Ordinal priority approach
Ordinal priority approach (OPA) is a multiple-criteria decision analysis method that aids in solving the group decision-making problems based on preference relations.
Description
Various methods have been proposed to solve multi-criteria decision-making problems.[1] The basis of most methods such as analytic hierarchy process and analytic network process is pairwise comparison matrix.[2] The advantages and disadvantages of the pairwise comparison matrix were discussed by Monier and Hontoria in their book.[3] In recent years, the OPA method was proposed to solve the multi-criteria decision-making problems based on the ordinal data instead of using the pairwise comparison matrix.[4]
This method uses linear programming approach to compute the weights of experts, criteria, and alternatives simultaneously.[5] The main reason for using ordinal data in the OPA method is the accessibility and accuracy of the ordinal data compared with exact ratios used in group decision-making problems involved with humans.[6]
In real-world situations, the experts might not have enough knowledge regarding one alternative or criterion. In this case, the input data of the problem is incomplete, which needs to be incorporated into the linear programming of the OPA. To handle the incomplete input data in the OPA method, the constraints related to the criteria or alternatives should be removed from the OPA linear-programming model.[7]
Various types of data normalization methods were employed in multi-criteria decision-making methods in recent years. Palczewski and Sałabun showed that using various data normalization methods can change the final ranks of the multi-criteria decision-making methods.[8] Javed and colleagues showed that a multiple-criteria decision-making problem can be solved by avoiding the data normalization.[9] There is no need to normalize the preference relations and thus, the OPA method does not require data normalization.[10]
The OPA method
The OPA model is a linear programming model, which can be solved using a simplex algorithm. The steps of this method are as follows:[11]
Step 1: Identifying the experts and determining the preference of experts based on their working experience, educational qualification, etc.
Step 2: identifying the criteria and determining the preference of the criteria by each expert.
Step 3: identifying the alternatives and determining the preference of the alternatives in each criterion by each expert.
Step 4: Constructing the following linear programming model and solving it by an appropriate optimization software such as LINGO, GAMS, MATLAB, etc.
In the above model, represents the rank of expert , represents the rank of criterion , represents the rank of alternative , and represents the weight of alternative in criterion by expert . After solving the OPA linear programming model, the weight of each alternative is calculated by the following equation:
The weight of each criterion is calculated by the following equation:
And the weight of each expert is calculated by the following equation:
Example
Suppose that we are going to investigate the issue of buying a house. There are two experts in this decision problem. Also, there are two criteria called cost (c), and construction quality (q) for buying the house. On the other hand, there are three houses (h1, h2, h3) for purchasing. The first expert (x) has three years of working experience and the second expert (y) has two years of working experience. The structure of the problem is shown in the figure.
Step 1: The first expert (x) has more experience than expert (y), hence x > y.
Step 2: The criteria and their preference are summarized in the following table:
Criteria | Expert (x) | Expert (y) |
---|---|---|
c | 1 | 2 |
q | 2 | 1 |
Step 3: The alternatives and their preference are summarized in the following table:
Alternatives | Expert (x) | Expert (y) | ||
---|---|---|---|---|
c | q | c | q | |
h1 | 1 | 2 | 1 | 3 |
h2 | 3 | 1 | 2 | 1 |
h3 | 2 | 3 | 3 | 2 |
Step 4: The OPA linear programming model is formed based on the input data as follows:
After solving the above model using optimization software, the weights of experts, criteria and alternatives are obtained as follows:
Therefore, House 1 (h1) is considered as the best alternative. Moreover, we can understand that criterion cost (c) is more important than criterion construction quality (q). Also, based on the experts' weights, we can understand that expert (x) has a higher impact on final selection compared with expert (y).
