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Inventory (Chapter 16)

Inventory (Chapter 16)

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Inventory (Chapter 16)

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  1. Inventory (Chapter 16) What is Inventory? How Inventory works: two ways of ordering based on three elements Inventory models (to p2) (to p3) (to p4) (to p5)

  2. Inventory - to study methods to deal with “how much stock of items should be kept on hands that would meet customer demand” Objectives are to determine: a) how much to order, and b) when to order (to p1)

  3. Two basic types of Inventory Systems 1) continuous (fixed-order quantity) • an order is placed for the same constant amount when inventory decreases to a specified level, ie. Re-order point 2) periodic (fixed-time) • an order is placed for a variable amount after a specified period of time • used in smaller retail stores, drugstores, grocery stores and offices (to p1)

  4. 3 basic inventory elements • Carrying cost, Cc • Include facility operating costs, record keeping, interest, etc. • Ordering cost, Co • Include purchase orders, shipping, handling, inspection, etc. • Shortage (stock out) cost, Cs • Sometimes peanlties involved; if customer is internal, work delays could result (to p1)

  5. Inventory models Here, we only study the following three different models: 1. Basic model 8th ed: 1, 15, 19, 9th ed: 1, 10, 13, 2. Model with “discount rate” 8th: 24, 26; 9th: 17, 18 3. Model with “re-order points” 8th: 36, 38; 9th: 26,28 (to p6) (to p23) (to p31)

  6. 1. Basic model The basic model is known as: “Economic Order Quantity” (EOQ) Models Objective is to determine the optimal order size that will minimize total inventory costs How the objective is being achieved? (to p7)

  7. 3 Basic EOQ models Three models to be discussed: • Basic EOQ model • EOQ model without instantaneous receipt 3. EOQ model with shortages. (to p8) (to p15) (to p18) (to p5)

  8. The Basic EOQ Model • The optimal order size, Q, is to minimize the sum of carrying costs and ordering costs. • Assumptions and Restrictions: - Demand is known with certainty and is relatively constant over time. - No shortages are allowed. - Lead time for the receipt of orders is constant. (will consider later) - The order quantity is received all at once and instantaniously. How to determine the optimal value Q*? (to p10)

  9. Determine of Q We try to • Find the total cost that need to spend for keeping inventory on hands • = total ordering + stock on hands • Determine its optimal solution by finding its first derivative with respect to Q How to get these values? • Find out the total carrying cost • Find out the total ordering cost • Total cost = 1 + 2 • d (Total cost) /d Q = 0, and find Q* (to p10)

  10. The Basic EOQ Model We assumed that, we will only keep half the inventory over a year then The total carry cost/yr = Cc x (Q/2). Total order cost = Co x (D/Q) (to p11) Finding optimal Q* Then , Total cost =

  11. The Basic EOQ Model • EOQ occurs where total cost curve is at minimum value and carrying cost equals ordering cost: • Where is Q* located in our model? * Then, (How to obtain this?) (to p12)

  12. To order inventory To keep inventory The Basic EOQ Model • Total annual inventory cost is sum of ordering and carrying cost: Figure 16.5 The EOQ cost model Try to get this value (to p13) Examples

  13. The Basic EOQ ModelExample Consider the following: * No. of working days/yr Note: You should pay attention that all measurement units must be the same Consider the same example, with yearly (to p14)

  14. The Basic EOQ ModelEOQ Analysis with monthly time frame (unit be based on yearly) 12 months a year (to p7)

  15. The EOQ Model with Noninstantaneous Receipt The order quantity is received gradually over time and inventory is drawn on at the same time it is being replenished. Example: Let p = production, d = demand, then the total cost (TC) = (to p16) Figure 16.6 The EOQ model with noninstantaneous order receipt Always greater than 0 why?

