Actuators

27 pages, 1073 KiB

Open AccessArticle

Variable Structure Depth Controller for Energy Savings in an Underwater Device: Proof of Stability

by João Bravo Pinto, João Falcão Carneiro, Fernando Gomes de Almeida and Nuno A. Cruz

Actuators 2025, 14(7), 340; https://doi.org/10.3390/act14070340 - 8 Jul 2025

Underwater exploration is vital for advancing scientific understanding of marine ecosystems, biodiversity, and oceanic processes. Autonomous underwater vehicles and sensor platforms play a crucial role in continuous monitoring, but their operational endurance is often limited by energy constraints. Various control strategies have been [...] Read more.

Underwater exploration is vital for advancing scientific understanding of marine ecosystems, biodiversity, and oceanic processes. Autonomous underwater vehicles and sensor platforms play a crucial role in continuous monitoring, but their operational endurance is often limited by energy constraints. Various control strategies have been proposed to enhance energy efficiency, including robust and optimal controllers, energy-optimal model predictive control, and disturbance-aware strategies. Recent work introduced a variable structure depth controller for a sensor platform with a variable buoyancy module, resulting in a 22% reduction in energy consumption. This paper extends that work by providing a formal stability proof for the proposed switching controller, ensuring safe and reliable operation in dynamic underwater environments. In contrast to the conventional approach used in controller stability proofs for switched systems—which typically relies on the existence of multiple Lyapunov functions—the method developed in this paper adopts a different strategy. Specifically, the stability proof is based on a novel analysis of the system’s trajectory in the net buoyancy force-versus-depth error plane. The findings were applied to a depth-controlled sensor platform previously developed by the authors, using a well-established system model and considering physical constraints. Despite adopting a conservative approach, the results demonstrate that the control law can be implemented while ensuring formal system stability. Moreover, the study highlights how stability regions are affected by different controller parameter choices and mission requirements, namely, by determining how these aspects affect the bounds of the switching control action. The results provide valuable guidance for selecting the appropriate controller parameters for specific mission scenarios. Full article

(This article belongs to the Special Issue Advanced Underwater Robotics)

20 pages, 23737 KiB

Open AccessArticle

Distributed Adaptive Angle Rigidity-Based Formation Control of Near-Space Vehicles with Input Constraints

by Qin Wang, Yuhang Shen, Hanyu Yin, Jianjiang Yu and Yang Yi

Actuators 2025, 14(7), 339; https://doi.org/10.3390/act14070339 - 8 Jul 2025

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