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Main Authors: Vijayakumar, Akash, A, Atmanand M, Somayajula, Abhilash
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.09668
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author Vijayakumar, Akash
A, Atmanand M
Somayajula, Abhilash
author_facet Vijayakumar, Akash
A, Atmanand M
Somayajula, Abhilash
contents Autonomous docking remains one of the most challenging maneuvers in marine robotics, requiring precise control and robust perception in confined spaces. This paper presents a novel approach integrating Model Predictive Path Integral(MPPI) control with real-time LiDAR-based dock detection for autonomous surface vessel docking. Our framework uniquely combines probabilistic trajectory optimization with a multiobjective cost function that simultaneously considers docking precision, safety constraints, and motion efficiency. The MPPI controller generates optimal trajectories by intelligently sampling control sequences and evaluating their costs based on dynamic clearance requirements, orientation alignment, and target position objectives. We introduce an adaptive dock detection pipeline that processes LiDAR point clouds to extract critical geometric features, enabling real-time updates of docking parameters. The proposed method is extensively validated in a physics-based simulation environment that incorporates realistic sensor noise, vessel dynamics, and environmental constraints. Results demonstrate successful docking from various initial positions while maintaining safe clearances and smooth motion characteristics.
format Preprint
id arxiv_https___arxiv_org_abs_2501_09668
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Model Predictive Path Integral Docking of Fully Actuated Surface Vessel
Vijayakumar, Akash
A, Atmanand M
Somayajula, Abhilash
Robotics
Autonomous docking remains one of the most challenging maneuvers in marine robotics, requiring precise control and robust perception in confined spaces. This paper presents a novel approach integrating Model Predictive Path Integral(MPPI) control with real-time LiDAR-based dock detection for autonomous surface vessel docking. Our framework uniquely combines probabilistic trajectory optimization with a multiobjective cost function that simultaneously considers docking precision, safety constraints, and motion efficiency. The MPPI controller generates optimal trajectories by intelligently sampling control sequences and evaluating their costs based on dynamic clearance requirements, orientation alignment, and target position objectives. We introduce an adaptive dock detection pipeline that processes LiDAR point clouds to extract critical geometric features, enabling real-time updates of docking parameters. The proposed method is extensively validated in a physics-based simulation environment that incorporates realistic sensor noise, vessel dynamics, and environmental constraints. Results demonstrate successful docking from various initial positions while maintaining safe clearances and smooth motion characteristics.
title Model Predictive Path Integral Docking of Fully Actuated Surface Vessel
topic Robotics
url https://arxiv.org/abs/2501.09668