Taiwan has been promoting renewable energy vigorously in recent years, of which offshore wind energy is one of the most important energy resources. The Taiwan Strait is an outstanding wind field, so it attracts wind energy operators both from domestic and abroad to invest, construct and operate wind farms. Under the government's policy of the offshore wind energy, three domestic offshore wind power corporations were appointed and each of them constructed one offshore meteorological masts. They are separately in the offshore areas of Miaoli and Changhua in 2015, serving weather condition monitoring purposes. Wind field and energy forecast is extremely essential for wind energy industry and power dispatching in public sectors. The real-time data of the wind mast may be incorporated to improve the forecast accuracy for the wind farms in the vicinity area. In this study, we demonstrate that such system can be achieved by combining numerical weather forecast model data (WRF model, the Weather research and forecast model), the offshore wind mast observation data, and machine learning facilities. The project is incorporation with Taiwan Generations Corporation so that the wind mast data are taken from the wind mast of the company. The mast was built in the Fuhai wind farm in September 2015. The LSTM (Long short-term memory recurrent neural networks) machine learning model is applied to train an Artificial Intelligence (AI) model from the WRF forecast to the observation. The AI model is then used to provide accurate wind forecast. The forecast accuracy is assessed by using the Pearson correlation coefficient and RMSE (the root-mean-square error). They are applied to evaluate the forecasts of both WRF and machine learning model. The forecasts are three-day forecasts. The assessments show that the forecast accuracy can be greatly improved in the northeast monsoon period (October to April). It is expected that excellent wind energy prediction can be achieved in the winter monsoon periods. The machine learning model in future can be further extended to provide accurate wind energy production forecasts prediction for the offshore wind energy industry.