Abstract
Performance evaluation is an important part in the management of any decision-making unit (DMU) as it identifies sources of managerial inefficiencies and provides a policy for inefficient DMUs to improve their efficiency. The latter is generally affected by environmental variables that are beyond managerial control. Modeling the impact of these environmental variables is a critical issue for both researchers and practitioners. Researchers developed and proposed several methods to deal with this issue in general and in the data envelopment analysis (DEA) literature in particular. However, the available two-stage DEA methods do not account for interdependence between observations and they are of limited use when the number of variables is fairly large. This paper proposes an integrated framework combining DEA, and boosted generalized linear mixed models (GLMMs) that accounts for the interdependence problem when studying the impact of environmental variables on performance. Additionally, the framework carries out variable selection. The framework is illustrated with a sample of 151 commercial banks from Middle East and North African countries.
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References
Anouze, A.L. (2010). Evaluating productive efficiency: Comparative study of commercial banks in Gulf countries. Unpublished Ph.D. thesis, Aston Business School, Aston University.
Ariff, M., & Can, L. (2008). Cost and profit efficiency of Chinese banks: A non-parametric analysis. China Economic Review, 19, 260–273.
Ariss, R. (2009). Competitive behavior in Middle East and North Africa banking systems. The Quarterly Review of Economics and Finance, 49, 693–710.
Assaf, A., Barros, C., & Matousek, R. (2011). Technical efficiency in Saudi banks. Expert systems with Applications, 38, 5781–5786.
Azadeh, A., Saberi, M., Moghaddam, R., & Javanmardi, L. (2011). An integrated data envelopment analysis-artificial neural network-rough set algorithm for assessment of personnel efficiency. Expert Systems with Applications, 38, 1364–1373.
Azen, R., & Budescu, D. (2003). The dominance analysis approach for comparing predictors in multiple regression. Psychological Methods, 8, 129–148.
Banker, R., Charnes, A., & Cooper, W. (1984). Some models for estimating technical and scale inefficiencies in data envelopment analysis. Management Science, 30, 1078–1092.
Banker, R., & Morey, R. (1986). The use of categorical variables in data envelopment analysis. Management Science, 32, 1613–1627.
Berger, A. N., & Humphrey, D. B. (1991). The dominance of inefficiencies over scale and product mix economies in banking. Journal of Monetary Economics, 28, 117–148.
Breslow, N. E., & Clayton, D. G. (1993). Approximate inference in generalized linear mixed model. Journal of the American Statistical Association, 88, 9–25.
Bühlmann, P., & Yu, B. (2003). Boosting with the L2 loss: Regression and classification. Journal of the American Statistical Association, 98, 324–339.
Burki, A., & Niazi, G. (2010). Impact of financial reforms on efficiency of state owned private and foreign banks in Pakistan. Applied Economics, 42, 3147–3160.
Casu, B., & Molyneux, P. (2003). A comparative study of efficiency in European banking. Applied Economics, 35, 1865–1876.
Charnes, A., Cooper, W., & Rhodes, E. (1978). Measuring the efficiency of decision making units. European Journal of Operational Research, 2, 429–444.
Charnes, A., Cooper, W., & Rhodes, E. (1981). Evaluating program and managerial efficiency: An application of data envelopment analysis to program follow through. Management Science, 27, 668–697.
Chronopoulos, D., Girardone, C., & Nankervis, J. (2011). Are there any cost and profit efficiency gains in financial conglomeration? Evidence from the accession countries. The European Journal of Finance, 17, 603–621.
Claeskens, G., & Hjort, N. L. (2008). Model selection and model averaging. Cambridge: Cambridge University Press.
Courville, T., & Thompson, B. (2001). Use of structure coefficients in published multiple regression articles: Is not enough. Educational and Psychological Measurement, 61, 229–248.
Dong, Y., Firth, M., Hou, W., & Yang, W. (2016). Evaluating the performance of Chinese commercial banks: A comparative analysis of different types of banks. European Journal of Operational Research, 252(1), 280–295.
Elyasiani, E., & Wang, Y. (2012). Bank holding company diversification and production efficiency. Applied Financial Economics, 22, 1409–1428.
Emrouznejad, A., & Anouze, A. L. (2010). Data envelopment analysis with classification and regression tree: A case of banking efficiency. Expert Systems, 27, 231–246.
