CDAE 266 - Class 23 Nov. 15 Last class: Result of Problem set 3

1. CDAE 266 - Class 23 Nov. 15 Last class: Result of Problem set 3 4. Queuing analysis and applications Group project 3 5. Inventory decisions Quiz 5 (sections 4.1 – 4.4) Today: Result of Quiz 5 5. Inventory decisions Quiz 6 (take-home) Next class: 5. Inventory decisions

2. CDAE 266 - Class 23 Nov. 15 Important dates: Problem set 4: due today Group project 3: due today Final exam, 8:00-11:00am, Monday, Dec. 10

3. N = 54 Range = 4 -- 10 Average = 8.1 Result of Quiz 5

4. 5. Inventory analysis and applications 5.1. Basic concepts 5.2. Inventory cost components 5.3. Economic order quantity (EOQ) model 5.4. Inventory policy with backordering 5.5. Inventory policy and service level 5.6. Production and inventory model

5. 5.1. Basic concepts -- Inventories: -- Inventory policy (decision problems): Q = Inventory order quantity? R = Inventory reorder point (R = level of inventory when you make the order)? -- Optimal inventory policy: Determine the order quantity (Q) and reorder point (R) that minimize the inventory cost. -- SKU: Stock-keeping units

6. 5.1. Basic concepts -- Lead time (L): the time between placing an order and receiving delivery -- Inventories models: (1) Economic order quantity (EOQ) model (2) Backordering model (3) Production and inventory model

7. 5.2. Inventory cost components: -- Inventory ordering and item costs -- Ordering costs (telephone, checking the order, labor, transportation, etc.) -- Item cost (price x quantity) -- Inventory holding costs (interest, insurance, storage, etc.) -- Inventory shortage costs (customer goodwill and satisfaction costs)

8. 5.3. The economic order quantity (EOQ) model 5.3.1. Assumptions: -- One item with constant demand (A) -- Lead time = 0 -- No backordering -- All the cost parameters are known

9. 5.3. The economic order quantity (EOQ) model 5.3.2. A graphical presentation 5.3.3. Mathematical model -- Variable definitions: k = fixed cost per order A = annual demand (units per yr.) c = price h = annual holding cost per $ value T = time between two orders

10. A graphical presentation of the EOQ model: The constant environment described by the EOQ assumptions leads to the following observation THE OPTIMAL EOQ POLICY ORDERS THE SAME AMOUNT EACH TIME. Q Q Q This observation results in the inventory profile below:

11. 5.3. The economic order quantity (EOQ) model 5.3.3. Mathematical model -- Objective: choose order quantity (Q) to minimize the total annual inventory cost What is the reorder point (R)?

12. 5.3. The economic order quantity (EOQ) model 5.3.3. Mathematical model -- Total annual inventory cost = annual ordering costs + annual holding cost + annual item costs (a) Annual order costs Annual demand = A Quantity of each order = Q Number of orders per yr. = A/Q Fixed cost per order = k Annual ordering costs = k (A/Q)

13. 5.3. The economic order quantity (EOQ) model 5.3.3. Mathematical model -- Total annual inventory cost = annual ordering costs + annual holding cost + annual item costs (b) Annual holding costs Average inventory = Q/2 Annual holding cost per unit = hc Annual holding cost = (Q/2)*hc

14. Holding Costs (Carrying costs) Cost of capital Storage space cost Costs of utilities Labor Insurance Security Theft and breakage Annual unit holding cost h = Annual holding cost rate (cost per dollar value) c = Unit value (price) h * c

15. 5.3. The economic order quantity (EOQ) model 5.3.3. Mathematical model -- Total annual inventory cost = annual ordering costs + annual holding cost + annual item costs (c) Annual item cost Average demand = A Cost per unit (price) = c Annual item cost = Ac

16. 5.3. The economic order quantity (EOQ) model 5.3.3. Mathematical model -- Total annual inventory cost = annual order costs + annual holding cost + annual item costs -- Total annual relevant (variable) cost: -- Examples

17. 5.3. The economic order quantity (EOQ) model 5.3.3. Mathematical model -- Derive the optimal solution: (1) A graphical analysis: the sum of the two costs is at the minimum level when the annual holding cost is equal to the annual ordering cost: => => =>

18. 5.3. The economic order quantity (EOQ) model 5.3.3. Mathematical model -- Derive the optimal solution: (2) A mathematical analysis: At the minimum point of the curve, the slope (derivative) is equal to zero: => =>

19. 5.3. The economic order quantity (EOQ) model 5.3.4. Examples (1) Liquor store (pp. 209-211) Available information: A = 5200 cases/yr k = $10/order c = $2 per case h = $0.20 per $ per yr. (a) Current policy: Q = 100 cases/order R = (5200/365) * 1 = 15 cases T = Q/A = 100/5200 (year) = 7 days TC = $540 per year (see page 210) (b) Optimal policy: Q* = 510 cases/order R = (5200/365) * 1 = 15 cases T = Q*/A = 510/5200 (year) =36 days TC = $204 per year If the retail price is $3 per case, Gross profit = 5200*3 – 5200*2 – 204 = $4996

20. Take-home class exercise • 1. Draw a graph to show the following inventory policy for • a business with no backordering: the annual demand is • 3650 units and the business opens 365 days a year, the • order quantity is 305 units and the lead time is 4 days. • If some customers of the above business are willing to • take backorders and the maximum backorders are 50 units, draw another graph to show the inventory policy (there is no change in order quantity and lead time) • 3. Take-home exercise: Example on pp. 215-216 with the annual demand (A) increased to 1200 units and the lead time to be 3 days.