This study intends to discuss the load and deformational behaviors of pile-raft foundations using the three-dimensional finite element analyses based on Midas-GTS program. A simple pile-raft foundation with a 27m×23m×1.5m (L×B×H) raft underlain by a number of piles is considered. The influences of the pile-to-pile distance (S) and the pile length (l) are monitored. Homogeneous soil layer consisting of either sands or clays is assumed on top of the rigid rock. Friction piles and end bearing piles can be thus studied. With the Mohr Coulomb model for sand and the Modified Cam Clay model for clay, rational model behaviors can be found. In general for the vertical loadings, it is found that the largest displacements on the order of 2~6 cm will occur at the center of the foundation, while the foundation edge will exert smallest displacements. In contrast, the loads transmitted to the corner piles are found larger than the side piles and much larger than the center pile(s). Vertical loads carried by the numerical piles are found approximately 60%~80% of the total load varying the ratios of S/D and l/B (where D is the pile diameter) whereas horizontal loads were found carried more by the piles. Frictions distributed at the upper parts of the piles will be much larger at the friction piles rather than those of the end bearing piles. Moments applied to the pile-raft foundation will cause tensile forces to some piles. The value of initial modulus of the soil is very sensitive to the results. In this study, the soft clayey site was assumed fully consolidated and a homogeneous ground was considered for foundation settlement due instantaneous load. For foundation behaviours including the consolidation effects along with the time, more rigorous simulations needs to be taken. Furthermore, the interface element (contact element) between soil and pile should be used for better solutions.