Numerous optical information processing, routing and imaging systems employ different polarization states to increase the information bandwidth and to reduce crosstalk between channels. Applications include, for example, free-space optical switching networks, optical microscopes and biosensors. In these systems, the polarizing beam splitter is a key element for separating two orthogonally polarized light beams. With the progress of semiconductors manufacturing technology, visible wavelength scale structure’s optoelectronic devices have become a rapidly growing field of research in recent years. Light manipulations capability of subwavelength dielectric gratings is substantial, manufacture wise are relatively easy and have the probability of mass production. The one dimensional slanted gratings used in augmented reality head-mounted display is one good example. Few theoretical analyses are focusing on such slanted gratings in the pass due to the lack of interest, mostly, the geometry was calculated mainly via mass parameter scan and simulation. In this thesis, one dimensional slanted gratings geometry was predicted using the Simplified Modal Method, achieving a transmittance rate as high as 92%. We also present how, by the use polarizing beam splitters, we can promote this one dimensional result to two dimensions. The two dimensional slanted gratings we successfully designed and can achieve a coupling efficiency as high as 70%, with an extinction ratio above 20 dB.