Epure, M., Kerstens, K., & Prior, D. (2011). Bank productivity and performance groups: A decomposition approach based upon the Luenberger productivity indicator. European Journal of Operational Research, 211, 630–641.
Estelle, S., Johnson, A., & Ruggiero, J. (2010). Three-stage DEA models for incorporating exogenous inputs. Computers & Operations Research, 37, 1087–1090.
Fiordelisi, F., & Molyneux, P. (2010). Total factor productivity and shareholder returns in banking. Omega, 38, 241–253.
Fitzmaurice, G. M., Laird, N. M., & Ware, J. H. (2011). Applied longitudinal analysis (2nd ed.). New Jersey: Wiley.
Freund, Y., & Schapire, R. E. (1996). Experiments with a new boosting algorithm. In Proceedings of the thirteenth international conference on machine learning Morgan Kaufmann, San Francisco, CA, pp. 148–156
Fried, H., Schmidt, S., & Yaisawarng, S. (1995). Incorporating the operating environment into a measure of technical efficiency. Paper presented to the Bureau of Industry Economics Seminar, Canberra.
Friedman, J. H. (2001). Greedy function approximation: A gradient boosting machine. Annals of Statistics, 29, 337–407.
García, V., Mollineda, R. A., & Sánchez, J. S. (2014). A bias correction function for classification performance assessment in two-class imbalanced problems. Knowledge-Based Systems, 59, 66–74.
Gardener, E., Molyneux, P., & Nguyen-Linh, H. (2011). Determinants of efficiency in South East Asian banking. The Service Industries Journal, 31, 2693–2719.
Groll, A. (2013). GMMBoost: Likelihood-based boosting for generalized mixed models. R package version 1.1.1. http://CRAN.R-project.org/package=GMMBoost.
Groll, A., & Tutz, G. (2012). Regularization for generalized additive mixed models by likelihood-based boosting. Methods of Information in Medicine, 51, 168–177.
Hall, M., Kenjegalieva, K., & Simper, R. (2012). Environmental factors affecting Hong Kong banking: A post-Asian financial crisis efficiency analysis. Global Finance Journal, 23, 184–201.
Hastie, T., Tibshirani, R., & Friedman, J. (2009). The elements of statistical learning: Data mining, inference, and prediction (2nd ed.). New York: Springer.
Hermes, N., & Nhung, V. (2010). The impact of financial liberalization on bank efficiency: Evidence from Latin America and Asia. Applied Economics, 42, 3351–3365.
Hsiao, H., Chang, H., Cianci, A., & Huang, L. (2010). First financial restructuring and operating efficiency: Evidence from Taiwanese commercial banks. Journal of Banking & Finance, 34, 1461–1471.
Johnes, J., Izzeldin, M., & Pappas, V. (2014). A comparison of performance of Islamic and conventional banks 2004–2009. Journal of Economic Behavior & Organization, 103, S93–S107.
Johnson, J., & LeBreton, J. (2004). History and use of relative importance indices in organizational research. Organizational Research Methods, 7, 238–257.
Kao, C., & Liu, S.-T. (2009). Stochastic data envelopment analysis in measuring the efficiency of Taiwan commercial banks. European Journal of Operational Research, 196, 312–322.
Kao, C., & Liu, S.-T. (2014). Multi-period efficiency measurement in data envelopment analysis: The case of Taiwanese commercial banks. Omega, 47, 90–98.
Kao, C., & Liu, S.-T. (2016). A parallel production frontiers approach for intertemporal efficiency analysis: The case of Taiwanese commercial banks. European Journal of Operational Research. doi:10.1016/j.ejor.2016.04.047.
Karim, D., Liadze, I., Barrell, R., & Davis, E. (2013). Off-balance sheet exposures and banking crises in OECD countries. Journal of Financial Stability, 9, 673–681.
Kouki, I., & Al-Nasser, A. (2014). The implication of banking competition: Evidence from African countries. Research in International Business and Finance (In Press). doi:10.1016/j.ribaf.2014.09.009.
Kumar, S., & Gulati, R. (2008). An examination of technical, pure technical, and scale efficiencies in Indian public sector banks using data envelopment analysis. Eurasian Journal of Business and Economics, 1(2), 33–69.
Ledolter, J., & Abraham, B. (1981). Parsimony and its importance in time series forecasting. Technometrics, 23, 411–414.
Ling, C.X., Huang, J., & hang, H. (2003). AUC: a statistically consistent and more discriminating measure than accuracy. In Proceedings of the international joint conferences on artificial intelligence, pp. 519–526.