  16. The EOQ Model with Noninstantaneous ReceiptModel Formulation Assuming placing an order/yr (to p17) Example

  17. The EOQ Model with Noninstantaneous ReceiptExample Let, ( to p7)

  18. The EOQ Model with Shortages Here, we allow Q being shortage, so that we could borrow or replenish the stocks later Max level of inventory • In the EOQ model wth shortages, the assumption that shortages cannot exist is relaxed. • Assumed that unmet demand can be backordered with all demand eventually satisfied. Shortage = S/Q Shortage What we needed Total cost is On hand = (Q-S)/Q t1 + t2 = S/Q + (Q-S)/Q = 1 (to p19)

  19. The EOQ Model with Shortages Area = ½ * (S/Q) * S = ½ * S2 /Q ½*base* height = ½ * (Q-S) * (Q-S)/Q = ½ * (Q-S)2 /Q Total cost = (to p20) • In the EOQ model wth shortages, the assumption that shortages cannot exist is relaxed. • Assumed that unmet demand can be backordered with all demand eventually satisfied. Shortage = S/Q Shortage What we needed On hand = (Q-S)/Q

  20. The EOQ Model with Shortages Example (to p21)

  21. The EOQ Model with ShortagesExample Let, (to p22)

  22. The EOQ Model with ShortagesAdditional Parameters in Example = Q/D (to p7)

  23. 2. Model with “discount rate” Price discounts are often offered if a predetermined number of units is ordered or when ordering materials in high volume. How do we decide if we should order more to take advantage of the discount being offered? (to p24)

  24. Quantity Discounts with Constant Carrying CostsAnalysis Approach • Solution method: • We first determine the optimal order size, Q* • We then compare with any lower total cost with a discount price • and accept the one has the minimum total cost Example (to p25)

  25. Quantity Discounts with Constant Carrying Costs Example(1 of 2) Consider the following example: The following discount schedule is offered, which size of order should we subscript? Falls in this section, Now we compare the TC of this, to The next discount class, 90+ (to p26)

  26. Quantity Discounts with Constant Carrying Costs Example(2 of 2) - Compute total cost at eligible discount price ($1,100): - Compare with total cost of with order size of 90 and price of $900: - Because $194,105 < $233,784, maximum discount price should be taken and 90 units ordered. (to p27) Do we always take the offer?

  27. No • It depends on the carrying cost • Example: • Carrying Costs as a Percentage of Price (to p28)

  28. Quantity Discounts with Carrying Costs as a Percentage of PriceExample (1 of 2) - Consider the same example, but with 15% of TC as carrying cost - Then, the carrying cost for each category is as follows: - Data: Co = $2,500, D = 200 computers per year Quantity Price (TC) Carrying Cost 0 - 49 $1,400 1,400(.15) = $210 50 - 89 1,100 1,100(.15) = 165 90 + 900 900(.15) = 135 (to p29) Chapter 16 - Inventory Management

  29. Quantity Discounts with Carrying Costs as a Percentage of PriceExample (2 of 2) - Compute optimum order size for purchase price without discount and Cc = $210: - Compute new order size: - Compute minimum total cost: - Compare with cost, discount price of $900, order quantity of 90: - Optimal order size computed as follows: - Since this order size is less than 90 units , it is not feasible,thus optimal order size is 77.8 units. (note: 69 falls onto 50-89 category) (less than 90 as needed) (to p5)

  30. Quantity Discount Model Solution with QM for Windows Exhibit 16.4

  31. 3. Model with “re-order points” • The reorder point is the inventory level at which a new order is placed. • Order must be made while there is enough stock in place to cover demand during lead time. • Formulation: R = dL, where d = demand rate per time period, L = lead time • Then R = dL = (10,000/311)(10) = 321.54 Working days/yr What would happen? (to p32)

  32. Reorder Point • Inventory level might be depleted at slower or faster rate during lead time. • When demand is uncertain, safety stock is added as a hedge against stockout. Two possible scenarios No Safety stocks! Safety stock! We should then ensure Safety stock is secured! How? (to p33)

  33. Determining Safety Stocks Using Service Levels • We apply the Z test to secure its safety level, Safety stock Reorder point Average sample demand How these values are represented in the diagram of normal distribution? (to p34)

  34. Reorder Point with Variable Demand Example (to p35)

  35. Reorder Point with Variable DemandExample Example: determine reorder point and safety stock for service level of 95%. (to p5)

  36. Determining the Reorder Point with Excel Exhibit 16.5