Localization of an underwater vehicle using an IMU and a laser-based vision system

This paper describes the development of a position tracking system designed for a remotely operated vehicle (ROV). The sensor package consists of an inertial measurement unit (IMU) and a laser-based vision system (LVS). The LVS consists of two undewater laser pointers and a single CCD camera mounted on the ROV. The LVS fuses data deriving from the projection of the laser pointers on the image plane while it tracks a target at the same plane using computer vision algorithms. The LVS calculates the position vector of the vehicle at a low frequency, with respect to the center of the tracked object. The IMU measures the accelerations and angular velocities of the vehicle at a high frequency. The fusion of the two sensors is based on a multisensor Kalman filter where the measured acceleration and angular velocity of the IMU is fed directly to the filter. The result is the calculation of the position vector at a high frequency, which can be used for a smooth closed loop steering control of the vehicle. The integration of the system was proved successful through an extensive experimental procedure.

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