The variation of the anticline movements of the thrust sheets illustrates a distinctive deformation pattern in SW Taiwan. Thus I use the PSInSAR (Persistent Scatterer Interferometric Synthetic Aperture Radar) technique with constrains of precise leveling and GPS measurements to derive the line of sight (LOS) velocities in the study area and characterize the deformation patterns. I noticed that the maximum LOS velocities of ~ 20 - 30 mm/yr is recorded on the footwall of Lungchuan and Chishan Faults, which are considered as reverse faults in Gutingkeng Mudstone. The anomalous high deformation rate might be related to a ramp duplex located in the footwall of Lungchuan Fault. Or this deformation is related to the mechanical heterogeneity between mudstone and sandstone together with the mud-core anticline. I then use DynearthSol2D, an efficient unstructured finite element code, to simulate the deformation mechanism. In addition, we proposed that the high pressure zone in Gutingkeng Mudstone provides a weak zone which can easily be triggered by earthquake and produce coseismic slip. I attempted several hypotheses controlling high deformation rate to find the dominant deformation mechanism. I concluded that the main deformation mechanisms are the duplex structure underneath the Lungchuan Fault and the west-dipping fault with high fluid pressure in the west of the Lungchuan Fault. Besided, the co-seismic deformation from the 2016 Mw 6.4 Meinong earthquake shows the high correlation with the shollow structure, I would like to use the numerical modeling to address the mechanism how moderate earthquake could trigger the shallow structure by co-seismic displacement.