Abstract
Autonomous collision detection and avoidance is a crucial requirement for the safe navigation of unmanned surface vehicles (USVs) in maritime traffic situations. Automatic identification system (AIS) is used to obtain the motion information of surrounding ships and their dimensional specifications. With AIS information, appropriate collision risk assessment between two ships can be performed; further, collision avoidance can be achieved by defining a safe radius of avoidance, which can be determined considering the shape parameters of a target ship. However, AIS data are often unreliable and some commercial fishing vessels intentionally turn off the public tracking system to hide their location. Under these circumstances, marine radars are used to detect and estimate the motion information of nearby ships. However, most existing target tracking studies model the target as a point object without any spatial extent, and thus, its physical dimensions cannot be identified. In this paper, a target tracking method that uses a marine radar is proposed to simultaneously estimate the motion states (i.e., position, course, and speed) of a target ship and its geometric parameter (length) in the framework of an extended Kalman filter (EKF). The proposed approach enhances collision avoidance by providing the kinematic and length parameters to evaluate collision risk and generate an appropriate collision-free path. Real-sea experiments using a developed USV system were conducted to verify and demonstrate the feasibility of the proposed algorithm; the results are presented and discussed in this paper.
Highlights
Over several decades, autonomous navigation technologies for unmanned surface vehicles (USVs) have advanced owing to the development of sensing and computing capabilities [1]
When automatic identification system (AIS) data are not available, the conventional automatic radar plotting aid (ARPA) system estimates the motion of target ship based on the time-varying trajectory obtained using consecutive radar images; collision-free path is generated considering an arbitrarily defined safe radius of avoidance
Most existing target tracking studies consider the target as a point object; kinematics parameters such as position, course, and speed are estimated within the framework of target motion analysis (TMA)
Summary
Autonomous navigation technologies for unmanned surface vehicles (USVs) have advanced owing to the development of sensing and computing capabilities [1]. When AIS data are not available, the conventional ARPA system estimates the motion of target ship based on the time-varying trajectory obtained using consecutive radar images; collision-free path is generated considering an arbitrarily defined safe radius of avoidance. By setting the safe radius to a large value, the USV can conservatively avoid an approaching target ship whose shape parameters are unknown This approach does not provide an accurate evaluation of ship collision or support the generation of an efficient collision-free path. When a USV encounters a target ship whose geometric parameters are not available a priori, the proposed method enhances its collision avoidance capability by providing shape information to evaluate the ship collision risk accurately and to generate an appropriate collision-free path.
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