[1]	Alcaraz J, Ramón N, Ruiz J L, Sirvent I (2013). Ranking ranges in cross-efficiency evaluations. European Journal of Operational Research, 226(3): 516–521 CrossRef Google scholar

[2]	Andersen P, Petersen N C (1993). A procedure for ranking efficient units in data envelopment analysis. Management Science, 39(10): 1261–1264 CrossRef Google scholar

[3]	Anderson T R, Hollingsworth K, Inman L (2002). The fixed weighting nature of a cross-evaluation model. Journal of Productivity Analysis, 17(3): 249–255 CrossRef Google scholar

[4]	Baker P C, Talluri S (1997). A closer look at the use of data envelopment analysis for technology selection. Computers & Industrial Engineering, 32(1): 101–108 CrossRef Google scholar

[5]	Barros C P (2006). A benchmark analysis of Italian seaports using data envelopment analysis. Maritime Economics & Logistics, 8(4): 347–365 CrossRef Google scholar

[6]	Boussofiane A, Dyson R G, Thanassoulis E (1991). Applied data envelopment analysis. European Journal of Operational Research, 52(1): 1–15 CrossRef Google scholar

[7]	Braglia M, Petroni A (1999). Evaluating and selecting investments in industrial robots. International Journal of Production Research, 37(18): 4157–4178 CrossRef Google scholar

[8]	Brannick M T, Salas E, Prince C W (1997). Team Performance Assessment and Measurement: Theory, Methods, and Applications. Hove, East Sussex: Psychology Press

[9]	Chang C M (2008). Engineering management in developing economies: The EMIDE approaches to meet the new challenges. International Journal of Innovation & Technology Management, 5(4): 381–400 CrossRef Google scholar

[10]	Charnes A, Cooper W W, Rhodes E (1978). Measuring the efficiency of decision making units. European Journal of Operational Research, 2(6): 429–444 CrossRef Google scholar

[11]	Chen J X (2011). Peer-estimation for multiple criteria ABC inventory classification. Computers & Operations Research, 38(12): 1784–1791 CrossRef Google scholar

[12]	Chen L, Wang Y M (2016). Data envelopment analysis cross-efficiency model in fuzzy environments. Journal of Intelligent & Fuzzy Systems, 30(5): 2601–2609 CrossRef Google scholar

[13]	Chen L, Wang Y M (2020). DEA target setting approach within the cross efficiency framework. Omega, 96: 102072

[14]	Chen W, Zhou K, Yang S (2017). Evaluation of China’s electric energy efficiency under environmental constraints: A DEA cross efficiency model based on game relationship. Journal of Cleaner Production, 164: 38–44 CrossRef Google scholar

[15]	Chu M T, Shyu J Z, Khosla R (2008). Measuring the relative performance for leading fabless firms by using data envelopment analysis. Journal of Intelligent Manufacturing, 19(3): 257–272 CrossRef Google scholar

[16]	Cook W D, Seiford L M (2009). Data envelopment analysis (DEA) — Thirty years on. European Journal of Operational Research, 192(1): 1–17 CrossRef Google scholar

[17]	Cui Q, Li Y (2015). Evaluating energy efficiency for airlines: An application of VFB-DEA. Journal of Air Transport Management, 44– 45: 34–41 CrossRef Google scholar

[18]	Despotis D K (2002). Improving the discriminating power of DEA: Focus on globally efficient units. Journal of the Operational Research Society, 53(3): 314–323 CrossRef Google scholar

[19]	Ding L, Yang Y, Wang W, Calin A C (2019). Regional carbon emission efficiency and its dynamic evolution in China: A novel cross efficiency-malmquist productivity index. Journal of Cleaner Production, 241: 118260 CrossRef Google scholar

[20]	Dotoli M, Epicoco N, Falagario M, Sciancalepore F (2016). A stochastic cross-efficiency data envelopment analysis approach for supplier selection under uncertainty. International Transactions in Operational Research, 23(4): 725–748 CrossRef Google scholar

[21]	Doyle J, Green R (1994). Efficiency and cross-efficiency in DEA: Derivations, meanings and uses. Journal of the Operational Research Society, 45(5): 567–578 CrossRef Google scholar

[22]	Du J, Cook W D, Liang L, Zhu J (2014). Fixed cost and resource allocation based on DEA cross-efficiency. European Journal of Operational Research, 235(1): 206–214 CrossRef Google scholar

