Brain computer interface (BCI) is a highly active field in the recent years. However, electroencephalogram (EEG) is a non-linear and non-stationary signal which contains various noises. Hence, the research groups in the world put effort into “feature extraction” and “classification” of EEG signal. In this study, an analysis strategy of single-trial EEG is developed for BCI and focus on “feature extraction”. The proposed method is to combine Independent Component Analysis (ICA) and Hilbert-Huang Transform (HHT) to analyze EEG. The EEG signal processing is performed in two stages: (1) ICA, a kind of Blind Source Separation (BSS), is used for dividing temporal-spatial components of EEG recordings; (2) HHT, a kind of temporal-frequency analysis (TFA), is used for processing these components. The empirical mode decomposition (EMD) in part of HHT is used for signal reconstruction and noise rejection. When the EEG is processed by above mentioned methods, the time-frequency-spatial features will be preserved. In additional, three kinds of TFAs (HHT, short time Fourier transform (STFT), and Morlet Transform) are experimented to compare the performance. The results show that the HHT has the better resolution in high frequency and low frequency. The last stage of the research, Support vector machine (SVM) is selected to classify EEG data of four motor imageries (left hand, right hand, foot, and tongue). The experiment result presents that the classification accuracy of imaging “right hand” moving is 83.33%, and total averaged accuracy is 54.17%. In additional, the method combined with both EMD and FastICA has 72.12% averaged accuracy of signal source localization of motor imagery.