In this study, a simulation study on the kinematic parameters of a two-dimensional flatfish-shaped biomimetic autonomous underwater vehicle (BAUV) under specific height in water is performed. The flow field is analyzed by a computational fluid dynamics tool ANSYS-FLUENT, and the design of the BAUV is based on the biological flatfish to mimic the geometric characteristics of the submerged bodies. The flatfish model is divided into two parts, rigid body and flexible pectoral fin. Mathematical formula is derived to describe the motion of the flexible fin. The distribution of the pressure field and velocity field when the flatfish-shaped BAUV swimming at different height above the ground is compared. The simulation results show that the ground effect of the flow field coincides with the derived formula from the potential theory, and it is confirmed that the optimal swimming efficiency can be obtained at a specific multiple of the characteristic length of the BAUV. The optimization of swimming-height above the ground can be obtained by simulation. In the future applications, the flatfish BAUV can be controlled at a specific height to ground to achieve the purpose of most energy-saving.