In this thesis, we study the optical properties in one-dimensional superconducting photonic crystals using numerical simulation. First, let A be the superconductor layer and B be the dielectric layer, then put layer and alternately arranged to the form air/(AB)^N/air. Define the form (AB)^N as the Positive, and the form (BA)^N as the Negative, then connect the Positive and the Negative in series that we can use the Transfer Matrix Method (TMM) to plot the transmission spectrum. By analyzing the transmission spectrum, we can generalize that the relation between period N, multiples of total thickness R, orders of combination structure Positive and Negative α, and the number of peaks P as P=R(N-1)+α. Second, we add external magnetic field to study how the magnetic field effect the transmission spectrum. After change the variables, we know that when the crystal is in the environment which temperature T is under the critical temperature Tc and external magnetic field B is under critical magnetic field Hc2(T), the bandwidth will decrease along the temperature and external magnetic field increase. In the third part, we combine the results in the Chapters aforementioned. As we change the thickness of the dielectric layer and the superconductor layer, we can see the features in narrow bands. Then add external magnetic field to study how the transmission spectrum will change while the magnetic field increased. Keyword: photonic crystals, superconductor, transmittance spectrum.