A spherical fuzzy AHP model for contractor assessment during project life cycle

IF 1.7 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of the Mechanical Behavior of Materials Pub Date : 2022-01-01 DOI:10.1515/jmbm-2022-0042

Hayder Ghazi Abdulkareem, K. R. Erzaij

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引用次数: 2

Abstract

Abstract Measurement of construction performance is essential to a clear image of the present situation. This monitoring by the management team is necessary to identify locations where performance is exceptionally excellent or poor and to identify the primary reasons so that the lessons gained may be exported to the firm and its progress strengthened. This research attempts to construct an integrated mathematical model utilizing one of the recent methodologies for dealing with the fuzzy representation of experts’ knowledge and judgment considering hesitancy called spherical fuzzy analytic hierarchy process (SFAHP) method to assess the contractor’s performance per the project performance parameters (cost, schedule, quality, leadership, and change management). At the same time, most project control systems are currently applied through software like Primavera P6 or MS Project. These look at a project’s cost and schedule status by following the earned value analysis for finding the performance. Based on decision makers’ preferences, the analytic hierarchy process (AHP) may be used to arrive at the optimum conclusion. AHP approaches are discussed, including AHP, grey-AHP, fuzzy-AHP, and SFAHP weights comparison. Calculation results showed that the spherical fuzzy approach differs significantly from the other approaches where it considers the decision maker’s hesitation when making linguistic multicriteria decisions and then, as a result, recommends applying periodically for performance measurement. This model can be viewed as a valuable way to help the decision-making stakeholders in the construction sector do the best job about critical issues at a suitable time.

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项目全生命周期承包商评价的球面模糊层次分析法

摘要建筑性能的测量对于清晰地了解现状至关重要。管理团队的这种监测是必要的，以确定绩效异常优秀或较差的地点，并确定主要原因，从而将所获得的经验教训输出到公司，并加强其进展。本研究试图利用一种最新的方法来处理专家知识和判断的模糊表示，并考虑到犹豫，构建一个综合数学模型，称为球面模糊层次分析法（SFAHP），根据项目绩效参数评估承包商的绩效（成本、进度、质量、领导力和变更管理）。同时，目前大多数项目控制系统都是通过Primavera P6或MS project等软件应用的。它们通过遵循挣值分析来查找性能，从而查看项目的成本和进度状态。基于决策者的偏好，可以使用层次分析法（AHP）来得出最优结论。讨论了AHP方法，包括AHP、灰色AHP、模糊AHP和SFAHP权重比较。计算结果表明，球形模糊方法与其他方法有很大不同，在其他方法中，球形模糊算法考虑了决策者在做出语言多准则决策时的犹豫，因此建议定期应用于绩效衡量。该模型可以被视为一种有价值的方式，帮助建筑行业的决策利益相关者在适当的时候就关键问题做得最好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of the Mechanical Behavior of Materials Materials Science-Materials Science (miscellaneous)

CiteScore

3.00

自引率

11.10%

发文量

审稿时长

30 weeks

期刊介绍： The journal focuses on the micromechanics and nanomechanics of materials, the relationship between structure and mechanical properties, material instabilities and fracture, as well as size effects and length/time scale transitions. Articles on cutting edge theory, simulations and experiments – used as tools for revealing novel material properties and designing new devices for structural, thermo-chemo-mechanical, and opto-electro-mechanical applications – are encouraged. Synthesis/processing and related traditional mechanics/materials science themes are not within the scope of JMBM. The Editorial Board also organizes topical issues on emerging areas by invitation. Topics Metals and Alloys Ceramics and Glasses Soils and Geomaterials Concrete and Cementitious Materials Polymers and Composites Wood and Paper Elastomers and Biomaterials Liquid Crystals and Suspensions Electromagnetic and Optoelectronic Materials High-energy Density Storage Materials Monument Restoration and Cultural Heritage Preservation Materials Nanomaterials Complex and Emerging Materials.