This thesis designs a polarization beam splitter (PBS) to achieve high light utilization efficiency (LUE). Compared with conventional absorption polarizers of which the LUE is at most 50%, the LUE of our design is about 80% under certain conditions. And, the 90% maximum light utilization efficiency was also achievable. We use dielectric diffraction grating to design the PBS and employ the so-called Littrow mounting phenomenon to analyze its characteristics. We use the "Rigorous Coupled Wave Analysis"(RCWA) to perform the numerical simulation. And we also describe the optimization process by using the physical theorems and equations. Some conventional PBSs employ birefringent crystals, multilayer structure, and birefringent multilayer structure. However, these attempts suffer either the relatively small acceptance angle or very bulky. The wire-grid polarizer/PBS which utilizes metal is also commercially available; nevertheless, the attenuation due to metals is inevitable. Compared with a wire-grid polarizer/PBS example in this thesis, our design would lead nearly 10% higher LUE in blue-violet band. However, there are some issues we need to concern about. First, we cannot apply whole visible band with one PBS. Second, the field of view (acceptance angle) of our PBSs is relatively too small to collect all light emitted from light sources with large divergence angle. To deal with the first issue, we may use red, green and blue light-emitting diodes (LED) for three separated band. The field of view could be improved by ignoring low-energy wavelengths in a Gaussian approximated LED spectrum. At the end of this thesis, we introduced some possible methods to reduce the divergence angle of LED light sources. An application of the PBS is backlight units (BLU) in the liquid crystal display (LCD). The usage of PBS can increase light utilization efficiency, and therefore, achieve high efficient energy utilization.