利用 LMI 进行数据高效的二次 Q 学习

arXiv - EE - Systems and Control Pub Date : 2024-09-18 DOI:arxiv-2409.11986

J. S. van Hulst, W. P. M. H. Heemels, D. J. Antunes

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引用次数: 0

摘要

强化学习（RL）的研究和应用成果显著，但往往需要大量的训练数据。本文提出了两种数据高效的非策略 RL 方法，它们使用参数化 Q 学习。在这些方法中，Q 函数被选择为在参数中是线性的，而在状态和控制偏离基本策略的选定基函数中是二次型的。对贝尔曼误差（Bellman errors）的$\ell_1$正态进行惩罚的成本最小化。我们提出了两种方法：线性矩阵不等式 Q 学习（LMI-QL）及其迭代变体（LMI-QLi），通过凸优化解决由此产生的偶发优化问题。LMI-QL 依靠的是一种凸松弛，它产生了一个带有线性矩阵不等式（LMI）的半定量编程（SDP）问题。LMI-QLi 需要求解一个 SDP 问题的连续迭代。这两种方法都将凸优化与直接 Q 函数学习相结合，大大提高了学习速度。一项数值案例研究证明了它们与现有参数化 Q-learning 方法相比的优势。

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Data-Efficient Quadratic Q-Learning Using LMIs

Reinforcement learning (RL) has seen significant research and application results but often requires large amounts of training data. This paper proposes two data-efficient off-policy RL methods that use parametrized Q-learning. In these methods, the Q-function is chosen to be linear in the parameters and quadratic in selected basis functions in the state and control deviations from a base policy. A cost penalizing the $\ell_1$-norm of Bellman errors is minimized. We propose two methods: Linear Matrix Inequality Q-Learning (LMI-QL) and its iterative variant (LMI-QLi), which solve the resulting episodic optimization problem through convex optimization. LMI-QL relies on a convex relaxation that yields a semidefinite programming (SDP) problem with linear matrix inequalities (LMIs). LMI-QLi entails solving sequential iterations of an SDP problem. Both methods combine convex optimization with direct Q-function learning, significantly improving learning speed. A numerical case study demonstrates their advantages over existing parametrized Q-learning methods.

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arXiv - EE - Systems and Control

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