PAC statistical model checking of mean payoff in discrete- and continuous-time MDP

IF 0.7 4区计算机科学 Q3 COMPUTER SCIENCE, THEORY & METHODS Formal Methods in System Design Pub Date : 2024-08-17 DOI:10.1007/s10703-024-00463-0

Chaitanya Agarwal, Shibashis Guha, Jan Křetínský, M. Pazhamalai

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Abstract

Markov decision processes (MDPs) and continuous-time MDP (CTMDPs) are the fundamental models for non-deterministic systems with probabilistic uncertainty. Mean payoff (a.k.a. long-run average reward) is one of the most classic objectives considered in their context. We provide the first practical algorithm to compute mean payoff probably approximately correctly in unknown MDPs. Our algorithm is anytime in the sense that if terminated prematurely, it returns an approximate value with the required confidence. Further, we extend it to unknown CTMDPs. We do not require any knowledge of the state or number of successors of a state, but only a lower bound on the minimum transition probability, which has been advocated in literature. Our algorithm learns the unknown MDP/CTMDP through repeated, directed sampling; thus spending less time on learning components with smaller impact on the mean payoff. In addition to providing probably approximately correct (PAC) bounds for our algorithm, we also demonstrate its practical nature by running experiments on standard benchmarks.

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离散和连续时间 MDP 平均报酬的 PAC 统计模型检查

马尔可夫决策过程（MDP）和连续时间 MDP（CTMDP）是具有概率不确定性的非确定系统的基本模型。平均报酬率（又称长期平均报酬率）是这两种模型中最经典的目标之一。我们提供了第一种实用算法，可以在未知 MDP 中近似正确地计算平均报酬。我们的算法具有随时性，即使过早终止，它也能返回具有所需置信度的近似值。此外，我们还将其扩展到未知 CTMDP。我们不需要任何关于状态或状态后继数的知识，只需要最小过渡概率的下限，这在文献中已经得到提倡。我们的算法通过重复的定向采样来学习未知的 MDP/CTMDP，因此在学习对平均报酬影响较小的部分上花费的时间较少。除了为我们的算法提供可能近似正确（PAC）的界限外，我们还通过在标准基准上运行实验来证明它的实用性。

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来源期刊

Formal Methods in System Design 工程技术-计算机：理论方法

CiteScore

2.00

自引率

12.50%

发文量

审稿时长

>12 weeks

期刊介绍： The focus of this journal is on formal methods for designing, implementing, and validating the correctness of hardware (VLSI) and software systems. The stimulus for starting a journal with this goal came from both academia and industry. In both areas, interest in the use of formal methods has increased rapidly during the past few years. The enormous cost and time required to validate new designs has led to the realization that more powerful techniques must be developed. A number of techniques and tools are currently being devised for improving the reliability, and robustness of complex hardware and software systems. While the boundary between the (sub)components of a system that are cast in hardware, firmware, or software continues to blur, the relevant design disciplines and formal methods are maturing rapidly. Consequently, an important (and useful) collection of commonly applicable formal methods are expected to emerge that will strongly influence future design environments and design methods.

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