A data-driven approach builds local exponentially input-to-state stabilizing controllers from noisy data per subsystem and composes them via small-gain conditions to achieve uniform global exponential stability for infinite LTI networks.
Data-Driven Global Stabilization of Unknown Infinite Networks
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abstract
This paper develops a direct data-driven framework for infinite networks with unknown nonlinear polynomial subsystems, enabling the synthesis of controllers that ensure the entire network is uniformly globally asymptotically stable (UGAS). To address scalability challenges arising from high dimensionality, we develop a data-driven approach to construct an input-to-state stable (ISS) Lyapunov function and its corresponding controller for each unknown subsystem using only a single set of noise-corrupted input-state trajectories collected from that subsystem. Once each subsystem admits a data-driven ISS Lyapunov function, we leverage a compositional small-gain framework for infinite-dimensional spaces to construct a global control Lyapunov function and its associated controller, thereby ensuring UGAS of the entire infinite network. The effectiveness of the proposed data-driven approach is demonstrated through three case studies, including infinite networks of spacecraft, Lorenz chaotic systems, and an academic example with a state-dependent control input matrix.
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2026 1verdicts
UNVERDICTED 1representative citing papers
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Data-Driven Stabilizing Controller Design for Linear Infinite Networks
A data-driven approach builds local exponentially input-to-state stabilizing controllers from noisy data per subsystem and composes them via small-gain conditions to achieve uniform global exponential stability for infinite LTI networks.