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Researchers co-learn physics-informed AI models and controllers for energy-shaping systems

By PulseAugur Editorial · Summary by gemini-2.5-flash-lite from 2 sources

Researchers have developed a new physics-informed learning framework designed to improve energy-shaping control for port-Hamiltonian systems. This framework simultaneously learns a system model and an optimal energy-balancing controller using trajectory data and alternating optimization. The approach utilizes neural networks to embed system dynamics and controller structure, ensuring interpretability and provable stability for the closed-loop system. AI

Summary written by gemini-2.5-flash-lite from 2 sources. How we write summaries →

IMPACT Introduces a novel physics-informed learning approach for control systems, potentially enhancing robustness and stability in real-world applications.

RANK_REASON This is a research paper detailing a new physics-informed learning framework for control systems.

Read on arXiv stat.ML →

COVERAGE [2]

  1. arXiv stat.ML TIER_1 · Ankur Kamboj, Biswadip Dey, Vaibhav Srivastava ·

    Co-Learning Port-Hamiltonian Systems and Optimal Energy-Shaping Control

    arXiv:2604.26172v1 Announce Type: cross Abstract: We develop a physics-informed learning framework for energy-shaping control of port-Hamiltonian (pH) systems from trajectory data. The proposed approach {co-learns} a pH system model and an optimal energy-balancing passivity-based…

  2. arXiv stat.ML TIER_1 · Vaibhav Srivastava ·

    Co-Learning Port-Hamiltonian Systems and Optimal Energy-Shaping Control

    We develop a physics-informed learning framework for energy-shaping control of port-Hamiltonian (pH) systems from trajectory data. The proposed approach {co-learns} a pH system model and an optimal energy-balancing passivity-based controller (EB-PBC) through alternating optimizat…

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