Bearings are the most frequently used component in a rotary machine. Bearing failure could lead to unpredictable productivity loss for production facilities. Therefore, the fault diagnosis of bearing has attracted significant attention from the research and engineering community over the past decades. In this dissertation, a bearing fault diagnosis algorithm was proposed to identify the types of bearing fault. This proposed algorithm is decomposed into three key phases. Firstly, the defect-related features were extracted from the vibrational signal by using several entropy-based algorithms. Secondly, the optimal feature set is obtained by the feature-selection algorithm. Finally, a classifier model is trained by using the optimal feature set and the one-against-one support vector machine. The main contributions of this dissertation can be summarized as follows: 1. We introduce several entropy-based algorithms including, multiscale entropy (MSE), multiscale permutation entropy (MPE) and multiband spectral entropy (MBSE) to extract defect-related feature hidden in the measured signal. Furthermore, a composite algorithm for MSE and MPE, named composite MSE (CMSE) and composite MPE (CMPE) were proposed to improve the performance of the feature extraction. 2. We introduce two feature selection algorithms including, Fisher score and Mahalanobis distance to select the sensitive features from the original feature set. An optimal feature set can be obtained by using the propose feature selection algorithm. Experiments show classifier model trained by optimal feature set is the most effective for the fault diagnosis of bearings. In the simulations presented in this dissertation, the vibration signal datasets of bearing from Case Western Reserve University (CWRU) are utilized. Nineteen experiments are designed to evaluate the capability of the proposed fault diagnosis system. Experimental results demonstrate that the proposed system provides a significantly higher accuracy of prediction for the classification of bearing faults.