A Universal Simulation Framework of Shipborne Inertial Sensors Based on the Ship Motion Model and Robot Operating System

Jing, Qianfeng; Wang, Haichao; Hu, Bin; Liu, Xiuwen; Yin, Yixin

doi:10.3390/jmse9080900

Cited by 6 publications

(2 citation statements)

References 33 publications

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“…The autonomous surface vehicle (ASV), as an intelligent, miniaturized, and versatile unmanned marine transport platform that operates through remote control or autonomous navigation, has a variety of applications in offshore ocean engineering [1][2][3][4][5][6][7][8][9][10][11][12][13]. Among the various applications of ASVs, the trajectory planning of ASVs is particularly crucial to provide a safe trajectory.…”

Section: Introductionmentioning

confidence: 99%

Distributed Swarm Trajectory Planning for Autonomous Surface Vehicles in Complex Sea Environments

Wang,

Li,

Wang

et al. 2024

JMSE

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In this paper, a swarm trajectory-planning method is proposed for multiple autonomous surface vehicles (ASVs) in an unknown and obstacle-rich environment. Specifically, based on the point cloud information of the surrounding environment obtained from local sensors, a kinodynamic path-searching method is used to generate a series of waypoints in the discretized control space at first. Next, after fitting B-spline curves to the obtained waypoints, a nonlinear optimization problem is formulated to optimize the B-spline curves based on gradient-based local planning. Finally, a numerical optimization method is used to solve the optimization problems in real time to obtain collision-free, smooth and dynamically feasible trajectories relying on a shared network. The simulation results demonstrate the effectiveness and efficiency of the proposed swarm trajectory-planning method for a network of ASVs.

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Section: Introductionmentioning

confidence: 99%

Distributed Swarm Trajectory Planning for Autonomous Surface Vehicles in Complex Sea Environments

Wang,

Li,

Wang

et al. 2024

JMSE

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show abstract

“…XAI methods can thus be used to interpret and justify the decisions made by a black-box model, control and prevent erroneous actions, improve the model, and even discover new strategies, correlations in the data set or application [19]. In [20], the importance of explaining AI-systems to non-expert users is highlighted, especially with consideration for the preparation for wider-scale operations of ASVs. The combination of explanations and thorough testing of the AI system is crucial for gaining the trust needed for the autonomous system to be deployed [21].…”

Section: Introductionmentioning

confidence: 99%

Explaining a Deep Reinforcement Learning Docking Agent Using Linear Model Trees with User Adapted Visualization

Gjærum

Strümke

Alsos

et al. 2021

JMSE

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Deep neural networks (DNNs) can be useful within the marine robotics field, but their utility value is restricted by their black-box nature. Explainable artificial intelligence methods attempt to understand how such black-boxes make their decisions. In this work, linear model trees (LMTs) are used to approximate the DNN controlling an autonomous surface vessel (ASV) in a simulated environment and then run in parallel with the DNN to give explanations in the form of feature attributions in real-time. How well a model can be understood depends not only on the explanation itself, but also on how well it is presented and adapted to the receiver of said explanation. Different end-users may need both different types of explanations, as well as different representations of these. The main contributions of this work are (1) significantly improving both the accuracy and the build time of a greedy approach for building LMTs by introducing ordering of features in the splitting of the tree, (2) giving an overview of the characteristics of the seafarer/operator and the developer as two different end-users of the agent and receiver of the explanations, and (3) suggesting a visualization of the docking agent, the environment, and the feature attributions given by the LMT for when the developer is the end-user of the system, and another visualization for when the seafarer or operator is the end-user, based on their different characteristics.

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A berthing state estimation pipeline based on 3D point cloud scan-matching and berth line fitting

Wang,

Yin,

Jing

et al. 2024

Measurement

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A Universal Simulation Framework of Shipborne Inertial Sensors Based on the Ship Motion Model and Robot Operating System

Cited by 6 publications

References 33 publications

Distributed Swarm Trajectory Planning for Autonomous Surface Vehicles in Complex Sea Environments

Distributed Swarm Trajectory Planning for Autonomous Surface Vehicles in Complex Sea Environments

Explaining a Deep Reinforcement Learning Docking Agent Using Linear Model Trees with User Adapted Visualization

A berthing state estimation pipeline based on 3D point cloud scan-matching and berth line fitting

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