In this study we consider the component ordering quantities and production decision problems for a single-period assemble-to-order (ATO) production system with two end products, called high profit product and low profit product. Each product is used for fulfill a particular customer. The ordering quantity of each customer’s order is uncertain following a given distribution. These two products are assembled by two components respectively, C0 and C1 for high profit product, and C2 and C3 for low profit product. However C3 can be replaced by C0 for assembling low profit product. We called C0 as common component and C3 as special component. The unit cost of C0 is higher than C3. If the customer order of the low profit product confirms before the other one, the manufacturer needs to commitment immediately how many products to be delivered. In this case if the inventory of the special component is insufficient to fill the demand, then the manufacturer faces the decision problem: how many of the common component should be distributed to fill the unsatisfied demand. Under the above ATO environment we formulate a mathematical model for maximizing the expected profit to determine the optimal inventory levels of components and to decide how many of the common component should be distributed to fill the unsatisfied demand of low profit product. Numerical Examples are given to illustrate the model, solution procedure and to find some management insights.