This research in this thesis is based on the use of Vertically Aligned (VA) liquid crystal mode in the design and development of single-cell-gap Transflective TFT-LCDs. In particular, we focus on using different electrode designs between T and R part in order to match the corresponding T-V and R-V curves. Since the light passes through the liquid crystal layer twice in the R part but only once in the T part, the structure we design is required to produce stronger electric fields in T part and weaker electric fields in the R part so that similar retardation change in T and R can be obtained. As a result, the transmittance and reflectance can become very similar even when the pixel is driven by a single TFT-driving circuit. Apart from matching the T-V and R-V curves, we also try to use compensation film and multi-domain approaches to simulate and improve the narrow viewing angle property of the VA liquid crystal mode. This thesis is divided into two parts; the first one is based on a Partial-Switching scheme which employs a partial distributed electrode design while the second one is based on the use of a VA-FFS liquid crystal mode which has a VA liquid crystal mode for the original OFF state and FFS mode for the driven ON state.