It is popular and inevitable for us to have many instruments with display screens in our life. The requirements of qualities whatever in image or appearance of apparatus have become more sophisticated. A revolutionary technology of TFT LCDs has been developed quickly which is system-on-panel (SOP) applications. However, SOP application has the potential to realize compact, highly reliable, and high resolution display by integrating functional circuits within a display. Besides, the cost of panel becomes lower, as well as the higher yield rate can be achieved. In the driver system of thin-film transistor liquid-crystal display (TFT-LCD), gate drivers (or scan drivers) are the essential parts that sequentially control the gates of pixel TFTs. Therefore, the pixel TFTs can transfer correct data and store in the liquid crystal and storage capacitors. Recently, in the consumer electronic display products, the gate driver circuits have been integrated into the bottom plate glass of LCD module rather than providing form the conventional ICs. Although the electron mobility in a-Si TFTs is extremely low (≈0.3cm2/V-s), the traits of high uniformity and low cost of manufacturing a-Si TFTs have created the trend towards gate driver on array (GOA). Moreover, the application of GOA decreases the cost of ICs and results in the module lighter and thinner. In this thesis, we propose two kinds of gate driver for the flat panel application. First one is bi-directional, pre-charge and noise-free sharing gate driver circuit. Using four phase clock signals to achieve single path condition and expanding the output stage can save tremendous layout area for narrow bezel purpose. In the second one, we emphasize on the power consumption issue. We propose a new structure called pseudo-bootstrap unit and introduce the concept of single clock driving to our gate driver circuit. Furthermore, this gate driver can not only suppress the noise but also lower the power consumption. We are hoping to add the bi-directional scanning feature into this gate driver in the future.