[23]	Dyson R G, Thanassoulis E (1988). Reducing weight flexibility in data envelopment analysis. Journal of the Operational Research Society, 39(6): 563–576 CrossRef Google scholar

[24]	Enberg C (2012). Enabling knowledge integration in coopetitive R&D projects — The management of conflicting logics. International Journal of Project Management, 30(7): 771–780 CrossRef Google scholar

[25]	Ertay T, Ruan D (2005). Data envelopment analysis based decision model for optimal operator allocation in CMS. European Journal of Operational Research, 164(3): 800–810 CrossRef Google scholar

[26]	Färe R, Grosskopf S, Norris M, Zhang Z (1994). Productivity growth, technical progress, and efficiency change in industrialized countries. The American Economic Review, 84(1): 66–83

[27]	Geng Z, Dong J, Han Y, Zhu Q (2017). Energy and environment efficiency analysis based on an improved environment DEA cross-model: Case study of complex chemical processes. Applied Energy, 205: 465–476 CrossRef Google scholar

[28]	Guo D, Wu J (2013). A complete ranking of DMUs with undesirable outputs using restrictions in DEA models. Mathematical and Computer Modelling, 58(5–6): 1102–1109 CrossRef Google scholar

[29]	Hatami-Marbini A, Agrell P J, Tavana M, Khoshnevis P (2017). A flexible cross-efficiency fuzzy data envelopment analysis model for sustainable sourcing. Journal of Cleaner Production, 142: 2761–2779 CrossRef Google scholar

[30]	Hong J D, Jeong K Y (2017). Cross efficiency based heuristics to rank decision making units in data envelopment analysis. Computers & Industrial Engineering, 111: 320–330 CrossRef Google scholar

[31]

Jahanshahloo G R, Khodabakhshi M, Hosseinzadeh Lotfi F, Moazami Goudarzi M R (2011). A cross-efficiency model based on super-efficiency for ranking units through the TOPSIS approach and its extension to the interval case. Mathematical and Computer Modelling, 53(9–10): 1946–1955 CrossRef Google scholar

[32]	Kao C, Liu S T (2019). Cross efficiency measurement and decomposition in two basic network systems. Omega, 83: 70–79 CrossRef Google scholar

[33]	Lam K F (2010). In the determination of weight sets to compute cross-efficiency ratios in DEA. Journal of the Operational Research Society, 61(1): 134–143 CrossRef Google scholar

[34]	Lannes W J (2001). What is engineering management? IEEE Transactions on Engineering Management, 48(1): 107–115 CrossRef Google scholar

[35]	Lee K H, Farzipoor Saen R (2012). Measuring corporate sustainability management: A data envelopment analysis approach. International Journal of Production Economics, 140(1): 219–226 CrossRef Google scholar

[36]	Li F, Zhu Q, Chen Z, Xue H (2018). A balanced data envelopment analysis cross-efficiency evaluation approach. Expert Systems with Applications, 106: 154–168 CrossRef Google scholar

[37]	Li H B, Lei L (2007). DEA-based project knowledge management performance evaluation. In: International Conference on Management Science & Engineering. Harbin, 1561–1566

[38]	Liang L, Wu J, Cook W D, Zhu J (2008a). Alternative secondary goals in DEA cross-efficiency evaluation. International Journal of Production Economics, 113(2): 1025–1030 CrossRef Google scholar

[39]	Liang L, Wu J, Cook W D, Zhu J (2008b). The DEA game cross-efficiency model and its Nash equilibrium. Operations Research, 56(5): 1278–1288 CrossRef Google scholar

[40]	Lim S (2012a). Context-dependent data envelopment analysis with cross-efficiency evaluation. Journal of the Operational Research Society, 63(1): 38–46 CrossRef Google scholar

[41]	Lim S (2012b). Minimax and maximin formulations of cross-efficiency in DEA. Computers & Industrial Engineering, 62(3): 726–731 CrossRef Google scholar

[42]	Lim S, Oh K W, Zhu J (2014). Use of DEA cross-efficiency evaluation in portfolio selection: An application to Korean stock market. European Journal of Operational Research, 236(1): 361–368 CrossRef Google scholar

[43]	Lim S, Zhu J (2015). DEA cross-efficiency evaluation under variable returns to scale. Journal of the Operational Research Society, 66(3): 476–487 CrossRef Google scholar

[44]	Lin L C, Tseng C C (2007). Operational performance evaluation of major container ports in the Asia-Pacific region. Maritime Policy & Management, 34(6): 535–551 CrossRef Google scholar

