An electrically tunable polarizer using dye-doped liquid crystal (LC) gels is demonstrated. The main mechanism of such a polarizer is a combination of the light absorption and the scattering owning to dichroic dyes and poly-domains resulting from polymer networks. In this thesis, we observe the morphologies of dye-doped liquid crystal gels by a scanning electron microscopy. The polymer networks perpendicular to the glass substrates are chain-linked by lots of nano-sized polymer grains. The sizes of poly-domains and polymer grains depend on curing temperatures and monomer concentrations. The domain sizes of polymer networks and the sizes of polymer grains increase by increasing the curing temperature. The domain sizes have influence on electro-optical properties of the electrically tunable polarizers. In our experiments, the maximum contrast ratio of the polarizer can be electrically tuned is around 5:1~10:1 at 10C curing temperature. The operating voltage is around 30 Vrms. The response time is around ~ 6ms. The optical analysis based on the scattering theory and the absorption theory is discussed as well. Furthermore, we focus on the color issue of dye-doped LC gels LC gels and provide several methods to improve the colors. One application of electrically tunable iris is also demonstrated.