This study aims at developing a structural damage detection technology for high-tech manufacturing factory. A typical triple fab is considered as the object to explore the feasibility of this technology for practical application. In this dissertation, a scheme integrated with deterministic–stochastic subspace system identification and the method of damage localization vector (DLV) is proposed for damage detection of structures based on seismic response data. Damage conditions simulated by removing columns of about 0.5% or 1% of the whole damaged story have been considered. System identification analysis shows that both modal frequencies and damping ratios of the fab can be accurately identified, regardless of full- or reduced-order observation condition. The identified system parameters in turn serve as the basis for damage detection of the structure. The reduced-order system, however, gives better damage identification results. The structural monitoring system acquiring dynamic responses at the corners is found to be more reliable for damage localization. In addition, as the fab is 3-D in nature and the structure is under bi-directional earthquake inputs, the stress index developed earlier for shear-type plane buildings is no longer applicable. Instead, this study proposes various combinations of stress indices for auxiliary judgment on damage localization. The results indicate that a probability of success of about 40% can be achieved to accurately identify the damaged storey without any misjudgment. The percentage of success can be further increased to be over 50% if the damaged storey is identified with or without misjudging one other storey that is in fact not damaged. This suggests the potential of the proposed damage localization scheme for practical use in high-tech manufacturing factories. The current scheme, however, is able to locate the damaged storey but fail to locate the exact positions of the damaged structural members. A more advanced technique deserves further development next.