In recent years, information terminal devices have become more convenient and easily portable to meet customers’ needs. This desire and request gradually stimulates the development of flexible electronics. Electronic products made of inorganic materials in the past are replaced by organic materials in order to achieve the goal of being” flexible”, such as flexible display, solar cells, electronic paper and RFID tags. In the fabrication process of organic devices, solution based process were adopted in this study, which have advantages such as low cost and low process temperature. However, the performance of state of the art organic thin film transistors (OTFT) are usually poor compare with thin-film transistor made of inorganic materials. The performance improvement on OTFT is therefore an important research issue and will be investigated in this thesis. In this study, the system set up by our research team and the OTFT standard operation process (SOP) developed in house is adopted, which is already proven to be a stable all ink-jet printing process. To improve the performance of all organic thin-film transistors, we blended graphene into P3HT. At blending concentration 2 wt.%, the mobility was ten times higher than pristine P3HT, while keeping the On/Off Ratio larger than 105. We also observed the decrease of contact resistance and channel resistance in our experiment. Furthermore, we found the percolation limit of blended graphene in P3HT. To understand the charge behavior in P3HT and graphene, material analyses such as XRD, FTIR, UV-Vis and PL are conducted to observe the lattice state, molecular internal vibration, and charge behavior after blending graphene with P3HT, respectively. These analyses demonstrated that the performance of the transistors can be improved since charge transfer between P3HT and graphene indeed exists and graphene sheets act as a preferential path which caused charge transport more easily than in pristine P3HT.