Koopman operator theory is receiving increased attention due to its promise to linearize nonlinear dynamics. Neural networks that are developed to represent Koopman operators have shown great success thanks to their ability to approximate arbitrarily complex functions. However, despite their great potential, they typically require large training data-sets either from measurements of a real system or from high-fidelity simulations. In this work, we propose a novel architecture inspired by physics-informed neural networks, which leverage automatic differentiation to impose the underlying physical laws via soft penalty constraints during model training. We demonstrate that it not only reduces the need of large training data-sets, but also maintains high effectiveness in approximating Koopman eigenfunctions.
翻译:Koopman操作员理论由于具有将非线性动态线性化的希望而日益受到重视。为代表Koopman操作员而开发的神经网络由于能够任意估计复杂功能而取得了巨大成功。然而,尽管这些网络具有巨大潜力,但它们通常需要从实际系统测量或高忠度模拟中获取大量培训数据集。在这项工作中,我们提议了一个由物理知情神经网络启发的新结构,通过在示范培训期间软性惩罚限制,利用自动差异来实施基本物理法律。我们证明,这不仅减少了对大型培训数据集的需求,而且还保持了对约合Koopman机能的高度有效性。
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