Applications
The applications of the OPA method in various field of studies are summarized as follows:
Agriculture, manufacturing, services
- Manufacturing supply chain[12][13]
- Sustainable agriculture[14]
- Production strategies[15]
- Community service demand[18]
Construction industry
Energy and environment
- Solar and wind energies[26]
- Electrification and emissions[27]
- Circular economy[22]
Healthcare
- Healthcare supply chain[29]
- Community services[30]
Information technology
- Technology demand[35]
Transportation
- Road maintenance[38]
Extensions
Several extensions of the OPA method are listed as follows:
- Grey ordinal priority approach (OPA-G)[10]
- Fuzzy ordinal priority approach (OPA-F)[28]
- Ordinal priority approach under picture fuzzy sets (OPA-P)[36]
- Confidence level measurement in the OPA[11]
- Neutrosophic ordinal priority approach (OPA-N)[39]
- Rough ordinal priority approach[31]
- Robust ordinal priority spproach (OPA-R)[25]
- Hybrid OPA–Fuzzy EDAS[15]
- Hybrid DEA-OPA model[13]
- Hybrid MULTIMOORA-OPA[40]
- Group-weighted ordinal priority spproach (GWOPA)[41]
Software
The following non-profit tools are available to solve the MCDM problems using the OPA method:
References
- ^ Mardani, Abbas; Jusoh, Ahmad; MD Nor, Khalil; Khalifah, Zainab; Zakwan, Norhayati; Valipour, Alireza (2015). "Multiple criteria decision-making techniques and their applications – a review of the literature from 2000 to 2014". Economic Research-Ekonomska Istraživanja. 28 (1): 516–571. doi:10.1080/1331677x.2015.1075139. ISSN 1331-677X. S2CID 57402259. Archived from the original on 2022-09-23. Retrieved 2022-09-23.
- ^ Penadés-Plà, Vicent; García-Segura, Tatiana; Martí, José; Yepes, Víctor (2016-12-09). "A Review of Multi-Criteria Decision-Making Methods Applied to the Sustainable Bridge Design". Sustainability. 8 (12): 1295. doi:10.3390/su8121295. ISSN 2071-1050.
- ^ Munier, Nolberto; Hontoria, Eloy (2021). Uses and Limitations of the AHP Method. Management for Professionals. Springer Nature. doi:10.1007/978-3-030-60392-2. ISBN 978-3-030-60392-2. S2CID 241759250. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ a b Ataei, Younes; Mahmoudi, Amin; Feylizadeh, Mohammad Reza; Li, Deng-Feng (1 January 2020). "Ordinal Priority Approach (OPA) in Multiple Attribute Decision-Making". Applied Soft Computing. 86: 105893. doi:10.1016/j.asoc.2019.105893. S2CID 209928171.
- ^ a b Sotoudeh-Anvari, Alireza (1 September 2022). "The applications of MCDM methods in COVID-19 pandemic: A state of the art review". Applied Soft Computing. 126: 109238. doi:10.1016/j.asoc.2022.109238. PMC 9245376. PMID 35795407.
- ^ Wang, Haomin; Peng, Yi; Kou, Gang (1 July 2021). "A two-stage ranking method to minimize ordinal violation for pairwise comparisons". Applied Soft Computing. 106: 107287. doi:10.1016/j.asoc.2021.107287. S2CID 233657592.
- ^ a b Mahmoudi, Amin; Deng, Xiaopeng; Javed, Saad Ahmed; Yuan, Jingfeng (2021-10-01). "Large-scale multiple criteria decision-making with missing values: project selection through TOPSIS-OPA". Journal of Ambient Intelligence and Humanized Computing. 12 (10): 9341–9362. doi:10.1007/s12652-020-02649-w. ISSN 1868-5145. S2CID 228929310. Archived from the original on 2022-09-23. Retrieved 2022-09-23.
- ^ Palczewski, Krzysztof; Sałabun, Wojciech (2019). "Influence of various normalization methods in PROMETHEE II: an empirical study on the selection of the airport location". Procedia Computer Science. 159: 2051–2060. doi:10.1016/j.procs.2019.09.378. ISSN 1877-0509. S2CID 207756779. Archived from the original on 2022-09-23. Retrieved 2022-09-22.
- ^ Ahmed Javed, Saad; Gunasekaran, Angappa; Mahmoudi, Amin (2022-09-22). "DGRA: Multi-sourcing and Supplier Classification through Dynamic Grey Relational Analysis Method". Computers & Industrial Engineering: 108674. doi:10.1016/j.cie.2022.108674. ISSN 0360-8352. S2CID 252478074.
- ^ a b c d Mahmoudi, Amin; Deng, Xiaopeng; Javed, Saad Ahmed; Zhang, Na (January 2021). "Sustainable Supplier Selection in Megaprojects: Grey Ordinal Priority Approach". Business Strategy and the Environment. 30 (1): 318–339. doi:10.1002/bse.2623. S2CID 224917346.
