Over the next 20 years, the aerospace industry will bring many opportunities to the world’s economic development, particularly in Asia. Taiwan's geographical advantage, manufacturing capacity and special government policy will bring a new competitive edge to Taiwan's aerospace industry. However, aerospace manufacturing parts are large in size, with very tight production tolerances and low rigidity which will cause high barriers for local engineering firms to meet the challenge. An answer to this problem is found in the Assembly Jig design which has a direct impact on the production quality. The aim of this study is to perform Finite Element Analysis of the Assembly Jig to investigate the Jig stiffness requirement, and also build a scale model test to verify the relationship between analysis and real-world outcomes. This‘Pre-analysis Method with Simplified Model’ is seen to significantly reduce the time needed to resume analysis each time a design change occurs. Finally recommendations to the assembly sequence is proposed, which can provide for a better production quality control. From the simulation, the max displacement of Jig in the worst case is within the Tolerance Matrix requirement, which means the jig can meet the MDCD assembly requirement. The comparison between analysis and real-test based on scaled model gives -.0013” error, which is 25.8%. Although it’s over the 10% error standard from Federal Aviation Regulation, the overall results are found justifiable through the error analysis, which means the analysis method is considered reasonable and reliable. The assembly sequence which can uniformly distribute the deformation will achieve a better assembly quality. The assembly sequence from the middle to both end sides is found to be the optimized mode.