With growing environmental awareness, many countries have announced their commitment to achieving net-zero carbon emissions by 2050. As the demand of energy has also increased with time, this leads to the significant development in renewable energy sources worldwide, with Taiwan being no exception. Since the Taiwan Strait has many excellent wind farms that are among the best in the world, offshore wind industry has more advantages in development among other renewable energy sources. Therefore, the development of offshore wind farms is imperative. However, Taiwan’s geographical location along the western Pacific coast poses many typhoon challenges for offshore wind farms. Extreme wind and extreme wave conditions generated by typhoons significantly increase the load on offshore wind turbines, posing a substantial threat to the offshore wind energy industry. A highly reliable simulation process for typhoon-induced wind and wave conditions was established in the study. The widely used Weather Research and Forecasting (WRF) model was employed to simulate typhoon wind fields and the results were imported into the third-generation nearshore wave model, Simulating WAves Nearshore (SWAN). In this way, the wave induced by conducted typhoon wind could be well simulated in the coast areas near Taiwan. With the combination of two simulation models, the wave conditions were more accurate. Typhoon Nesat (2017) was selected as a historical case in this study. Using the WRF model, typhoon wind fields was simulated with three different initial time. These wind fields were then imported into SWAN model separately, and the bathymetric data was also taken into consideration to calculate wave conditions under three different extreme wind scenarios near Taiwan. Some characteristic wave parameters were analyzed, including significant wave height, mean wave period, and mean wave direction. Additionally, the simulation results were also compared with the measurements from selected buoys and the observation tower in Zhunan in order to validate the accuracy of the simulations, especially for the simulated wave changes in Formosa 1 offshore wind farm. In summary, the simulation process successfully captured the variations in wave conditions under extreme wind events. The simulated wind and wave characteristics closely aligned with actual observations. Notably, at the Zhunan observation tower location, the simulated significant wave height was overestimated by approximately 0.5 meters, while the period is overestimated by around 1 second. Overall, the simulation trends correlated well with the observed data, with a maximum correlation coefficient of 0.88 and a lowest root mean square error (RMSE) of 0.53. In the future, we can apply the resulting wave fields as environmental parameters for offshore wind turbine load analysis, enhancing the reliability of engineering assessments and mitigating potential risks in practical projects.