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“Make to order or Make to Stock Model: and Application” S.Rajagopalan

“Make to order or Make to Stock Model: and Application” S.Rajagopalan. By: ÖNCÜ HAZIR. Content of Presentation. Introduction Literature Review Assumptions Trade-offs and Congestion Effects General Model and Relaxed Model Properties of O p timal Solu t ion & Solution Procedure

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“Make to order or Make to Stock Model: and Application” S.Rajagopalan

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  1. “Make to order or Make to Stock Model: and Application” S.Rajagopalan By: ÖNCÜ HAZIR

  2. Content of Presentation • Introduction • Literature Review • Assumptions • Trade-offs and Congestion Effects • General Model and Relaxed Model • Properties of OptimalSolution & Solution Procedure • Computational Study • Experimental Insights

  3. Introduction • Motivation is to determine whether an item is to make to stock(MTS) or make to order(MTO) and to offer an inventory policy for the make to stock items. • Characteristics of the production environment is multiple items,limited capacity and setups between the production of consecutive items. • Objective is minimize inventory costs of MTS items while ensuring that orders for MTO items are fullfilled with a sepicified probability.

  4. Literature Review • Popp(1965) made cost comparisons to make an item MTO or MTS for a single-item stochastic inventory model. • Williams(1984) assumed lower demand items are MTO and higher demand items as MTS. • Federgruen and Katalan(1995,1999) allowed the interruption of MTS items when MTO demand is realized. • Carr and Duenyas(1998) focuses on criteria to accept or reject MTO items. • Karmakar(1987) considers the queue length as a decision variable.

  5. Assumptions • Stochastic stationary, uncorrelated demand,varying processing times and limited capacity. • No inventory is carried for MTO items. • (Q,R) inventory policy is used for MTS items. • First come first served (FCFS) queue discipline. • Production facility is approximated by M/G/1 queue discipline.

  6. Assumptions • Setup and processing times are deterministic. • Type 1() service level represents probability of no stockout. • The distribution of demand during lead time is characterized by queue time,material handling times are ignored. • Whenever there exists a demand for MTO in the time period,a production order is initiated for a batch size equal to demand quantity.

  7. Trade-offs and Congestion Effects • Making an item to order: • Decreases inventory, • Congestion effect: • Making an item to stock: • Decreasing the lot size reduces cycle stock but increases number of setups and utilization so lead time increases.As a result more cyle and safety stock for MTO items and poorer service for MTO items. Higher cycle and safety stock for MTS and poorer service for MTO Longer and variable lead times More setups and higher utilization

  8. Model Parameters

  9. General Model Min ST

  10. Model without congestion effects Min ST

  11. Properties of optimal solution

  12. Solution procedure • 1)Set zi=1 for all i and set = maxi{mi2ihi/2i} • 2)Compute i for all items, if i <= 0 set zi=0, arrange items in order of decreasing ratioi • 3) Set zi=0 in the order determined above.Compute lot sizes and costs, check whether total cost declines.If cost decreases stop. • For the heuristic with congestion effects the ratio i includes cost of safety stock and for a given value of zi,a non-linear program is solved.

  13. Application of Model

  14. Computational Study • The heuristic performance was evaluated relative to lower bounds.Average percentage duality gap between heuristic gap and lower bound was performance criteria. • It is found that the heuristic works well.

  15. Experimental Insights • The MTS/MTO decisions with and without considering congestion effects were similar. • The lowest and highest demand items are MTO medium demand items are MTS since incremental capacity to make an item to MTO is concave in the average demand. • In addition to items demand decision depends on processing times,unit holding cost and set uptime. • As size of time bucket increases, number of MTO items increase and total cost decreases.However customer responsiveness decreases.

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