- ^ a b c Mahmoudi, Amin; Javed, Saad Ahmed (October 2022). "Probabilistic Approach to Multi-Stage Supplier Evaluation: Confidence Level Measurement in Ordinal Priority Approach". Group Decision and Negotiation. 31 (5): 1051–1096. doi:10.1007/s10726-022-09790-1. PMC 9409630. PMID 36042813.
- ^ Ahmed Javed, Saad; Gunasekaran, Angappa; Mahmoudi, Amin (2022-09-22). "DGRA: Multi-sourcing and Supplier Classification through Dynamic Grey Relational Analysis Method". Computers & Industrial Engineering: 108674. doi:10.1016/j.cie.2022.108674. ISSN 0360-8352. S2CID 252478074.
- ^ a b Mahmoudi, Amin; Abbasi, Mehdi; Deng, Xiaopeng (April 2022). "Evaluating the Performance of the Suppliers Using Hybrid DEA-OPA Model: A Sustainable Development Perspective". Group Decision and Negotiation. 31 (2): 335–362. doi:10.1007/s10726-021-09770-x.
- ^ a b Islam, Shajedul (2021-07-28). "Evaluation of Low-Carbon Sustainable Technologies in Agriculture Sector through Grey Ordinal Priority Approach". International Journal of Grey Systems. 1 (1): 5–26. doi:10.52812/ijgs.3. ISSN 2767-3308. S2CID 237463151. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ a b Le, Minh-Tai; Nhieu, Nhat-Luong (January 2022). "A Novel Multi-Criteria Assessment Approach for Post-COVID-19 Production Strategies in Vietnam Manufacturing Industry: OPA–Fuzzy EDAS Model". Sustainability. 14 (8): 4732. doi:10.3390/su14084732.
- ^ Tafakkori, Keivan; Tavakkoli-Moghaddam, Reza; Siadat, Ali (2022). "Sustainable negotiation-based nesting and scheduling in additive manufacturing systems: A case study and multi-objective meta-heuristic algorithms". Engineering Applications of Artificial Intelligence. 112: 104836. doi:10.1016/j.engappai.2022.104836. ISSN 0952-1976. S2CID 247829389. Archived from the original on 2022-09-23. Retrieved 2022-09-20.
- ^ Bah, M. K.; Tulkinov, S. (2022-07-20). "Evaluation of Automotive Parts Suppliers through Ordinal Priority Approach and TOPSIS | Management Science and Business Decisions". doi:10.52812/msbd.37. S2CID 250934141. Archived from the original on 2022-07-21. Retrieved 2022-09-19.
{{cite journal}}
: Cite journal requires|journal=
(help) - ^ Li, Jintao; Dai, Yan; Wang, Cynthia Changxin; Sun, Jun (2022). "Assessment of Environmental Demands of Age-Friendly Communities from Perspectives of Different Residential Groups: A Case of Wuhan, China". International Journal of Environmental Research and Public Health. 19 (15): 9120. doi:10.3390/ijerph19159120. ISSN 1660-4601. PMC 9368052. PMID 35897508.
- ^ Mahmoudi, Amin; Javed, Saad Ahmed (April 2022). "Performance Evaluation of Construction Sub‐contractors using Ordinal Priority Approach". Evaluation and Program Planning. 91: 102022. doi:10.1016/j.evalprogplan.2021.102022. PMID 34736766. S2CID 239609916.
- ^ a b Sadeghi, Mahsa; Mahmoudi, Amin; Deng, Xiaopeng (February 2022). "Adopting distributed ledger technology for the sustainable construction industry: evaluating the barriers using Ordinal Priority Approach". Environmental Science and Pollution Research. 29 (7): 10495–10520. doi:10.1007/s11356-021-16376-y. PMC 8443118. PMID 34528198.
- ^ a b Sadeghi, Mahsa; Mahmoudi, Amin; Deng, Xiaopeng (19 April 2022). "Blockchain technology in construction organizations: risk assessment using trapezoidal fuzzy ordinal priority approach". Engineering, Construction and Architectural Management. doi:10.1108/ECAM-01-2022-0014. S2CID 248225580.
- ^ a b c Sadeghi, M.; Mahmoudi, A.; Deng, X.; Luo, X. (27 June 2022). "Prioritizing requirements for implementing blockchain technology in construction supply chain based on circular economy: Fuzzy Ordinal Priority Approach". International Journal of Environmental Science and Technology. doi:10.1007/s13762-022-04298-2. S2CID 250065647.
