Abstract
Goal programming (GP) can be thought of as an extension or generalization of linear programming to handle multiple, normally conflicting objective measures. Each of these measures is given a goal or target value to be achieved. Unwanted deviations from this set of target values are then minimized in an achievement function. Production planning is an important process that aims to leverage the resources available in industry to achieve one or more business goals. However, the production planning that typically uses mathematical models has its own challenges where parameter models are sometimes difficult to find easily and accurately. Data collected with various data collection methods and human experts’ judgments are often prone to uncertainties that can affect the information presented by quantitative results. This study focuses on resolving data uncertainties as well as multi-objective optimization using fuzzy random methods and GP in production planning problems. GP was enhanced with fuzzy random features. Scalable approaches and maximum minimum operators were then used to solve multi-object optimization problems. Scaled indices were also introduced to resolve fuzzy symbols containing unspecified relationships. The application results indicate that the proposed approach can mitigate the characteristics of uncertainty in the analysis and achieve a satisfactory optimized solution.
Highlights
Goal programming (GP) is a branch of multiobjective optimization, which in turn is a branch of multi-criteria decision analysis (MCDA), known as multiple-criteria decision making (MCDM)
Considering hybrid uncertainty [14], we provide the methodology of fuzzy goal programming (FGP) in hybrid uncertainty
We explore the renewal of the Fuzzy Goal Programming (FGP) technique to multi-objective problems with hybrid uncertainty, which is motivated by the challenges of such scenarios
Summary
Goal programming (GP) is a branch of multiobjective optimization, which in turn is a branch of multi-criteria decision analysis (MCDA), known as multiple-criteria decision making (MCDM). It can be thought of as an extension or generalization of linear programming to handle multiple, normally conflicting objective measures. Each of these measures is given a goal or target value to be achieved. Data with a variety of uncertainties, such as political uncertainty, risk, insufficient knowledge, and random events, might have an impact on the dada’s reliability [12,13] These uncertainties can have an impact on the information provided by quantitative results [13].
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