarı GH, Chehreh CS, Aliabadi MA (2010) Prediction of unconfined compressive strength and modulus of elasticity for Travertine samples using regression and artificial neural. Netw Min Sci Technol 20:0041–0046

Diamantis K, Gartzos E, Migiros G (2009) Study on uniaxial compressive strength, point load strength index, dynamic and physical properties of serpentinites from Central Greece: test results and empirical relations. Eng Geol 108:199–207CrossRef

Doberenier L, De Freitas MH (1986) Geotechnical properties of weak sandstones. Geotechnique 36:79–94CrossRef

Ellis GW, Yao C, Zhao R (1992) Neural network modelling of the mechanical behaviour of sand. In: Proceedings of Ninth Conference ASCE Engng Mech. ASCE New York, pp 421–424

Fahy MP, Guccione MJ (1979) Estimating strength of sandstone using petrographic thin-section data. Bull Assoc Eng Geol 16:467–485

Fistikoglu O, Okkan U (2011) Statistical downscaling of monthly precipitation using NCEP/NCAR reanalysis data for Tahtali River basin in Turkey. ASCE J Hydrol Eng 16(2):157–164CrossRef

Garret JH Jr (1994) Where and why artificial neural networks are applicable in civil engineering. J Comput Civil Eng ASCE 8(2):129–130CrossRef

Gaviglio P (1989) Longitudinal waves propagation in a limestone: the relationship between velocity and density. Rock Mech Rock Eng 22:299–306CrossRef

Ghabousi J, Garret JH, Wu X (1991) Knowledge based modeling of material behavior with neural networks. ASCE J Eng Mech 171(1):132–153CrossRef

Gokceoglu C (2002) A fuzzy triangular chart to predict the unconfined compressive strength of the Ankara agglomerates from their petrographic composition. Eng Geol 66:39–51CrossRef

Gokceoglu C, Zorlu K (2004) A fuzzy model to predict the unconfined compressive strength and modulus of elasticity of a problematic rock. Eng Appl Artif Intell 17:61–72CrossRef

Gokceoglu C, Ulusay R, Sonmez H (2000) Factors affecting durability of the weak and clay-bearing rocks selected from Turkey with particular emphasis on the influence of the number of drying and wetting of cycles. Eng Geol 57(3–4):215–237CrossRef

Gundoğdu N (1982) Geological, mineralogical and geochemical analysis of Bigadic sedimentary basin aged Neojen. PhD thesis, Hacettepe University, Ankara, Turkey (in Turkish)

Hagan MT, Menhaj MB (1994) Training feed forward techniques with the Marquardt algorithm. IEEE Trans Neural Netw 5(6):989–993CrossRef

Ham F, Kostanic I (2001) Principles of neurocomputing for science and engineering. Mcgraw-Hill, USA

Hawkins A, McConnell BJ (1990) Influence of geology on geomechanical properties of sandstones. In: 7th International congress on rock mechanics, Balkema, Rotterdam, pp 257–260

Hinnes WW, Montgomery DC (1990) Probability and statistics in engineering and management science. John Wiley & Sons, Singapore

Huang Y, Wanstedt S (1998) The introduction of neural network system and its applications in rock engineering. Eng Geol 4:253–260CrossRef

International Society for Rock Mechanics (ISRM) (1981) In rock characterization, testing and monitoring—ISRM suggested methods. In: Brown ET (ed), Oxford Pergamon, p 211

International Society for Rock Mechanics (ISRM) (2007) The complete ISRM suggested methods for rock characterization, testing and monitoring: 1974–2006. In: Ulusay R, Hudson JA (eds) Suggested methods prepared by the commission on testing methods, International Society for Rock Mechanics. ISRM Turkish National Group. Ankara, Turkey

Jensen LRD, Friis H, Fundal E, Mǿller P, Jespersen M (2010) Analysis of limestone micromechanical properties by optical microscopy. Eng Geol 110(3–4):43–50

Kahraman S (2001) Evaluation of simple methods for assessing the unconfined compressive strength of rock. Int J Rock Mech Min Sci 38:981–984CrossRef

Kahraman S, Alber M (2006) Estimating the unconfined compressive strength and elastic modulus of a fault breccia mixture of weak rocks and strong matrix. Int J Rock Mech Min Sci 43:1277–1287CrossRef

Kahraman S, Gunaydin O, Alber M, Fener M (2009) Evaluating the strength and deformability properties of Misis fault breccia using artificial neural networks. Expert Syst Appl 36:6874–6878CrossRef

Kahraman S, Alber M, Fener M, Gunaydin O (2010) The usability of Cerchar abrasivity index for the prediction of UCS and E of Misis fault breccia: regression and artificial neural networks analysis. Expert Syst Appl 37:8750–8756CrossRef

Lama RD, Vutukuri V (1978) Handbook on mechanical properties of rocks. Vol 2, Trans Tech Publication. ISBN-13:978–0878490233

Lindqvist JE, Åkesson U (2001) Image analysis applied to engineering geology, a literature review. Bull Eng Geol Environ 60:117–122CrossRef

Mallows CL (1973) Some comments on C_p. Technometrics 15(4):661–675

Mann HB, Whitney DR (1947) On a test of whether one of two random variables is stochastically larger than the other. Ann Math Stat 18:50–60CrossRef

Marquardt D (1963) An algorithm for least squares estimation of non-linear parameters. J Soc Ind Appl Math 11(2):431–441CrossRef

McQuarrie AD, Tsai C (1998) Regression and time series model selection. World Scientific Publishing Co., Pte. Ltd, River EdgeCrossRef

