Pulmonary hypertension (PH) is a serious lung disease nowadays. Because the pulmonary artery (PA) structure is changed, resulting in the increase of PA blood pressure. Patients suffering from PH are difficult in breathing and fell chest pain. In clinic, several examinations, such as echocardiograph and computed tomography (CT) are used to examine the PH patient, and right heart catheterization is used to measure the PA blood pressure for PH diagnosis. Although these examinations are standard medical procedures, patients would not be diagnosed easily without obvious symptoms. In this study, we analyzed the PA pressure distribution on a three-dimensional (3-D) PA model built from a CT scan by using a computational fluid dynamics (CFD) software. The aim of this study is to offer a PH prediction model based on the pressure-based features extracted from the PA pressure distribution by the CFD simulation, and to increase the PH prediction accuracy. First, a semi-automatic segmentation was presented to obtain a 3-D PA model from a CT scan. After setting inlet and outlet planes on the 3-D PA model, the CFD simulation was performed to simulate the blood pressure distribution. Then, the pressure-based and volume-based features were used to extract the characteristics of the simulated PA pressure distribution and the PA structure, respectively. The experimental results showed that the PH prediction accuracy can be improved by using the pressure-based features. Originally, the PH prediction accuracy was 77.78% by using the combination of two volume-based pressures. Then, the accuracy was increase to 83.33% by using the combination of four pressure-based features and two volume-based features. Finally, the feature selection was used to select an optimal feature combination to obtain the highest accuracy of 88.89%.