This paper documents the numerical study of the motion of a spar type and a semi-submersible type floating wind turbine under the coupling of aerodynamic and hydrodynamic loads (under coupled aerodynamic and hydrodynamic loads), We use a computational fluid dynamics package and solve the flow field using a Reynolds-averaged Navier-Stokes equations (RANS) solver with a proper turbulent model and also use java code to compute the mooring line force. The NREL 5MW turbine was chosen as our target wind turbine. For the onshore simulation case, the result was (results were) verified with NREL simulation results, with errors less than 8%, For the offshore simulation case, the wind turbine is undergoing pitch motion or surge, heave and pitch motion simultaneously in regular head waves of wave height 4 m, wave period 10 s and uniform wind speed 11.4 m/s. The simulation results show that the rotor power changes dramatically because of the wind turbine's pitch motion. If we consider the real wind turbine control system situation, the average power will be reduced.In the case of the spar type floating wind turbine undergoing surge, heave and pitch motion simultaneously, the results show that the spar type floating wind turbine has a pitch angle range from -3.59 to -6.03 degrees, the rotor power change is between +32% and -36%, and the average power is reduced by 1.39%. If we consider the real wind turbine control system situation, the average power is reduced by 9.17%. In the case of a semi-submersible type floating wind turbine undergoing surge, heave and pitch motion simultaneously, the results show that the spar type floating wind turbine has a pitch angle range from -3.50 to -5.04 degrees, the rotor power change is between +6% and -10%, and the average power is reduced by 0.99%, If we consider the real wind turbine control system situation, the average power is reduced by 2.61%. According to this research, we recommend the semi-submersible floating platform in order to reduce the floating wind turbine's power loss.