Decision models for evaluation and selection of suppliers in the presence of ‎cardinal and ordinal data, weight restrictions, and non-discretionary factors: ‎An approach based on DEA with double frontiers

Azizi, Hossein; Jahed, Rasul

Manuscript ID : IMJ-1811-1149 (R1) Visit : 143 Page: 1 - 23

Article Type: Original Research

Decision models for evaluation and selection of suppliers in the presence of ‎cardinal and ordinal data, weight restrictions, and non-discretionary factors: ‎An approach based on DEA with double frontiers

Subject Areas : Industrial Management

1 - Department of Applied Mathematics, Parsabad Moghan Branch, Islamic Azad University, Parsabad Moghan, Iran.
2 - Department of Mathematics, Germi Branch, Islamic Azad University, Germi, Iran

Received: 2018-11-11 Accepted : 2019-09-18 Published : 2020-01-21

Keywords: Optimistic and pessimistic efficiencies‎, Data envelopment analysis, Weight restriction and Non-discretionary factors, ‎Cardinal and ordinal data, Supplier selection,

Abstract :

Selection of suppliers for outsourcing is now one of the most important decisions of the purchasing ‎department. These decisions constitute an important part of the production and logistics ‎management in many firms. On the other hand, suppliers can be evaluated and selected from ‎optimistic and pessimistic perspectives. There is an argument that both points of view must be ‎considered simultaneously, and any approach that considers only one perspective is biased. This ‎paper proposes a new “data envelopment analysis (DEA) with double frontiers” approach for ‎evaluation and selection of suppliers. The DEA with double frontiers approach can identify the best ‎supplier in the presence of weight restrictions, non-discretionary factors, and cardinal and ordinal ‎data. This paper proposes to integrate both efficiencies in the form of a geometric mean efficiency ‎that measures the overall performance of each supplier. It is shown that geometric mean efficiency ‎has more discriminative power than any of the optimistic and pessimistic efficiencies. A numerical ‎example illustrates the application of the proposed method.‎

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