Dynamic Lot Sizing The dynamic lot-size model in inventory theory, is a generalisation of the Economic Order Quantity (EOQ) model that takes into account that demand for a product varies over time. Dynamic lot sizing sometimes refers to as 'Time-Varying Demand' as well. In contrast to EOQ model where demand is constant, in the time-varying deterministic demand model, demands of various periods are unlike. The variations depend on different reasons. For example, production on a contract, which requires that certain quantities are delivered on specified dates. Note that we are still considering deterministic demand, i.e, all variations are known in advance. In the basic models, lead-time is disregarded. When dealing with lot sizing for time-varying demand, it is generally assumed that there are a finite number of discrete time steps, or periods. A period may be, for example, a day or a week. We know the demand in each period, and for simplicity, it is assumed that the period demand takes place at. the beginning of the period. There is no initial stock. When delivering a batch, the whole batch is delivered at the same time. The holding cost and the ordering cost are constant over time. No backorders are allowed. We shall use the following notation: Problem Costco has received the following demands for a product this year: Suppose ordering cost (OC) is $504 and holding cost (HC) of one unit of product in a year is 83 . There is no shortage cost. Backordering is not allowed in this model. Q1 (2 marks) Given that the total demand of the whole year is 10,000 products, suppose the company is going to tse the EOQ model for the accumulated demand of one year (10,000). In other words, ignore the monthly demand. Compute: 1 - Optimal order quantity (Q) - Total cost - Frequency of orders - Time between orders Q2 (5 marks) Use mixed integer linear programming to solve the problem regarding the monthly demand. Suppose that holding cost is applied to the ending inventory. - Develop the mathematical model in the Word document. - Solve the problem in Excel - Develop a plan in the Word document and explain when and how many products should be ordered in order to minimise the total cost. - Recalculate the optimal value of objective function (total cost with the new assumption that the holding cost is applied to the average inventory (not ending inventory)