Solid oxide fuel cells (SOFCs) have received significant attention recently since their characteristic high efficiency for energy conversion and multiple fuel selections promise to be a clean electric power generation approach. However, the application of SOFCs is limited by the excessive operation temperature and relatively high system cost because of the high operation temperature. Therefore, current research interests have devoted to reducing the operation temperature as well as developing an inexpensive fabrication method. In the general, the ionic conductivity in the solid electrolyte plays a critical role in determining the operation temperature of a SOFC. In order to reduce the operation temperature, it is necessary to achieve a thinner and denser electrolyte film. To achieve this goal, we selected the electrophretic deposition (EPD) approach to fabricate the SOFC structure because the EPD is long established as a powerful tool for forming complex ceramics in diverse shapes and on various substrates. Also, the application of EPD to fabricate SOFCs has been demonstrated by previous research. This research is divided into three parts. First, we discussed the EPD suspension properties, the microstructure after sintering, and the optimized conditions to fabricate SOFCs. In the second part, we tried to fabricate the tri-layer structure by Co-Deposition and One Step Sintering method. Meanwhile, we discussed the microstructure after sintering and the feasibility of this method. Finally, a Step-by-Step method was performed to fabricate SOFCs. The electrochemical analysis was conducted and the microstructure after sintering was investigated.