All unique properties of charges, spins and crystal structures of transition metal-oxides can attribute to their symmetrical valence electron orbital. Indeed, many important features, such as high temperature superconductivity, colossal magnetoresistance effect and metal-insulator transition are in closely connection to the complicate charge-spin interaction. Therefore, in this thesis, we will investigate the electronic structure of these strongly correlated systems by means of first-principles calculations. In this work, we firstly performed the electronic structure calculation of Fe3O4. Beyond the DFT, LSDA+U approximation was also adopted to elucidate the characteristics of this half-metal material. Furthermore, charge, spin, and orbital ordering in a half-metal were studied carefully with proper coordinate consideration. On the other hand, the electronic structure calculations corresponding to different crystal structures were carried out in our work. Finally, the optimized doping site of Al in Al-doped Fe3O4 can be determined from calculated total energies.