The device characteristics of InAlAs/InGaAs pseudomorphic high mobility transistor is very excellent at high frequency operations. There are already a lot of teams which have done broad research and verify the electrical characteristic of device. In order to save costs and to develop new device effectively with better property in the future, so simulation technology with fitting becomes more and more important. In this study, we adopted TCAD of SILVACO company, based on the foundation of semiconductor physics, to study the DC characteristics of devices by simulation. First we adopted advanced physical models to fit the actual trend of electrical devices as model validation. Then we further use the advanced model parameters to fit the value of electrical properties, which can reveal optimized device trends. If simulate device by using TCAD, we have to choose the correct advanced model built in TCAD to obtain the correct trends and results. Therefore, because that the InGaAs semiconductor is a low band-gap material, we must reference the published papers or documents carefully to determine the properties of InGaAs which could easily lead to induce impact ionization at high electric field. The InAlAs surface would induce numerous negative dangling bond during epitaxy, lead to a lot of interface trap charge generated. Base on this, to get the correct trends of devices simulation, the corresponding model in manual of TCAD must be selected correctly. Then the calibration of the simulation values in the advanced model parameters is required to approach the actual value of device. Most of the parameters of advanced model are empirical parameters, so the user must attempt to complete the calibration in all means by himself. Finally, to optimize device trends we need to manipulate the delta-doped concentration and epitaxial structure, optimize epitaxy parameters of the barrier layer and the spacer layer as well as the channel layer thickness to predict the electrical characteristics of optimized device. It is important to develop the InAlAs/InGaAs system devices in the future with considerable assistance. The achievements of this thesis in simulation would provide key information for device development more effective, more time and cost saving.