Liu, J., Lu, L., Lu, W.-M., & Lin, B. A. (2013). A survey of DEA applications. Omega, 41, 893–902.
Lozano-Vivas, A., & Pasiouras, F. (2010). The impact of non-traditional activities on the estimation of bank efficiency: International evidence. Journal of Banking & Finance, 34, 1436–1449.
Luo, D., Yao, S., Chen, J., & Wang, J. (2011). World financial crisis and efficiency of Chinese commercial banks. The World Economy, 34, 805–825.
McCullagh, P., & Nelder, J. A. (1989). Generalized linear models (2nd ed.). London: Chapman & Hall/CRC.
Noor, M., & Bt Ahmad, N. (2012). The determinants of Islamic banks’ efficiency changes: Empirical evidence from the world banking sectors. Global Business Review, 13, 179–200.
Olson, D., & Zoubi, T. (2011). Efficiency and bank profitability in MENA countries. Emerging Markets Review, 12, 94–110.
Ongena, S., & Smith, D. (2000). What determines the number of bank relationships? Cross-country evidence. Journal of Financial Intermediation, 9, 26–56.
Osman, H., Anouze, A. L., & Emrouznejad, A. (2014). Handbook of research on strategic performance management and measurement using data envelopment analysis. Hershey, PA: IGI Global.
Pastor, J., & Tortosa-Ausina, E. (2008). Social capital and bank performance: An international comparison for OECD countries. The Manchester School, 76(2), 223–265.
Pedhazur, E. J. (1997). Multiple regression in behavioral research. Fort Worth: Harcourt Brace.
Pervan, M., Pelivan, I., & Arnerić, J. (2015). Profit persistence and determinants of bank profitability in Croatia. Economic Research-Ekonomska Istraživanja, 28(1), 284–298.
Phan, H., Daly, K., & Akhter, S. (2016). Bank efficiency in emerging Asian countries. Research in International Business and Finance, 38, 517–530.
Ray, S. (1988). Data envelopment analysis, nondiscretionary inputs and efficiency: An alternative interpretation. Socio-Economic Planning Science, 22, 167–176.
Ray, S. (1991). Resource-use efficiency in public schools: A study of Connecticut data. Management Science, 37, 1620–1628.
R Core Team (2013). R: A language and environment for statistical computing. Vienna, Austria: R Foundation for Statistical Computing. http://www.R-project.org/.
Řepková, I. (2015). Banking efficiency determinants in the Czech banking sector. Procedia Economics and Finance, 23, 191–196.
Rezvanian, R., Ariss, R., & Mehdian, S. (2011). Cost efficiency, technological progress and productivity growth of Chinese banking pre- and post-WTO accession. Applied Financial Economics, 21, 437–454.
Sahut, J. M., & Mili, M. (2011). Banking distress in MENA countries and the role of mergers as a strategic policy to resolve distress. Economic Modelling, 28, 138–146.
San, O., Theng, L., & Heng, T. (2011). A comparison on efficiency of domestic and foreign banks in Malaysia: A DEA approach. Business Management Dynamics, 1, 33–49.
SAS Institute Inc. SAS/STAT Software, Version 9.4. Cary, NC. http://www.sas.com.
Seol, H., Choi, J., Park, G., & Park, Y. (2007). A framework for benchmarking service process using data envelopment analysis and decision tree. Expert Systems with Applications, 32, 432–440.
Shamsi, F., Aly, H., & El-Bassiouni, M. (2009). Measuring and explaining the efficiencies of the United Arab Emirates banking system. Applied Economics, 41, 3505–3519.
Shyu, J., & Chiang, T. (2012). Measuring the true managerial efficiency of bank branches in Taiwan: A three-stage DEA analysis. Expert Systems with Applications, 39, 11494–11502.
Sufian, F. (2009). Determinants of bank efficiency during unstable macroeconomic environment: Empirical evidence from Malaysia. Research in International Business and Finance, 23, 54–77.
Tanna, S., Pasiouras, F., & Nnadi, M. (2011). The effect of board size and composition on the efficiency of UK banks. International Journal of the Economics of Business, 18, 441–462.
Thanassoulis, E. (2001). Introduction to the theory and application of data envelopment analysis: A foundation text with integrated software. Massachusetts: Kluwer Academic.
