This study uses SAP2000 to simulate the dynamic responses of different structure-pile-soil models under centrifuge shaking table testing, considering both the inertia effect from the structure mass and kinematic effect of ground on the pile. The centrifuge models consisted of piles embedded in dry sand under 80g centrifuge acceleration. The thickness of sand in the prototype was 25.2 m with relative density of 80% and 50%. A mass block was placed on the top of the pile to simulate the mass of the structure. Different extended lengths of the pile above the ground were adopted to represent different dynamic characteristics of the structural system. In the numerical model, a mass-pile-soil model connected to a shear beam model is established to consider both inertia and kinematic effects at the same time. The shear beam model adopts a series of vertically distributed horizontal springs, which adopts a hyperbolic shear force-displacement curve and the Masing rule for the hysteretic response, to simulate the seismic ground responses. For the pile-soil interaction behavior in the mass-pile-soil model, beam elements are used to model the pile, while the spring elements are used to model the soil reactions. The soil springs are defined by hyperbolic p-y curves and their hysteretic response is modeled by the Masing rule. A series of verification analyses show that the numerical ground, pile and structure responses from the proposed combined model are in good agreement with the centrifuge test results.