Band gap narrowing and red-shift of optical absorption spectra were fiercely debated for N-doped anatase in the past ten years. In this study, the properties of N-doped anatase were discussed using first principle calculation. In order to realize the variations of stability, electronic and optical properties of N-doped anatase, I apply formation energy, charge density of state, charge density distribution, and optical absorption coefficient to this research. According to my calculation, the formation energy of N-doped anatase was increased as the system concentration of nitrogen was elevated. This result was lead to difficult doping of nitrogen atoms into the lattice of anatase. Besides, the doped nitrogen atoms preferred to grouped or clustered with the pre-doped nitrogen atoms in the same tetrahedral site under the nitrogen doping process. The band gap was unchanged when the doping concentration of nitrogen atoms was low. When the doping concentration was increased, the band gap variation was also getting obvious. Under the analysis of optical absorption spectra, the red-shift-like behavior of optical absorption spectra became apparent as the doping concentration was elevated, even though without the band gap variation. Our results show that the red-shift-like behaviors do not seem to have clear correlation with the change in the electronic band gaps. I proposed that defect state and redistribution of charge density of the valence band top were the main factors to the red-shift properties of N-doped anatase. On the other hand, I supposed that the band gap defined by tauc plot was inappropriate for defected structure of anatase. In the system under high concentration of doped-nitrogen atoms and oxygen vacancies（N:Vo = 2:1）, the red shift of optical absorption spectra was observed due to high charge density of the localized states. The optical absorption efficiency does not obviously enhanced by oxygen vacancies in N-doped anatase. Properties of the TiO2 involved N:H is similar to the N-doped anatase contain vacancies. When the concentration of x in the TiO2-x(NH)x raise to 0.250, the red shift of optical absorption spectra was observed due to high charge density of the localized states. Nevertheless, The optical absorption efficiency does not obviously enhanced by hydrogen bonding to the nitrogen in N-doped anatase.