Abstract
Considering autonomous navigation in busy marine traffic environments (including harbors and coasts), major study issues to be solved for autonomous ships are avoidance of static and dynamic obstacles, surface vehicle control in consideration of the environment, and compliance with human-defined navigation rules. The reinforcement learning (RL) algorithm, which demonstrates high potential in autonomous cars, has been presented as an alternative to mathematical algorithms and has advanced in studies on autonomous ships. However, the RL algorithm, through interactions with the environment, receives relatively fewer data from the marine environment. Moreover, the open marine environment causes difficulties for autonomous ships in learning human-defined navigation rules because of excessive degrees of freedom. This study proposes a sustainable, intelligent learning framework for autonomous ships (ILFAS), which helps solve these difficulties and learns navigation rules specified by human beings through neighboring ships. The application of case-based RL enables the participation of humans in the RL learning process through neighboring ships and the learning of human-defined rules. Cases built as curriculums can achieve high learning effects with fewer data along with the RL of layered autonomous ships. The experiment aims at autonomous navigation from a harbor, where marine traffic occurs on a neighboring coast. The learning results using ILFAS and those in an environment where random marine traffic occurs are compared. Based on the experiment, the learning time was reduced by a tenth. Moreover, the success rate of arrival at a destination was higher with fewer controls than the random method in the new marine traffic scenario. ILFAS can continuously respond to advances in ship manufacturing technology and changes in the marine environment.
Highlights
The new environment had neighboring ships following the right path to comply with human-defined navigation rules in the harbor that were not randomly created
This study demonstrates that when the autonomous ship learns autonomous navigation using the intelligent learning framework for autonomous ships (ILFAS) in the space, unnecessary experience is eliminated and learning results are stabilized as compared to general random learning
If the neighboring ships are not intelligent, there is a limit to the research on intelligent autonomous ships
Summary
Artificial intelligence for autonomous ships (unmanned surface vehicles (USVs) and autonomous surface vehicles (ASVs)) has been extensively investigated in the private sector (including bathymetric measurements, subsea pipelines management, marine geography surveys, and safety management) and the military sector (including patrol, security, intrusion detection, blockage, and defense). In Starcraft (a real-time strategy game), multiple agents can be controlled at the same time to outperform human players [12], while in Minecraft (a role-playing video game), tiering problems are solved based on decisionmaking. This hints at the possibility of solving problems similar to a human [13]. There are several factors, such as the natural environment and harbor entry/departure rules that have been defined for each harbor in the self-driving vessel’s learning, and this learning must be learned through surrounding vessels This makes it difficult to establish an environment capable of learning human-level rules through learning [14]
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