To reduce the emissions of NOx caused by traffic emissions and internal combustion engines, the NOx removal using photoreactor has been investigated. An optical fiber photoreactor was studied for the photodecomposition of NOx under a steady state flow system. A batch also was performed to classify photocatalytic efficiency of different catalysts for decomposing of NOx. Based on the batch data, the TiO2-coated optical fiber photoreactor was built and studied in order to optimize different parameters such as temperature, O2 volume ratio and light intensity. Hence the optical fiber reactor may achieve a practical removal of the NOx. The titanium oxide sol for dip-coating on the optical fiber was prepared according to the procedures of modified hydrothermal synthesis previously. The thickness of the TiO2 and Ag/TiO2 film prepared by modified hydrothermal method on an optical fiber were about 54nm and 44nm estimated by SEM, respectively. The UV-vis spectra showed that pre-edge of adsorption peak located at about 350nm. In the photocatalytic reaction, the concentration of NOx reactant gas was 246ppm and the retention time was about 64min. A NOx analyzer was used to measure the NO, NOx, and NO2 concentrations. After reaching steady state, UV irradiation was turned on and continued for several hours. The experimental data revealed that the removal of NOx was found to increase as the intensity of the incident light intensity increased. The optimal catalyst and reaction conditions were observed at the 0.5wt%-Ag/TiO2 catalyst and a reaction temperature 160℃. The conversion of NOx was 5.22%.