This research presents a series of 1g model tests and finite element (FE) analyses to investigate the performance of geosynthetic-reinforced soil (GRS) and geosynthetic encased granular columns (GEC) reinforced foundations subjected to fault movement. The aim is to evaluate the performance of GRS and GEC reinforced foundations as a mitigation measure for surface faulting hazards. This research first conducts a series of 1g model tests on GRS foundations across a normal fault. A 3-m thick foundation in prototype subjected to a normal fault vertical displacement up to 90 cm was modeled in the 1g model tests. Digital image analysis (DIA) techniques were applied to determine the surface settlement profile, angular distortion, shear rupture propagation, and mobilized reinforcement tensile strain at various magnitudes of fault offset. Finite element (FE) analyses were developed to investigate the reinforcing mechanism of GRS foundations subjected to normal fault movement. Experimental and numerical results of unreinforced and GRS foundations were compared for model validation. Parametric studies were conducted to evaluate the influence of soil and reinforcement parameters on the performance of GRS foundations. Design method was also developed for determining the reinforcement length against significant pullout. Secondly, a series of 1g model tests on GEC reinforced foundations across a reverse fault were conducted in this research. The performance of GEC reinforced foundations under reverse faulting and the reinforcing mechanism of the geotextile encasement were investigated. The DIA techniques were also adopted in the GEC reinforced foundation tests to determine the surface displacement profile, angular distortion, and shear rupture propagation at various reverse fault offsets. The influence of horizontal spacing of GECs on the effectiveness and reinforcing mechanism of GEC reinforced foundations was discussed. Three-dimensional FE analyses were also carried out to explore the deformation behavior of the GECs embedded in the GEC reinforced foundation and the mobilized reinforcement tensile strain developed in the geotextile encasement. For the GRS foundation subjected to normal fault movement, a smooth surface settlement profile was observed. The reinforcement inclusions effectively prevented the shear rupture propagating to the ground surface and also spread the differential settlement to a wider influential zone, resulting in an average reduction of 60% in the fault-induced angular distortion at the ground surface as compared to the unreinforced foundation. Two main reinforcing mechanisms, the tensioned membrane and shear rupture interception effects, were identified. The numerical results of the parametric study showed that reinforcement pullout in the top reinforcement layer could occur in the case of the short reinforcement. Due to the impact of reinforcement pullout, the shear rupture propagated upward and passed through one end of the reinforcements, resulting in the development of a secondary settlement at the ground surface. The numerical results of the parametric study also showed that reinforcement breakage could occur in the cases of the reinforcement with a low ultimate tensile strength. The foundation height and reinforcement stiffness had considerable influence on βmaxandmax. To ensure adequate reinforcement anchorage against significant pullout, the reinforcement length should be longer than the fault influence length at the free field ground surface. For the GEC reinforced foundations subjected to reverse fault movement, the maximum angular distortion at the ground surface was effectively mitigated. A reduction of 15-23.3% in the max values was observed at S/H = 30% as compared to the unreinforced foundation. Two reinforcing mechanisms, the shear rupture diffusion and diversion effects, were identified. Complex reinforcing mechanisms between diversion and diffusion of the shear rupture were observed in the GEC foundations with different horizontal spacing. The GEC reinforced foundation with Sh /dc = 3.3 shows the most significant effect in reducing max values. The results of FE analysis show that the predicted displacement at the surface of the hanging wall for the unreinforced foundation was overestimated. The predicted βmax values were also slightly underestimated because of the less localized surface displacement occurring at the outcrop. The predicted and measured βmax values for the GEC reinforced foundations are in good agreement, except that the βmax at S/H = 15% was slightly underestimated in FE analyses. The GEC group in the hanging wall remained vertical and undisturbed as reverse fault displaced, while considerable tilting deformation was observed in the GEC group in the footwall. The locations of the maximum tensile strain for each GEC were approximately on the propagation path of the shear rupture. Reinforcement breakage may occur in the geotextile encasement of the GEC closest to the fault tip due to the high lateral earth pressure acting on the geotextile encasement, which leads to strong soil–reinforcement interaction and higher εmax values.