The cell assembly factory assembles the color filter with the glass substrate produced from array factory, and filling with liquid crystal for making thin film transistor liquid crystal display (TFT-LCD). In the process selectable environment, each custom order can specify its required process such that orders can be classified as hot press (HPS) specified, one drop fill (ODF) specified, and unspecified. Factories that producing middle and small size products, thus take make-to-order (MTO) mixed with make-to-forecast (MTF) policy and try to keep some unused capacity to response the new arrived customer orders. As a result, this thesis proposes a master production scheduling system to plan a schedule with the most unused capacity, and develops the available-to-promise mechanism to response the new arrived customer orders in short time. The proposed master production scheduling system solves the schedule for all major workstations. At first, rough cut capacity planning mechanism is used to identify three major workstations and then distinguishes the bottleneck and sub-bottleneck among them. Then major workstation planning mechanism is used to determine the production quantity of HPS process and of ODF process. An integer programming model is built to solve the schedule for the three major workstations simultaneously with minimization of the bottleneck’s setup time as the objective function. The proposed available-to-promise mechanism is applied when the new orders arrives. It adopts the order promise module to check whether the quantity available to promise and the capacity to promise can fulfill the new arrived orders or not. If the new order can not be fulfilled, rescheduling module freezes the schedule of the firm orders and reschedule the make to forecast orders and new arrived orders, with consideration of minimizing the difference of the bottleneck’s average utilization rate before and after rescheduling. According to the result of cases analysis, the proposed master production scheduling system can solve the schedule of the three major workstations and minimize setup times for the bottleneck with efficiency. The proposed available-to-promise mechanism can make the new arrived orders fulfilled with the time faster than rerunning the proposed master production scheduling system. Key words：TFT-LCD, major workstations, production quantity, inter-period setup, actual order