- ^ a b Mahmoudi, Amin; Sadeghi, Mahsa; Deng, Xiaopeng (2022-04-12). "Performance measurement of construction suppliers under localization, agility, and digitalization criteria: Fuzzy Ordinal Priority Approach". Environment, Development and Sustainability: 1–26. doi:10.1007/s10668-022-02301-x. ISSN 1387-585X. PMC 9001166. PMID 35431618.
- ^ Faisal, Mohd. Nishat; Al Subaie, Abdulla Abdulaziz; Sabir, Lamay Bin; Sharif, Khurram Jahangir (2022-01-01). "PMBOK, IPMA and fuzzy-AHP based novel framework for leadership competencies development in megaprojects". Benchmarking: An International Journal. ahead-of-print (ahead-of-print). doi:10.1108/BIJ-10-2021-0583. ISSN 1463-5771. S2CID 250940618. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ a b Mahmoudi, Amin; Abbasi, Mehdi; Deng, Xiaopeng (February 2022). "A novel project portfolio selection framework towards organizational resilience: Robust Ordinal Priority Approach". Expert Systems with Applications. 188: 116067. doi:10.1016/j.eswa.2021.116067.
- ^ Elkadeem, Mohamed R.; Younes, Ali; Mazzeo, Domenico; Jurasz, Jakub; Elia Campana, Pietro; Sharshir, Swellam W.; Alaam, Mohamed A. (2022). "Geospatial-assisted multi-criterion analysis of solar and wind power geographical-technical-economic potential assessment". Applied Energy. 322: 119532. doi:10.1016/j.apenergy.2022.119532. ISSN 0306-2619. S2CID 250062623.
- ^ a b Candra, Cliford Septian (2022-07-29). "Evaluation of Barriers to Electric Vehicle Adoption in Indonesia through Grey Ordinal Priority Approach | International Journal of Grey Systems". doi:10.52812/ijgs.46. S2CID 251183598.
{{cite journal}}
: Cite journal requires|journal=
(help) - ^ a b c Mahmoudi, Amin; Javed, Saad Ahmed; Mardani, Abbas (June 2022). "Gresilient supplier selection through Fuzzy Ordinal Priority Approach: decision-making in post-COVID era". Operations Management Research. 15 (1–2): 208–232. doi:10.1007/s12063-021-00178-z. S2CID 232240914.
- ^ Quartey-Papafio, T. K.; Shajedul, I.; Dehaghani, A. R. (2021-07-25). "Evaluating Suppliers for Healthcare Centre using Ordinal Priority Approach | Management Science and Business Decisions". doi:10.52812/msbd.12. S2CID 237950190. Archived from the original on 2021-08-04. Retrieved 2022-09-19.
{{cite journal}}
: Cite journal requires|journal=
(help) - ^ Dorado Chaparro, Javier; Fernández-Bermejo Ruiz, Jesús; Santofimia Romero, María José; del Toro García, Xavier; Cantarero Navarro, Rubén; Bolaños Peño, Cristina; Llumiguano Solano, Henry; Villanueva Molina, Félix Jesús; Gonçalves Silva, Anabela; López, Juan Carlos (2022-05-01). "Phyx.io: Expert-Based Decision Making for the Selection of At-Home Rehabilitation Solutions for Active and Healthy Aging". International Journal of Environmental Research and Public Health. 19 (9): 5490. doi:10.3390/ijerph19095490. ISSN 1660-4601. PMC 9103419. PMID 35564884.
- ^ a b c Pamucar, Dragan; Deveci, Muhammet; Gokasar, Ilgin; Tavana, Madjid; Köppen, Mario (2022). "A metaverse assessment model for sustainable transportation using ordinal priority approach and Aczel-Alsina norms". Technological Forecasting and Social Change. 182: 121778. doi:10.1016/j.techfore.2022.121778. ISSN 0040-1625. S2CID 249799590. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ a b Deveci, Muhammet; Pamucar, Dragan; Gokasar, Ilgin; Koppen, Mario; Gupta, Brij B. (2022). "Personal Mobility in Metaverse With Autonomous Vehicles Using Q-Rung Orthopair Fuzzy Sets Based OPA-RAFSI Model". IEEE Transactions on Intelligent Transportation Systems: 1–10. doi:10.1109/TITS.2022.3186294. S2CID 250507795.