[45]	Lin R, Chen Z, Xiong W (2016). An iterative method for determining weights in cross efficiency evaluation. Computers & Industrial Engineering, 101: 91–102 CrossRef Google scholar

[46]	Liu B, Tian C, Li Y, Song H, Ma Z (2018). Research on the effects of urbanization on carbon emissions efficiency of urban agglomerations in China. Journal of Cleaner Production, 197: 1374–1381 CrossRef Google scholar

[47]	Liu H H, Song Y Y, Yang G L (2019). Cross-efficiency evaluation in data envelopment analysis based on prospect theory. European Journal of Operational Research, 273(1): 364–375 CrossRef Google scholar

[48]	Liu S T (2018). A DEA ranking method based on cross-efficiency intervals and signal-to-noise ratio. Annals of Operations Research, 261(1–2): 207–232 CrossRef Google scholar

[49]	Liu W, Wang Y M, Lv S (2017a). An aggressive game cross-efficiency evaluation in data envelopment analysis. Annals of Operations Research, 259(1–2): 241–258 CrossRef Google scholar

[50]	Liu X, Chu J, Yin P, Sun J (2017b). DEA cross-efficiency evaluation considering undesirable output and ranking priority: A case study of eco-efficiency analysis of coal-fired power plants. Journal of Cleaner Production, 142: 877–885 CrossRef Google scholar

[51]	Lo Storto C (2016). Ecological efficiency based ranking of cities: A combined DEA cross-efficiency and Shannon’s entropy method. Sustainability, 8(2): 124 CrossRef Google scholar

[52]	Lu W M, Lo S F (2007). A closer look at the economic-environmental disparities for regional development in China. European Journal of Operational Research, 183(2): 882–894 CrossRef Google scholar

[53]	Ma R, Yao L, Jin M, Ren P (2014). The DEA game cross-efficiency model for supplier selection problem under competition. Applied Mathematics & Information Sciences, 8(2): 811–818 CrossRef Google scholar

[54]	Mahdiloo M, Farzipoor Saen R, Lee K H (2015). Technical, environmental and eco-efficiency measurement for supplier selection: An extension and application of data envelopment analysis. International Journal of Production Economics, 168: 279–289 CrossRef Google scholar

[55]	Noorizadeh A, Mahdiloo M, Farzipoor Saen R (2013). Using DEA cross-efficiency evaluation for suppliers ranking in the presence of non-discretionary inputs. International Journal of Shipping and Transport Logistics, 5(1): 95–111 CrossRef Google scholar

[56]	Örkcü H H, Bal H (2011). Goal programming approaches for data envelopment analysis cross efficiency evaluation. Applied Mathematics and Computation, 218(2): 346–356 CrossRef Google scholar

[57]	Oukil A (2019). Embedding OWA under preference ranking for DEA cross-efficiency aggregation: Issues and procedures. International Journal of Intelligent Systems, 34(5): 947–965 CrossRef Google scholar

[58]	Park J, Bae H, Bae J (2014). Cross-evaluation-based weighted linear optimization for multi-criteria ABC inventory classification. Computers & Industrial Engineering, 76: 40–48 CrossRef Google scholar

[59]	Ramón N, Ruiz J L, Sirvent I (2010a). A multiplier bound approach to assess relative efficiency in DEA without slacks. European Journal of Operational Research, 203(1): 261–269 CrossRef Google scholar

[60]	Ramón N, Ruiz J L, Sirvent I (2010b). On the choice of weights profiles in cross-efficiency evaluations. European Journal of Operational Research, 207(3): 1564–1572 CrossRef Google scholar

[61]	Ramón N, Ruiz J L, Sirvent I (2011). Reducing differences between profiles of weights: A “peer-restricted” cross-efficiency evaluation. Omega, 39(6): 634–641 CrossRef Google scholar

[62]	Ramón N, Ruiz J L, Sirvent I (2014). Dominance relations and ranking of units by using interval number ordering with cross-efficiency intervals. Journal of the Operational Research Society, 65(9): 1336–1343 CrossRef Google scholar

[63]	Rezaee M J, Izadbakhsh H, Yousefi S (2016). An improvement approach based on DEA-game theory for comparison of operational and spatial efficiencies in urban transportation systems. KSCE Journal of Civil Engineering, 20(4): 1526–1531 CrossRef Google scholar