Thanassoulis, E., Portela, M., & Despic, O. (2008). Data envelopment analysis: The mathematical programming approach to efficiency analysis. In H. Fried, C. Lovell, & S. Schmidt (Eds.), The measurement of productive efficiency and productivity growth (pp. 251–420). New York: Oxford University Press.
Tutz, G., & Groll, A. (2010). Generalized linear mixed models based on boosting. In T. Kneib & G. Tutz (Eds.), Statistical modelling and regression structures—Festschrift in the Honour of Ludwig Fahrmeir. Heidelberg: Physica.
Tzeremes, N. (2014). Efficiency dynamics in Indian banking: A conditional directional distance approach. European Journal of Operational Research. doi:10.1016/j.ejor.2014.07.029.
Vu, H., & Nahm, D. (2013). The determinants of profit efficiency of banks in Vietnam. Journal of the Asia Pacific Economy, 18, 615–631.
Wankea, P., Barrosb, C., & Faria, J. (2015). Financial distress drivers in Brazilian banks: A dynamic slacks approach. European Journal of Operational Research, 240(1), 258–268.
Wanke, P., & Barros, C. (2014). Two-stage DEA: An application to major Brazilian banks. Expert Systems with Applications, 41(5), 2337–2344.
Wheelock, D. C., & Wilson, P. W. (1999). Technical progress, inefficiency, and productivity changes in U.S. banking 1984–1993. Journal of Money, Credit, and Banking, 31, 212–234.
Yang, C.-C. (2012). Service, investment, and risk management performance in commercial banks. The Service Industries Journal, 32, 2005–2025.
Zha, Y., Liang, N., Wu, M., & Bian, Y. (2014). Efficiency evaluation of Banks in China: A dynamic two-stage slacks-based measure approach. Omega. doi:10.1016/j.omega.2014.12.008.
Zhang, T., & Matthews, K. (2012). Efficiency convergence properties of Indonesian banks 1992–2007. Applied Financial Economics, 22, 1465–1478.
Acknowledgments
The authors are very grateful to the anonymous referees and the editor for their constructive comments which greatly helped improve the presentation of this manuscript. This research was supported by the AUB University Research Board (Grant No. 102853), Lebanese National Council for Scientific Research (CNRS) (Grant No. 100350).
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Appendix
Appendix
See Table 6.
bGLMM algorithm
The bGLMM algorithm (Boosted GLMM) of Tutz and Groll (2010) is now briefly summarized (see the original article for all the computational details).
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1.
Initialization Choose a number of iteration \(l_{max} \). Start with the model without any fixed effects (only an intercept). Compute initial values for the parameters \(\beta _0 ,Q\) and for the random effects b. For example with the PQL method. Initialize the fixed effects parameters \(\beta _1 ,\ldots ,\beta _p \) to 0.
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Iteration For \(l=1,\ldots ,l_{max} \) Refitting of residuals
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(i)
Computation of parameters. Based on the current model, for each fixed effect covariate \(r=1,\ldots ,p\), compute an update of the estimated parameter. This is done separately (component-wise) for each r. The update is performed based on a one-step Fisher scoring.
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(ii)
Selection step. Let r be the component in \(\left\{ {1,\ldots ,p} \right\} \) leading to the smallest value of the AIC (or BIC) and let \(\hat{\beta }_0^*,\hat{\beta } _r^{*} ,\hat{b}^{*}\) be the corresponding estimates.
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(iii)
Update the parameters. Set \(\hat{\beta } _0^{\left( l \right) } =\hat{\beta } _0^{\left( {l-1} \right) } +\hat{\beta } _0^*\), \(\hat{\beta } _r^{\left( l \right) } =\hat{\beta } _r^{\left( {l-1} \right) } +\hat{\beta } _r^*, \quad \hat{b} ^{\left( l \right) }=\hat{b} ^{\left( {l-1} \right) }+\hat{b}^{*}\). Based on these updated parameters, compute the update \(\hat{Q} ^{\left( l \right) }\) (for instance as an approximate REML-type estimate).
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(i)
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Final selection Select the final solution among all the solutions obtained for \(l=1,\ldots ,l_{max}\) as the one with the smallest AIC (or BIC).
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Bou-Hamad, I., Anouze, A.L. & Larocque, D. An integrated approach of data envelopment analysis and boosted generalized linear mixed models for efficiency assessment. Ann Oper Res 253, 77–95 (2017). https://doi.org/10.1007/s10479-016-2348-4
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DOI: https://doi.org/10.1007/s10479-016-2348-4