In nature, fish can extract near field information via detecting nearby pressure variations. This concept is suitable for a biomimetic autonomous underwater vehicle (BAUV): a fish-like swimming robot. This study develops the methods to control the robotic fish by feeding back the hydrodynamic pressure variations of the environment. To control a robotic fish to swim along the solid boundary while exploring the environment, this paper presents a method to control the robot to swim along a straight wall via pressure feedback. A model based on two-dimensional potential flow is used, where the tail of the robotic fish and the wall effect are described as a dipole and an image dipole on the opposite side of the wall, respectively. From this model, the position of the robotic fish with respect to the wall can be derived from the magnitudes and ratios of the pressure data measured by the pressure sensors equipped on the head and the body of the robot. The information is then used to control the direction of the robotic fish. From the experiments, the robotic fish can swim a distance-to-wall/tail-span ratio of 1-1.33 beside a wall, which shows the effect of the proposed method. Besides, a robotic fish is expected to detect the periodic movements of its neighbors and adjust its motion, such that it can swim properly in a school. To achieve that, this study also presents a method to control the tail motion of a robotic fish to follow the oscillation of a neighboring source. The tail motion of the robot and the oscillation of the source are described as two oscillators, and can be synchronized by an oscillator-based method. To track the oscillation of the source, the hydrodynamic pressure around the robotic fish is measured by a PVDF sensor on the robot. The predicted pressure generated by the robotic fish is subtracted from the measured pressure, and the pressure generated by the source is obtained. The pressure field is also described by a dipole model based on the potential flow theory. Based on this model, the phase difference between the tail and the oscillating source can be estimated from the pressure measurements of the PVDF sensor. This phase difference is then used to determine the torque which drives the tail. From the experiments that involve a captured robotic fish swimming close to an oscillating source, the proposed phase following control method is demonstrated to be effective.