Recently, the needs for liquid-crystal-on-silicon (LCOS) have been dramatically increased by the expansion of the projection display market. LCOS has the advantages of high resolution, light weight, and slim size. However, the motion blur issue, resulting from slow LC response, limits its potential for high quality display application. Fast switching LC modes were studied to solve the motion blur issue. With fast LC response less than 3 ms, the field sequential color (FSC) technique could be applied to improve the color gamut, and reduce power consumption. In this thesis, three kinds of fast switching LC modes: twisted nematic (TN), optically compensated bend (OCB) and surface stabilized ferroelectric liquid crystal (SSFLC) were studied in the reflective display technology. In reflective TN mode, low rotational viscosity LC material was utilized, and the cell gap was reduced to reduce LC response time.The parameters, such as, twisted angle, optical anisotropy, and reflectance were optimized in this research. Hybrid aligned nematic (HAN) cell was applied to solve the pre-transition time and critical operating voltage issues in the reflective OCB mode. The horizontal chevron defect issue of half-V mode FLC device was suppressed by the asymmetrical surface polarity controlled hybrid alignment technique. The reflectance of the FLC device was optimized by cell gap. The study solved the problems such as pre-transition time and alignment defect and discovered the best parameters of fabrication that it has fast response time less than 3 ms. Finally, LCOS device was fabricated in the use of SSFLC mode.