Improving discrimination power based on reducing dispersion of weights in data envelopment analysis
الموضوعات :
Yousef Badraghi
1
,
Shokrollah Ziari
2
,
Naghi Shoja
3
,
Amir Gholam Abri
4
1 - Department of Industrial Engineering, Rudehen branch, Islamic Azad University, Rudehen, Iran
2 - Department of Mathematics, Firoozkooh branch, Islamic Azad University, Firoozkooh, Iran
3 - Department of Mathematics, Firoozkooh branch, Islamic Azad University, Firoozkooh, Iran
4 - Department of Mathematics, Firoozkooh branch, Islamic Azad University, Firoozkooh, Iran
الکلمات المفتاحية: Data envelopment analysis, Discrimination power, Dispersion of weights, Scale transformation,
ملخص المقالة :
The main drawbacks that arise for data envelopment analysis (DEA) are: lack of discriminationpower amongst efficient decision making units (DMUs) and scattering input-output weights. In theDEA, sometimes the mismatch of the input or output weights in the decision-making units (DMUs)under consideration leads to assigning higher weight to variables with the less significance and/or thelower or zero weight to the variables with high significance. Accordingly, most DEA models introducemore than one efficient DMU in evaluating the relative efficiency of decision-making units. The presentpaper is conducted to overcome these inabilities. In this trends, we present a novel DEA model basedon minimizing the sum of absolute deviations of all input-output weights from each other. The proposedmodel provides to enhance the discrimination power and adjusts the balance dispersion of input-outputweights. Finally, well-known numerical experiments are considered to demonstrate the efficiency andvalidation of the suggested model.
[1] Amin G R (2007) A new approach to determine efficient DMUs in DEA models using inverse optimization. J Ind Eng Int 3(4): 67–70.
[2] Amirteimoori A, & Kordrostami S (2012) A distance-based measure of super efficiency in data envelopment analysis: an application to gas companies. Journal of Global Optimization 54(1): 117-128.
[3] Andersen, P., & Petersen, N.(1993). A procedure for ranking efficient units in data envelopment analysis. Management Science, 39(10), 1261-1264.
[4] Bal, H., orkcu, H. H., & Celebioglu, S. (2008). A new method based on the dispersion of weights in data envelopment analysis. Journal of Computers Industrial Engineering 54, 502-512.
[5] Bal, H.,orkcu, H. H., & Celebioglu, S. (2010). Improving the discrimination power and weights dispersion in the data envelopment analysis. Computers & Operations Research, 37, 99-107.
[6] Banker, R.D.,Charnes, A., & Cooper, W.W. (1984). Some methods for estimating technical and scale inefficiencies in data envelopment analysis. Management Science, 30(9), 1078-1092.
[7] Charnes, A., Cooper, W.W., & Rhodes, E. (1978). Measuring the efficiency of decision making units. European Journal of Operational Research, 2(6), 429-444.
[8] Chen Y (2005) Measuring super-efficiency in DEA in the presence of infeasibility. European Journal of Operational Research 161: 447-468.
[9] Chen, Y., & Liang, L. (2011). Super-efficiency DEA in the presence of infeasibility: One model approach. European Journal of Operational Research, 213, 359-360.
[10] Chen, Y., Du, J., & Huo, J. (2013). Super-efficiency based on a modified directional distance function. Omega, 41, 621-625.
[11] Doyle, J. R., & Green, R. H. (1994). Efficiency and cross-efficiency in DEA: Derivations, meanings and uses. Journal of the Operational Research Society, 45, 567-578.
[12] Doyle, J. R., & Green, R. H. (1995). Cross-evaluation in DEA: Improving discrimination among DMUs. INFOR, 33, 205-222.
[13] Ghasemi, M. R., Ignatius, J., & Emrouznejad, A. (2014). A bi-objective weighted model for improving the discrimination power in MCDEA. European Journal of Operational Research, 233(3), 640-650.
[14] Hatami-Marbini, A., & Toloo, M. (2016). An Extended Multiple Criteria Data Envelopment Analysis Model. Expert Systems with Applications, 73, 201-219.
[15] Jahanshahloo, G.R., & Firoozi Shahmirzadi, P.(2013). New methods for ranking decision making units based on the dispersion of weights and Norm 1 in data envelopment analysis. Computers & Industrial Engineering 65, 187-193.
[16] Hatami-Marbini A, Toloo M (2016) An Extended Multiple Criteria Data Envelopment Analysis Model. Expert Systems with Applications 73: 201-219.
[17] Seiford L.M., Zhu J. (1999) Infeasibility of super-efficiency data envelopment analysis models. INFOR 37 (2): 174-187.
[18] Sexton, T. R., Silkman, R. H., & Hogan, A. J. (1986). The methodology of data envelopment analysis. In R. H. Silkman (Ed.), Measuring efficiency: An
assessment of data envelopment analysis (pp. 729). San Fransisco: Jossey-Bass.
[19] Razavian S, Tohidi G (2011) A Full Ranking Method Using Integrated Dea Models And Its Application To Modify Ga For Finding Pareto Optimal Solution Of Mop Problem. J Ind Eng Int 7(15): 8-14.
[20] Rodder W, Kleine A, Dellnitz A (2018) Scaling production and improving efficiency in DEA: an interactive approach. J Ind Eng Int 14:501–510.
[21] J.-Sharahi, S., Khalili-Damghani, K., Abtahi, AR., & Rashidi Komijan, A. (2021) A new network data envelopment analysis models to measure the efficiency of natural gas supply chain. Oper Res Int J 21, 1461–1486.
[22] Saeidi RG, Oukil A, Amin GR et al (2015) Prioritization of textile fabric defects using ordered weighted averaging operator. Int J Adv Manuf Technol 76: 745–752.
[23] Saeidi, R.G., Oukil, A., Amin, G.R. et al. Prioritization of textile fabric defects using ordered weighted averaging operator. Int J Adv Manuf Technol 76, 745–752 (2015).
[24] Wang, Y. M., & Luo Y. (2009). A note on a new method based on the dispersion of weights in data envelopment analysis. Journal of Computers & Industrial Engineering, 56, 1703-1707.
[25] Ziari S., & Raissi S. (2016) Ranking efficient DMUs using minimizing distance in DEA. J Ind Eng Int 12: 237–242.
