The Mw=6.8 Chengkung Earthquake is almost a pure thrust event which is occurred on December 10th, 2003 in the Costal Range of eastern Taiwan. This earthquake is believed to rupture the NNE-striking Chihshang Fault in the Longitudinal Valley. Based on the relocation of aftershock sequences, the main shock mainly dislocates the east dipping high-angle Chihshang Fault plane. The maximum permanent vertical displacement shown by GPS data in the hanging wall side is about 30 cm. Remarkably, not only all the stations on the hanging wall of the Chihshang Fault were uplifted in this earthquake event, but also the stations on the Longitudinal Valley were still raised till the foothills of the Central Range. We employ GPS data around the Chihshang Fault by using the elastic half-space dislocation model to figure out the fault plane geometry and the distribution of co-seismic dislocations. I construct the Chihshang Fault, consisting of 6 segments, by the delineation of the aftershock distribution. The segments all strike N˚18E, because of the fault trace on the surface, and the segments of Chihshang fault, from top to bottom, are 60˚, 65˚, 60˚, 40˚, 20˚, 10˚, respectively, revealing a listric fault type. The dislocation model in term of GPS data reveals that the maximal dislocation is about 1 m along dip-slip and the dislocations gradually decrease to 10 cm near the surface. The average slip is 0.52 m along the fault surface, which yields a scalar moment of 2.0 × 1026 dyne-cm. These results are similar to that of the Harvard CMT, indicating a scalar moment of 2.0 × 1026 dyne-cm. The result shows the uplift of the foot wall highly affects the root mean square of vertical component. From the post-seismic displacements recorded by GPS 3 months after the main shock, the hanging wall of Chihshang fault still uplifted during this period. Contrast to the hanging wall, the footwall moved downward. Under the assumption that the postseismic deformation was due to the afterslip on the same fault, the dislocation model is also applied to investigate the postseismic afterslip distribution. The result shows the maximum afterslip is up to 15 cm and most slip are distributed to upper part of the fault. This phenomenon probably implies that coseismic dislocation near the fault trace may be partially locked or damped, thus the strain cumulated and caused the uplift of the footwall. After the mainshock, the strain released near the surface causes aseismic creeping and significant post-slip. To inspect the stress field after the Chengkeng earthquake, Coulomb failure criterion is employed to investigate the occurrence of aftershocks and future rupturing, based on the coseismic dislocation and fault geometry. Coulomb stress change, on specified orientation and optimally orientated faults, both reveal that the footwall should experience a significant stress increase up to 2 bars, a candidate for the occurrence of aftershocks. The comparison between the Coulomb stress change pattern and aftershock distribution shows there should be a pre-existing geological structure beneath the Longitudinal Valley and was triggered after the Chengkung earthquake.