- ^ Deveci, Muhammet; Pamucar, Dragan; Gokasar, Ilgin; Pedrycz, Witold; Wen, Xin (2022). "Autonomous Bus Operation Alternatives in Urban Areas Using Fuzzy Dombi-Bonferroni Operator Based Decision Making Model". IEEE Transactions on Intelligent Transportation Systems: 1–10. doi:10.1109/TITS.2022.3202111. ISSN 1524-9050. S2CID 252349294. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ Su, Chong; Ma, Xuri; Lv, Jing; Tu, Tao; Li, Hongguang (2022). "A multilayer affective computing model with evolutionary strategies reflecting decision-makers' preferences in process control". ISA Transactions. 128 (Pt B): 565–578. doi:10.1016/j.isatra.2021.11.038. ISSN 0019-0578. PMID 34953588. S2CID 245168890. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ Amirghodsi, Sirous; Naeini, Ali Bonyadi; Makui, Ahmad (2022). "An Integrated Delphi-DEMATEL-ELECTRE Method on Gray Numbers to Rank Technology Providers". IEEE Transactions on Engineering Management. 69 (4): 1348–1364. doi:10.1109/tem.2020.2980127. ISSN 0018-9391. S2CID 218924240. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ a b Pamucar, Dragan; Deveci, Muhammet; Gokasar, Ilgin; Martínez, Luis; Köppen, Mario (1 July 2022). "Prioritizing transport planning strategies for freight companies towards zero carbon emission using ordinal priority approach". Computers & Industrial Engineering. 169: 108259. doi:10.1016/j.cie.2022.108259. S2CID 248978509.
- ^ Bouraima, Mouhamed Bayane; Kiptum, Clement Kiprotich; Ndiema, Kevin Maraka; Qiu, Yanjun; Tanackov, Ilija (2022-08-19). "Prioritization Road Safety Strategies Towards Zero Road Traffic Injury Using Ordinal Priority Approach". Operational Research in Engineering Sciences: Theory and Applications. 5 (2): 206–221. doi:10.31181/oresta190822150b. ISSN 2620-1747. S2CID 251728499. Archived from the original on 2022-08-21. Retrieved 2022-09-19.
- ^ Bouraima, Mouhamed Bayane; Qiu, Yanjun; Kiptum, Clement Kiprotich; Ndiema, Kevin Maraka (2022-08-17). "Evaluation of Factors Affecting Road Maintenance in Kenyan Counties Using the Ordinal Priority Approach". Journal of Computational and Cognitive Engineering. doi:10.47852/bonviewJCCE2202272. ISSN 2810-9503. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ Abdel-Basset, Mohamed; Mohamed, Mai; Abdel-monem, Ahmed; Elfattah, Mohamed Abd (2022-04-29). "New extension of ordinal priority approach for multiple attribute decision-making problems: design and analysis". Complex & Intelligent Systems: 1–16. doi:10.1007/s40747-022-00721-w. ISSN 2199-4536. PMC 9051802. PMID 35505994. Archived from the original on 2022-09-23. Retrieved 2022-09-23.
- ^ Irvanizam, Irvanizam; Zulfan, Zulfan; Nasir, Puti F.; Marzuki, Marzuki; Rusdiana, Siti; Salwa, Nany (2022). "An Extended MULTIMOORA Based on Trapezoidal Fuzzy Neutrosophic Sets and Objective Weighting Method in Group Decision-Making". IEEE Access. 10: 47476–47498. doi:10.1109/access.2022.3170565. ISSN 2169-3536. S2CID 248698791. Archived from the original on 2022-09-23. Retrieved 2022-09-19.
- ^ Mahmoudi, Amin; Abbasi, Mehdi; Yuan, Jingfeng; Li, Lingzhi (7 September 2022). "Large-scale group decision-making (LSGDM) for performance measurement of healthcare construction projects: Ordinal Priority Approach". Applied Intelligence. 52 (12): 13781–13802. doi:10.1007/s10489-022-04094-y. PMC 9449288. PMID 36091930.
- ^ "Web-based solver". ordinalpriorityapproach.com. Retrieved 2022-10-15.
- ^ Excel-based solver, Zenodo, 2021-01-21, retrieved 2022-10-15
- ^ Lingo-based solver, github.com, 2022-07-07, retrieved 2022-10-15
- ^ "Matlab-based solver". www.mathworks.com. Retrieved 2022-10-15.