A thorough understanding of crustal structures is crucial for earthquake hazard assessments. One of the essential factors in seismic hazard analysis is shear wave velocity near the surface. When an earthquake occurs, the damage caused by the shear wave is usually more severe than that caused by P waves because of its large amplitude and the shear motions. Moreover, offshore wind energy is one of the main future energy because the government of Taiwan supports renewable energy or related industries. It is important to assess the offshore wind farms seismic forces reasonably in order to ensure the safety and stability of the offshore wind turbine support structures. There have been many methods developed to estimate S-wave velocity. A direct approach is to drill. However, drilling is expensive and not practical. A newly developed body-wave polarization method provides an inexpensive way to explore shallow crustal structures. The P-wave polarization direction has no sensitivity to P-wave velocity but only S-wave velocity. In contrast, the S-wave polarization direction is sensitive to both P-wave and S-wave velocities. Thus, we apply the P-wave polarization method to ocean-bottom seismometers (OBS), island stations on the Okinawa trough (OT), and F-net stations in Kyushu, Japan, to estimate the S-wave velocity of the shallow crust. The preliminary results demonstrate that the average S-wave velocity calculated by OBS is lower than those calculated by inland stations. The low S-wave speed may imply that OBS is mainly seated on soft rich-hydrous seafloor sediments. In addition, the results indicate that the average S-wave velocity from the surface to depth of 100 m below the stations. In the future, it can be discussed according to different filters to obtain different depth ranges to provide a more detailed reference for seismic hazard analysis and seabed stability assessment.