Piles serve as a common foundation for offshore structures, enduring inertial forces, hydrodynamic pressure, and ground movement during seismic events. This study employs theoretical and numerical analyses to investigate the response of piles under hydrodynamic pressures and simplifies the dynamic analysis model considering both hydrodynamic pressures and ground movement effects. Furthermore, the study examines the applicability of a pseudo-static method for analyzing pile response under ground movement and proposes an improved method. First, this study modified theoretical solutions to examine seismic responses of underwater piles, validated by numerical analysis under both rigid and flexible base conditions. Parametric studies reveal that hydrodynamic pressure decreases resonance frequency and increases pile-head displacement, with reduced impact as soil stiffness increases. The magnitude of seismic response is influenced by hydrodynamic pressure. This study also verified the added mass method for underwater piles, in which additional mass is applied to simulate hydrodynamic pressure. Both precise and simplified added mass distributions yielded good seismic response prediction in numerical analyses. Application of the simplified distribution to complete underwater piles indicated that ground movement diminishes the water’s influence on pile responses. Lastly, this study improved the pseudostatic method for assessing ground movement effects on pile responses by evaluating numerous characteristic ground displacement profiles under various conditions. Since no single method suits all conditions, this study developed a multi-characteristic profile method. This improved method forecasts dynamic responses in various soil conditions more accurately than previous methods. Keywords: Pile foundations, earthquake excitation, hydrodynamic force, ground movement, pseudostatic analysis.