[64]	Rödder W, Reucher E (2011). A consensual peer-based DEA-model with optimized cross-efficiencies — Input allocation instead of radial reduction. European Journal of Operational Research, 212(1): 148–154 CrossRef Google scholar

[65]	Ruiz J L (2013). Cross-efficiency evaluation with directional distance functions. European Journal of Operational Research, 228(1): 181–189 CrossRef Google scholar

[66]	Sarkis J (2000). An analysis of the operational efficiency of major airports in the United States. Journal of Operations Management, 18(3): 335–351 CrossRef Google scholar

[67]	Sarkis J, Talluri S (2004). Performance based clustering for benchmarking of US airports. Transportation Research Part A, Policy and Practice, 38(5): 329–346 CrossRef Google scholar

[68]	Sarkis J, Weinrach J (2001). Using data envelopment analysis to evaluate environmentally conscious waste treatment technology. Journal of Cleaner Production, 9(5): 417–427 CrossRef Google scholar

[69]	Sexton T R, Silkman R H, Hogan A J (1986). Data envelopment analysis: Critique and extensions. New Directions for Program Evaluation, (32): 73–105

[70]	Shang J, Sueyoshi T (1995). A unified framework for the selection of a flexible manufacturing system. European Journal of Operational Research, 85(2): 297–315 CrossRef Google scholar

[71]	Shi H, Wang Y, Chen L (2019). Neutral cross-efficiency evaluation regarding an ideal frontier and anti-ideal frontier as evaluation criteria. Computers & Industrial Engineering, 132: 385–394 CrossRef Google scholar

[72]	Song L, Liu F (2018). An improvement in DEA cross-efficiency aggregation based on the Shannon entropy. International Transactions in Operational Research, 25(2): 705–714 CrossRef Google scholar

[73]	Song M, Zhang J, Wang S (2015). Review of the network environmental efficiencies of listed petroleum enterprises in China. Renewable & Sustainable Energy Reviews, 43: 65–71 CrossRef Google scholar

[74]	Song M, Zhu Q, Peng J, Santibanez Gonzalez E D R (2017). Improving the evaluation of cross efficiencies: A method based on Shannon entropy weight. Computers & Industrial Engineering, 112: 99–106 CrossRef Google scholar

[75]	Sun J, Fu Y, Ji X, Zhong R Y (2017a). Allocation of emission permits using DEA-game-theoretic model. Operations Research, 17(3): 867–884 CrossRef Google scholar

[76]	Sun J, Li G, Wang Z (2018a). Optimizing China’s energy consumption structure under energy and carbon constraints. Structural Change and Economic Dynamics, 47: 57–72 CrossRef Google scholar

[77]	Sun J, Li G, Wang Z (2019). Technology heterogeneity and efficiency of China’s circular economic systems: A game meta-frontier DEA approach. Resources, Conservation and Recycling, 146: 337–347 CrossRef Google scholar

[78]	Sun J, Wang Z, Li G (2018b). Measuring emission-reduction and energy-conservation efficiency of Chinese cities considering management and technology heterogeneity. Journal of Cleaner Production, 175: 561–571 CrossRef Google scholar

[79]	Sun J, Wu J, Guo D (2013). Performance ranking of units considering ideal and anti-ideal DMU with common weights. Applied Mathematical Modelling, 37(9): 6301–6310 CrossRef Google scholar

[80]	Sun J, Wu J, Wang Y, Li L, Wang Y (2018c). Cross-efficiency evaluation method based on the conservative point of view. Expert Systems, e12336 CrossRef Google scholar

[81]	Sun J, Yang R, Ji X, Wu J (2017b). Evaluation of decision-making units based on the weight-optimized DEA model. Kybernetika, 53(2): 244–262 CrossRef Google scholar

[82]	Sun J, Yuan Y, Yang R, Ji X, Wu J (2017c). Performance evaluation of Chinese port enterprises under significant environmental concerns: An extended DEA-based analysis. Transport Policy, 60: 75–86 CrossRef Google scholar

[83]	Sun S (2002). Assessing computer numerical control machines using data envelopment analysis. International Journal of Production Research, 40(9): 2011–2039 CrossRef Google scholar

[84]	Talluri S, Paul Yoon K (2000). A cone-ratio DEA approach for AMT justification. International Journal of Production Economics, 66(2): 119–129 CrossRef Google scholar

[85]	Tan Y, Zhang Y, Khodaverdi R (2017). Service performance evaluation using data envelopment analysis and balance scorecard approach: An application to automotive industry. Annals of Operations Research, 248(1–2): 449–470 CrossRef Google scholar

