Piezo-actuated stage is commonly used in electron beam lithography for providing nanometer scale positioning resolution. However, the PZT stage has hysteresis effect which degrades positioning performance. For this reason, a mathematical model is required to eliminate hysteresis. In addition, an appropriate controller dealing with model mismatching and un-modeled high frequency dynamics is demanded. As a result, in this thesis we presented the classical inverse Preisach model and improved the disadvantage of the model such as complexity and large memory demand by surface fitting method, resulting in a new surface fitted inverse Preisach model (INVP). Moreover, the model mismatching and un-modeled high frequency dynamics are taken as uncertainty sources of the system and are suppressed by robust controllers. The experiment results show that the INVP model has benefits such as reducing more than 85% hysteresis and shortening computation time to 0.19ms, making the INVP available for on-line application. Moreover, using the INVP in system identification might be useful to obtain a more accurate LTI system and to reduce the model mismatching. These advance controller design process. Finally, the INVP combined robust controllers contribute to energy re-distribution which results in a better tracking control in middle frequency.