Meulenkamp F (1997) Improving the prediction of the UCS by Equotip readings using statistical and neural network models. Memoirs of the centre for engineering geology in the Netherlands, vol 162, p 127

Meulenkamp F, Alvarez Grima M (1999) Application of neural networks for the prediction of the unconfined compressive strength (UCS) from Equotip hardness. Int J Rock Mech Min Sci 36:29–39CrossRef

Moh’d BK (2009) Compressive strength of vuggy oolitic limestones as a function of their porosity and sound propagation. Jordan J Earth Environ Sci 2:18–25

Moradian Z, Behnia M (2009) Predicting the unconfined compressive strength and static young’s modulus of intact sedimentary rocks using the ultrasonic tests. Int J Geomech ASCE 9:1–14CrossRef

Neter J, Kutner M, Nachtsheim C, Wasserman W (1996) Applied linear statistical models. McGraw-Hill Companies, Inc, NY

Nie X, Zhang Q (1994) Prediction of rock mechanical behaviour by artificial neural network. A comparison with traditional method. In: IV CSMR, Integral Approach to Applied Rock Mechanics. Santiago, Chile

Okkan U (2011) Application of Levenberg-Marquardt optimization algorithm based multilayer neural networks for hydrological time series modeling. An Int J Optim Control Theor Appl 1(1):53–63

Okkan U, Dalkilic HY (2011) Reservoir inflows modeling with artificial neural networks: the case of Kemer Dam in Turkey. Fresenius Environ Bull 20(12):3110–3119

Oyler DC, Mark C, Melinda GM (2010) In situ estimation of roof rock strength using sonic logging. Int J Coal Geol 83:484–490CrossRef

Romana M (1999) Correlation between unconfined compressive and point-load (Franklin tests) strengths for different rock classes. In: 9th ISRM Congress, 1. Balkema, Paris, pp 673–676

Saito T, Mamoru ABE, Kundri S (1974) Study on weathering of igneous rock. Rock Mech Jpn 2:28–30

Sarkar K, Tiwary A, Singh TN (2010) Estimation of strength parameters of rock using artificial neural networks. Bull Eng Geol Environ 69:599–606CrossRef

Shakoor A, Bonelli R (1991) Relationship between petrographic characteristics, engineering index properties and mechanical properties of selected sandstones. Bull Assoc Eng Geol 28:55–71

Sharma S (1996) Applied multivariate techniques. John Willey & Sons, Inc, Canada

Singh TN, Dubey R (2000) A study of transmission velocity of primary wave (P-Wave) in Coal Measures sandstone. J Sci Ind Res India 59:482–486

Singh A, Harrison A (1985) Standardized principal components. Int J Remote Sens 6:883–896CrossRef

Singh VK, Singh D, Singh TN (2001) Prediction of strength properties of some schistose rocks from petrographic properties using artificial neural networks. Int J Rock Mech Min Sci 38:269–284CrossRef

Sonmez H, Tuncay E, Gokceoglu C (2004) Models to predict the unconfined compressive strength and the modulus of elasticity for Ankara Agglomerate. Int J Rock Mech Min Sci 41(5):717–729CrossRef

Temel A, Gundogdu MN (1996) Zeolite occurrences and the erionite–mesothelioma relationship in Cappadocia, Central Anatolia, Turkey. Miner Deposita 31:539–547CrossRef

Tiryaki B (2008) Predicting intact rock strength for mechanical excavation using multivariate statistics, artificial neural networks and regression trees. Eng Geol 99(1–2):51–60CrossRef

Ulusay R, Tureli K, Ider MH (1994) Prediction of engineering properties of a selected litharenite sandstone from its petrographic characteristics using correlation and multivariate statistical techniques. Eng Geol 37:135–157CrossRef

Ulusay R, Gokceoglu C, Sulukcu S (2001) ISRM suggested method for determining block punch index (BPI). Int J Rock Mech Min Sci 38:1113–1119CrossRef

Yagiz S, Sezer EA, Gokceoglu C (2012) Artificial neural networks and nonlinear regression techniques to assess the influence of slake durability cycles on the prediction of uniaxial compressive strength and modulus of elasticity for carbonate rocks. I J Numer Anal Method Geomech. doi:10.1002/nag.1066

Yilmaz I (2010) Use of the core strangle test for tensile strength estimation and rock mass classification. Int J Rock Mech Min Sci 47(5):845–850CrossRef

Yilmaz I, Yuksek AG (2008) An example of artificial neural network (ANN) application for indirect estimation of rock parameters. Rock Mech Rock Eng 41(5):781–795CrossRef

Yilmaz I, Yuksek AG (2009) Prediction of the strength and elasticity modulus of gypsum using multiple regression, ANN and ANFIS models. Int J Rock Mech Min Sci 46(4):803–810CrossRef

Youash Y (1970) Dynamic, physical properties of rocks: Part 2. Experimental result. Proc 2nd Congr Int Soc Rock Mech Beograd 1:185–195

Zorlu K, Gokceoglu C, Ocakoglu F, Nefeslioglu HA, Acikalin S (2008) Prediction of unconfined compressive strength of sandstones using petrography-based models. Eng Geol 96:141–158CrossRef

Title: Prediction of unconfined compressive strength of carbonate rocks using artificial neural networks
Authors: Nurcihan Ceryan
Umut Okkan
Ayhan Kesimal
Publication date: 01-02-2013
Publisher: Springer-Verlag
Published in: Environmental Earth Sciences / Issue 3/2013
Print ISSN: 1866-6280
Electronic ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-012-1783-z

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