Multi-objective inventory model incorporating shortage cost and delayed replenishment with diverse fuzzy number applications using C++ programming language

Singaravelu  Nandhini; Jeevanantham  Jayanthi

doi:10.5269/bspm.77950

Singaravelu Nandhini
Jeevanantham Jayanthi

Resumo

Today’s supply chains face many problems, especially when it comes to managing inventory. Delays in getting supplies, sudden changes in customer demand, and the high cost of running out of stock make planning difficult. Most traditional models use fixed values, which don’t work well when things are uncertain. Although fuzzy logic has been used to handle uncertainty, many studies only use simple fuzzy numbers, which don’t fully capture the complexity of real-life situations. This study introduces an improved inventory model that considers both shortage costs and delays in restocking. It uses four types of fuzzy numbers trapezoidal, pentagonal, hexagonal, and decagonal to show different levels of uncertainty more accurately. The model is programmed in C++ and uses a special method called graded mean integration to turn fuzzy numbers into useful values. Results show that while trapezoidal numbers produce basic results, pentagonal and hexagonal numbers are better especially hexagonal, which provides the lowest overall cost. The model also deals with uncertainty in how long restocking takes. The article examines a fuzzy inventory model using trapezoidal, pentagonal, and hexagonal fuzzy numbers. It finds trapezoidal fuzzy numbers ineffective for cost efficiency, while pentagonal and hexagonal fuzzy numbers outperform crisp models, enhancing inventory management decision-making.

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