Lenses are widely used in our daily life. In recent years, with the development of fabrication and computer power, a metasurface composed of sub-wavelength structures has been realized. The metasurface, which does not exist in nature, manipulate the phase, amplitude and polarization of electromagnetic waves by many sub-wavelength structures. It can achieve novel optical characteristics. When the metasurface is applied to the imaging optics, we widely call it metalens. In this dissertation, I designed three metalenses for different applications by using finite difference time domain (FDTD), near-to-far-field transformation, and in-house algorithms. The first one is an electronically modulated multifocal metalens. We combined twisted nematic liquid crystal (TN-LC) to theoretically demonstrate a tunable lens that can switch different focal points in sub-milliseconds. The second is an ultra-wide-angle metalens in hexagonal arrangement. We combine ray tracing method to design a single metalens, which is almost panoramic wide-angle. The third type is a broadband achromatic metalens. By rigorously designing meta-structures, we correct chromatic aberration by a single lens at visible wavelengths. Compared to traditional lenses and traditional diffraction elements, our simulation results show that the designed metalenses have an optical performance that is close to the diffraction limit, and have potential to be used in several optical systems. At the end of this dissertation, we introduce some methods such as inverse design, which can break the local-periodicity assumptions of the unit-cell design approach and improve performance of metalens in the future. Such method has the possibility to design an almost perfect lens theoretically, and then achieve a true meaning for metalens.