This thesis aims to explore how the dynamic ground effect affects the lifting behavior of a robotic flat-fish when it is near a flat bottom. The robotic fish is propelled by a pair of ribbon side fins, and a caudal fin controls the pitching in the vertical plane. Variables related to the swimming behavior of the robotic fish including the angle of the caudal fin, the swimming modes of the ribbon fin, and the distance of the fish body to the ground. The outputs of the robotic fish motion are the acceleration and the velocity in the vertical direction, the angular acceleration, the angular rate of the pitch while the robot is starting to pitch. A dynamic model of the robotic fish is derived using the Lagrange method. The added mass and damping coefficients of the fish body are estimated by equations of an equivalent ellipsoid. Ribbon-fin generated forces and the hydrodynamic interaction with the caudal fin are the driving forces and moments of the fish body. A robotic fish testbed is built to tank tests. The testbed’s ribbon fins perform two types of swimming modes, either a constant amplitude or a linear amplitude mode for the surge and turning motions. The caudal fin is mainly responsible for the pitching motion. In the construction of the vehicle motion model, the dynamic ground effect on the pitch and surge motions are approximated by potential theory derived by a linear oscillating fin and its mirror image with respect to solid ground. A video camera placed above the tank was used to record the position and velocity of a triangle formed by three light bulbs on the top cover of the vehicle. A pressure sensor and electronic compass are placed on the main case to measure the pressure and pose information, they are also used as feedback signals for automatic depth control and pitch angle calculations. More than twenty trials of independent variable combinations of caudal angle and swimming modes are conducted at various distances to the ground. Experimental data and simulated data are compared to verify the dynamic model of the ground effects on the robotic fish.