[86]	von Geymueller P (2009). Static versus dynamic DEA in electricity regulation: The case of US transmission system operators. Central European Journal of Operations Research, 17(4): 397–413 CrossRef Google scholar

[87]	Wang Y M, Chin K S (2010a). Some alternative models for DEA cross-efficiency evaluation. International Journal of Production Economics, 128(1): 332–338 CrossRef Google scholar

[88]	Wang Y M, Chin K S (2010b). A neutral DEA model for cross-efficiency evaluation and its extension. Expert Systems with Applications, 37(5): 3666–3675 CrossRef Google scholar

[89]	Wang Y M, Chin K S (2011). The use of OWA operator weights for cross-efficiency aggregation. Omega, 39(5): 493–503 CrossRef Google scholar

[90]	Wang Y M, Chin K S, Jiang P (2011a). Weight determination in the cross-efficiency evaluation. Computers & Industrial Engineering, 61(3): 497–502 CrossRef Google scholar

[91]	Wang Y M, Chin K S, Luo Y (2011b). Cross-efficiency evaluation based on ideal and anti-ideal decision making units. Expert Systems with Applications, 38(8): 10312–10319 CrossRef Google scholar

[92]	Wang Y M, Chin K S, Wang S (2012). DEA models for minimizing weight disparity in cross-efficiency evaluation. Journal of the Operational Research Society, 63(8): 1079–1088 CrossRef Google scholar

[93]	Wang Y M, Greatbanks R, Yang J B (2005). Interval efficiency assessment using data envelopment analysis. Fuzzy Sets and Systems, 153(3): 347–370 CrossRef Google scholar

[94]	Wang Y M, Wang S (2013). Approaches to determining the relative importance weights for cross-efficiency aggregation in data envelopment analysis. Journal of the Operational Research Society, 64(1): 60–69 CrossRef Google scholar

[95]	Wong Y H, Beasley J E (1990). Restricting weight flexibility in data envelopment analysis. Journal of the Operational Research Society, 41(9): 829–835 CrossRef Google scholar

[96]	Wu J, Chu J, Sun J, Zhu Q (2016a). DEA cross-efficiency evaluation based on Pareto improvement. European Journal of Operational Research, 248(2): 571–579 CrossRef Google scholar

[97]	Wu J, Chu J, Sun J, Zhu Q, Liang L (2016b). Extended secondary goal models for weights selection in DEA cross-efficiency evaluation. Computers & Industrial Engineering, 93: 143–151 CrossRef Google scholar

[98]	Wu J, Chu J, Zhu Q, Yin P, Liang L (2016c). DEA cross-efficiency evaluation based on satisfaction degree: An application to technology selection. International Journal of Production Research, 54(20): 5990–6007 CrossRef Google scholar

[99]	Wu J, Huang D, Zhou Z, Zhu Q (2020). The regional green growth and sustainable development of China in the presence of sustainable resources recovered from pollutions. Annals of Operations Research, 290: 27–45 CrossRef Google scholar

[100]

Wu J, Li M, Zhu Q, Zhou Z, Liang L (2019a). Energy and environmental efficiency measurement of China’s industrial sectors: A DEA model with non-homogeneous inputs and outputs. Energy Economics, 78: 468–480 CrossRef Google scholar

[101]

Wu J, Liang L (2012). A multiple criteria ranking method based on game cross-evaluation approach. Annals of Operations Research, 197(1): 191–200 CrossRef Google scholar

[102]

Wu J, Liang L, Chen Y (2009a). DEA game cross-efficiency approach to Olympic rankings. Omega, 37(4): 909–918 CrossRef Google scholar

[103]

Wu J, Liang L, Song M (2010). Performance based clustering for benchmarking of container ports: An application of DEA and cluster analysis technique. International Journal of Computational Intelligence Systems, 3(6): 709–722 CrossRef Google scholar

[104]

Wu J, Liang L, Yang F (2009b). Achievement and benchmarking of countries at the Summer Olympics using cross efficiency evaluation method. European Journal of Operational Research, 197(2): 722–730 CrossRef Google scholar

[105]

Wu J, Liang L, Yang F (2009c). Determination of the weights for the ultimate cross efficiency using Shapley value in cooperative game. Expert Systems with Applications, 36(1): 872–876 CrossRef Google scholar

[106]

