Typhoons are generated on the vast tropical ocean. When they pass through the ocean, the sea surface temperature (SST) might decrease significantly due to their passages. In addition, previous literatures point out that the SST drop usually occurs at the right side of the typhoon trajectory. However, in this study, through the continuous measurement of SST by Longdong weather buoy in the past 20 years (1998-2017), we found that the far field typhoons passing through the Luzon Strait repeatedly caused SST drop more than 6℃surrounding the Longdong sea area. To clarify the possible mechanism(s), this study uses the Regional Ocean Modeling System (ROMS) to simulate the oceanic environment corresponding to 6 far field typhoon cases with similar tracks occurred from 2001 to 2016. They are typhoons Utor ( 2001 ), Dujuan ( 2003 ), Sanvu ( 2005 ), Nanmadol ( 2011 ), Usagi ( 2013 ), and Meranti ( 2016 ). The simulations are validated by the sea levels data from in-situ tidal gauges of Longdong tide station and continuous temperature measured by moored buoy, and the processes of the upper ocean cooling response caused by far field typhoons in Longdong sea area are systematically analyzed. The results show that the strong cooling caused by the far field typhoon in Longdong is mainly through the mechanism of the Kuroshio intrusion. In addition, the local wind surroudning Northeast of Taiwan is the key factor determining the occurrence of Kuroshio intrusion or not. Moreover, in the experiments without tidal effect, the average temperature difference is 6.8℃, which is much weaker relative to in-situ measurements. After including tidal effect, the temperature drops in the nearshore resion tend to be strong. Compared with the in-situ data, the average temperature difference significantly reduces to 1℃. In general, after the tidal effect is included, the simulations of temperature drops in the nearshore region caused by typhoon have been systematically improved. Finally, through systematic analysis, it’s shown that, the addition of tidal effect enhances the cooling process through mainly the underlying mechanism. (1) Tidal mixing can de-stratify the water column and provide a favorable environment for cold water to rise. Consequentially, upper ocean mixing and stronger upwelling allow enhanced SST drop. (2) The interaction between tidal currents and bottom topography results in enhanced bottom kinetic energy and bottom stress. (3) The southward tidal residual current in the subsurface of Longdong caused a downward bottom Ekman flow. Then, due to the bottom topography, an upward flow was generated about 20 kilometers offshore, forming a counterclockwise circulation. This process leads to tidal residual temperature getting cold at the top and warm at the bottom. Finally, it is suggested that, for simulating the response of upper ocean cooling to typhoon passages at nearshore regions, including tidal effect can provide a more comprehensive understanding about the process of occurrence of SST cooling to typhoon passage.