通过学习提升稳定非线性系统的性能

Luca Furieri;Clara Lucía Galimberti;Giancarlo Ferrari-Trecate
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引用次数: 0

摘要

安全关键型控制系统的规模和复杂性不断增加,这凸显了发展当前控制架构的必要性,其目标是通过最先进的优化和机器学习算法实现无与伦比的性能。然而,在利用数据驱动和深度学习方法提高非线性控制系统性能的同时保持闭环稳定性是一项尚未解决的重要挑战。在本文中,我们将在保证闭环稳定性的前提下解决性能提升问题。具体来说,我们在非线性系统的内部模型控制(IMC)原理和最先进的无约束优化方法之间建立了协同作用,以学习稳定的动力学。我们的方法可以学习特定类别的深度神经网络性能提升控制器,用于稳定的非线性系统;重要的是,即使优化过早停止,我们也能保证 $\mathcal {L}_{p}$ 闭环稳定性。当地面真实动态不确定时,我们会学习鲁棒稳定控制策略。我们的鲁棒性结果是严密的,即随着模型失配算子的 $\mathcal {L}_{p}$ -gain 降为零,所有稳定策略都会恢复。我们讨论了所提控制方案(包括分布式方案)的实施细节以及相应的优化程序,并通过几个数值实验展示了自由塑造成本函数的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Learning to Boost the Performance of Stable Nonlinear Systems
The growing scale and complexity of safety-critical control systems underscore the need to evolve current control architectures aiming for the unparalleled performances achievable through state-of-the-art optimization and machine learning algorithms. However, maintaining closed-loop stability while boosting the performance of nonlinear control systems using data-driven and deep-learning approaches stands as an important unsolved challenge. In this paper, we tackle the performance-boosting problem with closed-loop stability guarantees. Specifically, we establish a synergy between the Internal Model Control (IMC) principle for nonlinear systems and state-of-the-art unconstrained optimization approaches for learning stable dynamics. Our methods enable learning over specific classes of deep neural network performance-boosting controllers for stable nonlinear systems; crucially, we guarantee $\mathcal {L}_{p}$ closed-loop stability even if optimization is halted prematurely. When the ground-truth dynamics are uncertain, we learn over robustly stabilizing control policies. Our robustness result is tight, in the sense that all stabilizing policies are recovered as the $\mathcal {L}_{p}$ -gain of the model mismatch operator is reduced to zero. We discuss the implementation details of the proposed control schemes, including distributed ones, along with the corresponding optimization procedures, demonstrating the potential of freely shaping the cost functions through several numerical experiments.
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