Directional and adaptive forgetting factor based recursive least square algorithms for maneuvering dynamic identification and motion prediction of unmanned surface vessel

In recent years, Unmanned Surface Vessel (USV) has been increasingly widely used in commercial and scientific research fields. The prerequisite of realizing intelligent control and auxiliary decision of USV is to establish accurate mathematical model of maneuvering motion and carry out effective par...

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Vydané v:Ocean engineering Ročník 342; s. 122948
Hlavní autori: Tan, Mu, Xiang, Gong, Xiang, Xianbo, Yu, Shuhang, Rao, Kunpeng, Soares, Carlos Guedes
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Elsevier Ltd 30.12.2025
Predmet:
Adaptive forgetting factor
Computational fluid dynamic
Directional forgetting factor
Parameter identification
Recursive least squares algorithm
USV
USV
Directional forgetting factor
Computational fluid dynamic
Parameter identification
Recursive least squares algorithm
Adaptive forgetting factor
ISSN:0029-8018
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Shrnutí:In recent years, Unmanned Surface Vessel (USV) has been increasingly widely used in commercial and scientific research fields. The prerequisite of realizing intelligent control and auxiliary decision of USV is to establish accurate mathematical model of maneuvering motion and carry out effective parameter identification. In this paper, to overcome the limitations of traditional recursive least squares (FFRLS) in dealing with non-continuous excitation and dynamic change environment, two improved recursive least squares algorithms: directional forgetting recursive least squares algorithm (DFFRLS) and adaptive forgetting recursive least squares algorithm (AFFRLS) are proposed. In this paper, the training datasets are established by validated CFD simulated turning test and Z-shaped maneuverability test. The parameters of the model are identified by DFFRLS and AFFRLS algorithm, and compared with the traditional FFRLS algorithm. The results show that DFFRLS has higher identification accuracy and robustness through directional decomposition when dealing with abnormal data such as random noise, sensor fault and data mutation. However, the AFFRLS, by adapting the forgetting factor adaptively, makes it possible to be more accurate in the process of data updating, especially when the parameters change rapidly. The research results of this paper show that DFFRLS and AFFRLS algorithms have significant advantages in parameter identification of USVs, especially in specific complex and dynamic environments, which can effectively improve the accuracy and performance of the maneuvering model. •A DFFRLS algorithm is proposed to effectively address parameter divergence problems under discontinuous excitation.•An AFFRLS algorithm is proposed to overcome the limits of traditional forgetting RLS in rapidly changing environments.•Compared with CFD simulation of Z-maneuvers, the accuracy and stability of two identification-based predictions were verified.•DFFRLS shows strong anti-interference in long-term marine environments, while AFFRLS excels in rapidly changing conditions.
ISSN:0029-8018
DOI:10.1016/j.oceaneng.2025.122948