This research inherits the automatic grinding machine developed by the laboratory and constructs the surface roughness prediction models using grinding force measured by a six-axis force sensor, the label used in this research is Ra. The prediction model can directly get Ra of the workpieces, rather than measure it by humans, which is effective to determine the grinding quality. In the training data set collection section, firstly use the Taguchi method to optimize the grinding parameters of the grinding tool such as feed rate, grinding wheel speed, grinding force, and grinding angle, and also analyze their respective effects on surface roughness. Then, the data collection experiment was designed based on the results of the Taguchi method, and the brass plate was used for grinding. The experimental variables include three levels of grinding wheel speed and grinding force, and the specimens are used as training data for the surface roughness model after grinding and measuring the surface roughness. In the surface roughness prediction model training section, Linear regression, deep neural network (DNN), and convolutional neural network (CNN) model architectures were trained, and feature extraction of raw force information using raw features, statistical features, and FFT features are conducted, then apply min-max normalization and L1 normalization to the input data. By selecting the most suitable model by calculating the mean absolute percentage error (MAPE) of the predicted Ra values compared to the actual Ra values on the validation data, the DNN model using FFT features with L1 normalization achieves a MAPE value of 3.17% for the validation data, showing that the model can accurately predict the Ra value. In the section on testing the surface roughness prediction model, the application of the proposed surface roughness prediction model in actual grinding is tested by a surface roughness prediction experiment and regrinding experiment. The surface roughness prediction experiment was conducted by grinding brass plates and stainless steel plates respectively, and the experimental results showed that the MAPE of Ra prediction on brass plate test data could reach 6.96%, but the MAPE of Ra prediction on stainless steel plate test data was only 19.13%, since the prediction model used is based on the abrasive force information of the brass plate, so when predicting the Ra value of the stainless steel plate, the MAPE increases significantly due to the difference in material characteristics. On the other hand, after using the model to predict the surface roughness of the brass plates in the regrinding experiment, the areas with higher than expected Ra values were reground, and the results showed that the surface roughness prediction model was effective in predicting the areas with excessive Ra values, and the regrinding did reduce the Ra values.