Wu J, Liang L, Yang F, Yan H (2009d). Bargaining game model in the evaluation of decision making units. Expert Systems with Applications, 36(3): 4357–4362 CrossRef Google scholar

[107]

Wu J, Liang L, Zha Y (2009e). Preference voting and ranking using DEA game cross efficiency model. Journal of the Operations Research Society of Japan, 52(2): 105–111 CrossRef Google scholar

[108]

Wu J, Liang L, Zha Y, Yang F (2009f). Determination of cross-efficiency under the principle of rank priority in cross-evaluation. Expert Systems with Applications, 36(3): 4826–4829 CrossRef Google scholar

[109]

Wu J, Sun J, Liang L (2012a). Cross efficiency evaluation method based on weight-balanced data envelopment analysis model. Computers & Industrial Engineering, 63(2): 513–519 CrossRef Google scholar

[110]

Wu J, Sun J, Liang L (2012b). DEA cross-efficiency aggregation method based upon Shannon entropy. International Journal of Production Research, 50(23): 6726–6736 CrossRef Google scholar

[111]

Wu J, Sun J, Liang L, Zha Y (2011a). Determination of weights for ultimate cross efficiency using Shannon entropy. Expert Systems with Applications, 38(5): 5162–5165 CrossRef Google scholar

[112]

Wu J, Sun J, Song M, Liang L (2013). A ranking method for DMUs with interval data based on DEA cross-efficiency evaluation and TOPSIS. Journal of Systems Science and Systems Engineering, 22(2): 191–201 CrossRef Google scholar

[113]

Wu J, Sun J, Zha Y, Liang L (2011b). Ranking approach of cross-efficiency based on improved TOPSIS technique. Journal of Systems Engineering and Electronics, 22(4): 604–608 CrossRef Google scholar

[114]

Wu J, Xia P, Zhu Q, Chu J (2019b). Measuring environmental efficiency of thermoelectric power plants: A common equilibrium efficient frontier DEA approach with fixed-sum undesirable output. Annals of Operations Research, 275(2): 731–749 CrossRef Google scholar

[115]

Wu J, Yan H, Liu J (2009g). Groups in DEA based cross-evaluation: An application to Asian container ports. Maritime Policy & Management, 36(6): 545–558 CrossRef Google scholar

[116]

Wu Y C J, Goh M (2010). Container port efficiency in emerging and more advanced markets. Transportation Research Part E, Logistics and Transportation Review, 46(6): 1030–1042 CrossRef Google scholar

[117]

Xu J, Li Z (2012). A review on ecological engineering based engineering management. Omega, 40(3): 368–378 CrossRef Google scholar

[118]

Yang F, Ang S, Xia Q, Yang C (2012). Ranking DMUs by using interval DEA cross efficiency matrix with acceptability analysis. European Journal of Operational Research, 223(2): 483–488 CrossRef Google scholar

[119]

Yang G L, Yang J B, Liu W B, Li X X (2013). Cross-efficiency aggregation in DEA models using the evidential-reasoning approach. European Journal of Operational Research, 231(2): 393–404 CrossRef Google scholar

[120]

Yu M M, Ting S C, Chen M C (2010). Evaluating the cross-efficiency of information sharing in supply chains. Expert Systems with Applications, 37(4): 2891–2897 CrossRef Google scholar

[121]

Yu V F, Hu K J (2014). An integrated approach for resource allocation in manufacturing plants. Applied Mathematics and Computation, 245: 416–426 CrossRef Google scholar

[122]

Zerafat Angiz M, Mustafa A, Kamali M J (2013). Cross-ranking of decision making units in data envelopment analysis. Applied Mathematical Modelling, 37(1–2): 398–405 CrossRef Google scholar

[123]

Zopounidis C, Doumpos M (2002). Multicriteria classification and sorting methods: A literature review. European Journal of Operational Research, 138(2): 229–246 CrossRef Google scholar

[124]

Zoroofchi K H, Farzipoor Saen R, Lari P B, Azadi M (2018). A combination of range-adjusted measure, cross-efficiency and assurance region for assessing sustainability of suppliers in the presence of undesirable factors. International Journal of Industrial and Systems Engineering, 29(2): 163–176 CrossRef Google scholar

[125]

Zoroufchi K H, Azadi M, Farzipoor Saen R (2012). Developing a new cross-efficiency model with undesirable outputs for supplier selection. International Journal of Industrial and Systems Engineering, 12(4): 470–484 CrossRef Google scholar