Atrial Fibrillation (AF) is the most common and sustained type of cardiac arrhythmia. Since AF is a risk factor for stroke, automatic detection of AF is an important public health issue. Currently, the most useful and accurate tool for diagnosing AF is electrocardiography (EKG). However, EKG monitoring devices have their limitations or drawbacks. On the other hand, photoplethysmogram (PPG) is an alternative technique to obtain the heart rate information by pulse oximetry. Compared with EKG monitors, PPG devices are more convenient, making PPG promising in identifying paroxysmal AF. The aim of this thesis is to investigate the potential of analyzing PPG waveforms to identify patients with AF. The state-of-the-art PPG-based AF detection researches in this thesis have some limitations. In addition, there is still performance gap between related works and EKG-based algorithm. Therefore, we propose a PPG-based AF detection framework, including pre-processing, feature extraction, and SVM classification with GA-based optimization. The receiver operating characteristic curve (ROC) and statistical measures were applied to evaluate model performances. Furthermore, two clinical scenarios, long-term monitoring and fast screening were considered in the experiments. Among 673 patients’ signals recorded in clinic environments, we achieve ROC area under curve, sensitivity, specificity and accuracy of 0.980, 0.954, 0.979 and 0.973, respectively. And the record time can be shorten to 30 seconds with little performance degradation in fast screening scenario. The result suggests that the PPG-based AF detection algorithm is a promising pre-screening tool for AF and helps doctors monitoring patient with arrhythmia.