This thesis demonstrates a photoswitchable and electrically tunable hybrid photonic structure consisting of a one-dimensional photonic crystal (1D-PC) infiltrated with an azo-chiral-doped liquid crystal (ACDLC) as the defect layer. Based on the photoswitching among the planar-nematic (N), twisted-nematic (T), and planar-cholesteric (CLC) states, attributable to the photoinduced trans-cis isomerization of the azo-chiral dopant, three stable and switchable sets of defect-mode peaks can be realized by controlling the intensity of the green and ultraviolet lights irradiated to the PC/ACDLC cell. Moreover, when respectively stabilizing the cell in the nematic and planar-cholesteric states, upon the application of external voltages, two unique tunabilities in wavelength and intensity can be obtained in our proposed PC/ACDLC hybrid in accordance with the electrically controlled birefringence and voltage-controlled light-scattering strength in the nematic and cholesteric states, respectively. Other spectral features of the proposed hybrids are clarified accordingly. Furthermore, we also investigated the effect of polarized UV light on the isomerization process of azo chiral dopant as well as the textural transition in the ACDLC cell. When the polarization state of UV light is perpendicular to the rubbing direction, the photo-induced isomerization will be fastened which facilitates the unwinding of molecular helices. In the contrary, setting the polarization state of UV light in parallel to the rubbing direction can rewind the ACDLC cell to the helical state, presumably due to the photo-induced instability of the azo chiral molecules in the cis state. Consequently, we propose a new pathway for an ACDLC, enabling the isomerization process of azo chiral molecules and textural transition of LC states to be triggered by a single light source.