Solid oxide fuel cells (SOFCs) have the highest energy conversion efficiency among various fuel cell types. SOFCs can be divided into two categories according to their cell design: planner and tubular type. Tubular SOFCs have many advantages in terms of good mechanical strength, easy sealing, and simple stacking process. Meanwhile, electrophoretic deposition (EPD) is very useful technique to deposit thin or thick layers due to easy layer thickness control by voltage and time. When a dc electric field is applied to the carbon rod in the slurry, the charging agent carries the particles to a substrate. One of major advantages of EPD is to fabricate multi-layer structure at the same time. In this study, symmetrical La0.7Ca0.3Cr0.8Mn0.2O3- δ(LCCM) electrode scaffold-type micro tubular SOFCs with the configuration of LCCM-YSZ anode // YSZ electrolyte // LCCM-YSZ cathode have been fabricated by EPD process. LCCM is considered as promising symmetrical electrode because it is very stable in both oxidizing and reducing atmosphere. The microstructure of the symmetrical electrode was controlled by the amount of pore former (PMMA). LCCM-YSZ electrode slurry for highly porous microstructure with uniform pore distribution was obtained with 40 vol.% PMMA, 2.5 wt.% polyvinyl butyral (PVB), 100 ml anhydrous ethanol, and 3 wt.% charging agent (polyethyleneimine). YSZ electrolyte slurry with highly dense microstructure was prepared with polyvinyl butyral (PVB), 100 ml anhydrous ethanol, and 5 wt.% charging agent (phosphate ester). After weighing of each slurry, ball-milling process was performed for 24 hour to obtain well-dispersed and uniform slurry. Carbon rod was deposited by LCCM-YSZ anode slurry, YSZ electrolyte slurry, and LCCM-YSZ cathode slurry in order. Deposition condition affected the microstructure and on thickness of each layers. LCCM-YSZ anode had thick layer for supporting the single cell with the deposition condition of the applied voltage of 20 V for 100 second. YSZ electrolyte was deposited on anode with the deposition condition of the applied voltage of 20 V for 20 second. At last, LCCM-YSZ electrode was deposited on electrolyte with the deposition condition of the applied voltage of 20 V for 20 second. After deposition of all layers by EPD, the single cell was co-filed at 1400 °C for 5 hour. Various processing conditions such as amount of charging agent, applied voltage, deposition time and sintering temperature were investigated. Stoichiometry amount of co-catalysts such as Pd or Co-Ni-Mo for better performance were impregnated into both sides of the LCCM scaffold by a glycine mediated solution impregnation method. Finally, the single cell performances of the fabricated LCCM symmetrical scaffold-type micro tubular SOFCs were evaluated in the temperature range of 600-800°C. Additionally thermal shock and redox cycling tests have been carried out.