Unified line-of-sight: A guidance algorithm with integral wind-up mitigation and turning assist for USVs

Guidance algorithm is a key part in waypoint navigation for USVs. In this paper, a novel guidance algorithm named the unified line-of-sight (ULOS) is introduced. The ULOS algorithm is developed based on the concept of the integral-based LOS algorithm. However, a special technique is employed in the...

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Published inOcean engineering Vol. 314; p. 119615
Main Authors Tanakitkorn, Kantapon, Phoemsapthawee, Surasak, Thaweewat, Nonthipat, Jungrungruengtaworn, Sirirat
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 15.12.2024
Subjects
Cross-track error
Integral wind-up alleviation
Integral-based LOS
Line-of-sight guidance
Path following
Cross-track error
Line-of-sight guidance
Integral wind-up alleviation
Integral-based LOS
Path following
Online AccessGet full text
ISSN0029-8018
DOI10.1016/j.oceaneng.2024.119615

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Abstract Guidance algorithm is a key part in waypoint navigation for USVs. In this paper, a novel guidance algorithm named the unified line-of-sight (ULOS) is introduced. The ULOS algorithm is developed based on the concept of the integral-based LOS algorithm. However, a special technique is employed in the ULOS algorithm to address the integral wind-up issue commonly found in other integral-based LOS algorithms in the literature. In addition, a heading compensation term based on sway velocity is incorporated into the algorithm. This sway compensation term enhances the vehicle’s ability to execute sharp turns effectively. The ULOS algorithm was benchmarked against four existing guidance algorithms in various tasks through numerical simulations. The comprehensive results have revealed the superior performance of the ULOS algorithm over the other algorithms. •A novel guidance algorithm named the unified line-of-sight (ULOS) is introduced.•The ULOS uses a unique technique to address integral wind-up.•A sway compensation is added to enhance the vehicle’s ability in sharp turns.•The ULOS has been benchmarked against four existing guidance algorithms.•The ULOS is able to handle the external disturbance with superior performance.
AbstractList Guidance algorithm is a key part in waypoint navigation for USVs. In this paper, a novel guidance algorithm named the unified line-of-sight (ULOS) is introduced. The ULOS algorithm is developed based on the concept of the integral-based LOS algorithm. However, a special technique is employed in the ULOS algorithm to address the integral wind-up issue commonly found in other integral-based LOS algorithms in the literature. In addition, a heading compensation term based on sway velocity is incorporated into the algorithm. This sway compensation term enhances the vehicle’s ability to execute sharp turns effectively. The ULOS algorithm was benchmarked against four existing guidance algorithms in various tasks through numerical simulations. The comprehensive results have revealed the superior performance of the ULOS algorithm over the other algorithms. •A novel guidance algorithm named the unified line-of-sight (ULOS) is introduced.•The ULOS uses a unique technique to address integral wind-up.•A sway compensation is added to enhance the vehicle’s ability in sharp turns.•The ULOS has been benchmarked against four existing guidance algorithms.•The ULOS is able to handle the external disturbance with superior performance.
ArticleNumber 119615
Author Jungrungruengtaworn, Sirirat
Thaweewat, Nonthipat
Phoemsapthawee, Surasak
Tanakitkorn, Kantapon
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Keywords Cross-track error
Line-of-sight guidance
Integral wind-up alleviation
Integral-based LOS
Path following
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Snippet Guidance algorithm is a key part in waypoint navigation for USVs. In this paper, a novel guidance algorithm named the unified line-of-sight (ULOS) is...
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StartPage 119615
SubjectTerms Cross-track error
Integral wind-up alleviation
Integral-based LOS
Line-of-sight guidance
Path following
Title Unified line-of-sight: A guidance algorithm with integral wind-up mitigation and turning assist for USVs
URI https://dx.doi.org/10.1016/j.oceaneng.2024.119615
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