Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV

Brayan Saldarriaga; Rodrigo Gimenez-Valenzuela; Julio Montesdeoca; Flavio Roberti; Marcos Toibero

doi:10.1109/ICAR65334.2025.11338629

Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV

Brayan Saldarriaga
, Rodrigo Gimenez-Valenzuela
, Julio Montesdeoca
, Flavio Roberti
, Marcos Toibero

Grupo de Investigación en Bioética en la Investigación (GI-BI)

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución de conferencia › revisión exhaustiva

Resumen

This work presents a hierarchical control strategy for a differential-thrust Unmanned Surface Vehicle, integrating a polar Line of Sight guidance law with a dynamic feedback compensation layer. The kinematic controller is formulated in polar coordinates and ensures convergence to predefined waypoints. Local asymptotic stability of the closed-loop kinematic system is established via Lyapunov analysis. The dynamic layer uses model inversion based on a simplified three-degree-of-freedom model structured according to Fossen's canonical formulation. Control efforts are mapped into actuator-level commands consistent with the vehicle's propulsion layout. The proposed strategy is validated both on a physical prototype, IAcquaBot, and in IAcquaBotSim, a digital model of the real platform implemented in a virtual simulation environment. Experimental and simulated results confirm the effectiveness of the control scheme in achieving accurate and stable waypoint tracking.

Idioma original	Inglés
Título de la publicación alojada	2025 IEEE International Conference on Advanced Robotics, ICAR 2025
Editorial	Institute of Electrical and Electronics Engineers Inc.
Páginas	438-443
Número de páginas	6
ISBN (versión digital)	9798331578091
DOI	https://doi.org/10.1109/ICAR65334.2025.11338629
Estado	Publicada - 2025
Evento	2025 IEEE International Conference on Advanced Robotics, ICAR 2025 - San Juan, Argentina Duración: 2 dic. 2025 → 5 dic. 2025

Serie de la publicación

Nombre	2025 IEEE International Conference on Advanced Robotics, ICAR 2025

Conferencia

Conferencia	2025 IEEE International Conference on Advanced Robotics, ICAR 2025
País/Territorio	Argentina
Ciudad	San Juan
Período	2/12/25 → 5/12/25

Nota bibliográfica

Publisher Copyright:
© 2025 IEEE.

Acceder al documento

10.1109/ICAR65334.2025.11338629

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Enlace a la publicación en Scopus

Citar esto

Saldarriaga, B., Gimenez-Valenzuela, R., Montesdeoca, J., Roberti, F., & Toibero, M. (2025). Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV. En 2025 IEEE International Conference on Advanced Robotics, ICAR 2025 (pp. 438-443). (2025 IEEE International Conference on Advanced Robotics, ICAR 2025). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ICAR65334.2025.11338629

Saldarriaga, Brayan ; Gimenez-Valenzuela, Rodrigo ; Montesdeoca, Julio et al. / Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV. 2025 IEEE International Conference on Advanced Robotics, ICAR 2025. Institute of Electrical and Electronics Engineers Inc., 2025. pp. 438-443 (2025 IEEE International Conference on Advanced Robotics, ICAR 2025).

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title = "Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV",

abstract = "This work presents a hierarchical control strategy for a differential-thrust Unmanned Surface Vehicle, integrating a polar Line of Sight guidance law with a dynamic feedback compensation layer. The kinematic controller is formulated in polar coordinates and ensures convergence to predefined waypoints. Local asymptotic stability of the closed-loop kinematic system is established via Lyapunov analysis. The dynamic layer uses model inversion based on a simplified three-degree-of-freedom model structured according to Fossen's canonical formulation. Control efforts are mapped into actuator-level commands consistent with the vehicle's propulsion layout. The proposed strategy is validated both on a physical prototype, IAcquaBot, and in IAcquaBotSim, a digital model of the real platform implemented in a virtual simulation environment. Experimental and simulated results confirm the effectiveness of the control scheme in achieving accurate and stable waypoint tracking.",

author = "Brayan Saldarriaga and Rodrigo Gimenez-Valenzuela and Julio Montesdeoca and Flavio Roberti and Marcos Toibero",

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Saldarriaga, B, Gimenez-Valenzuela, R, Montesdeoca, J, Roberti, F & Toibero, M 2025, Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV. En 2025 IEEE International Conference on Advanced Robotics, ICAR 2025. 2025 IEEE International Conference on Advanced Robotics, ICAR 2025, Institute of Electrical and Electronics Engineers Inc., pp. 438-443, 2025 IEEE International Conference on Advanced Robotics, ICAR 2025, San Juan, Argentina, 2/12/25. https://doi.org/10.1109/ICAR65334.2025.11338629

Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV. / Saldarriaga, Brayan; Gimenez-Valenzuela, Rodrigo; Montesdeoca, Julio et al.
2025 IEEE International Conference on Advanced Robotics, ICAR 2025. Institute of Electrical and Electronics Engineers Inc., 2025. p. 438-443 (2025 IEEE International Conference on Advanced Robotics, ICAR 2025).

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución de conferencia › revisión exhaustiva

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T1 - Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV

AU - Saldarriaga, Brayan

AU - Gimenez-Valenzuela, Rodrigo

AU - Montesdeoca, Julio

AU - Roberti, Flavio

AU - Toibero, Marcos

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N2 - This work presents a hierarchical control strategy for a differential-thrust Unmanned Surface Vehicle, integrating a polar Line of Sight guidance law with a dynamic feedback compensation layer. The kinematic controller is formulated in polar coordinates and ensures convergence to predefined waypoints. Local asymptotic stability of the closed-loop kinematic system is established via Lyapunov analysis. The dynamic layer uses model inversion based on a simplified three-degree-of-freedom model structured according to Fossen's canonical formulation. Control efforts are mapped into actuator-level commands consistent with the vehicle's propulsion layout. The proposed strategy is validated both on a physical prototype, IAcquaBot, and in IAcquaBotSim, a digital model of the real platform implemented in a virtual simulation environment. Experimental and simulated results confirm the effectiveness of the control scheme in achieving accurate and stable waypoint tracking.

AB - This work presents a hierarchical control strategy for a differential-thrust Unmanned Surface Vehicle, integrating a polar Line of Sight guidance law with a dynamic feedback compensation layer. The kinematic controller is formulated in polar coordinates and ensures convergence to predefined waypoints. Local asymptotic stability of the closed-loop kinematic system is established via Lyapunov analysis. The dynamic layer uses model inversion based on a simplified three-degree-of-freedom model structured according to Fossen's canonical formulation. Control efforts are mapped into actuator-level commands consistent with the vehicle's propulsion layout. The proposed strategy is validated both on a physical prototype, IAcquaBot, and in IAcquaBotSim, a digital model of the real platform implemented in a virtual simulation environment. Experimental and simulated results confirm the effectiveness of the control scheme in achieving accurate and stable waypoint tracking.

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Saldarriaga B, Gimenez-Valenzuela R, Montesdeoca J, Roberti F, Toibero M. Hierarchical LOS-Based Control in Polar Coordinates with Dynamic Feedback Compensation for a Differential USV. En 2025 IEEE International Conference on Advanced Robotics, ICAR 2025. Institute of Electrical and Electronics Engineers Inc. 2025. p. 438-443. (2025 IEEE International Conference on Advanced Robotics, ICAR 2025). doi: 10.1109/ICAR65334.2025.11338629