透视规划-使用功能条分解认知规划

IF 4.5 3区 计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Journal of Artificial Intelligence Research Pub Date : 2022-10-16 DOI:10.1613/jair.1.13446
Guanghua Hu, Tim Miller, N. Lipovetzky
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引用次数: 3

摘要

在本文中,我们提出了一种新的认知规划方法,称为透视规划(PWP),它比现有的最先进的认知规划工具更具表现力和计算效率。认知规划——基于知识和信念的规划——在许多多智能体和人-智能体交互领域是必不可少的。大多数最先进的知识规划者通过编译命题经典规划(例如,生成所有可能的知识原子或编译知识公式为标准形式)来解决知识规划问题;或者显式编码基于kripke的语义。然而,随着问题规模的增长,这些方法在计算上变得不可行。在本文中,我们通过将关于认知公式的推理委托给外部求解器来分解认知规划。我们通过使用Functional STRIPS对问题建模来做到这一点,它比标准strip更具表现力,并支持在操作模型中使用外部的黑盒函数。基于最近的工作,展示了智能体“看到”和它所知道的之间的关系,我们使用外部函数定义了每个智能体的视角,并围绕此构建了一个认知逻辑的求解器。建模者可以自定义代理的透视图功能,允许在不更改规划器的情况下定义新的认知逻辑。我们对众所周知的认知规划基准进行了评估,以比较现有的最先进的规划,并对展示PWP方法的表达能力的新场景进行了评估。结果表明,我们的PWP规划器的可伸缩性明显优于我们所比较的最先进的规划器,并且可以更简洁地表达问题。
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Planning with Perspectives - Decomposing Epistemic Planning using Functional STRIPS
In this paper, we present a novel approach to epistemic planning called planning with perspectives (PWP) that is both more expressive and computationally more efficient than existing state-of-the-art epistemic planning tools. Epistemic planning — planning with knowledge and belief — is essential in many multi-agent and human-agent interaction domains. Most state-of-the-art epistemic planners solve epistemic planning problems by either compiling to propositional classical planning (for example, generating all possible knowledge atoms or compiling epistemic formulae to normal forms); or explicitly encoding Kripke-based semantics. However, these methods become computationally infeasible as problem sizes grow. In this paper, we decompose epistemic planning by delegating reasoning about epistemic formulae to an external solver. We do this by modelling the problem using Functional STRIPS, which is more expressive than standard STRIPS and supports the use of external, black-box functions within action models. Building on recent work that demonstrates the relationship between what an agent ‘sees’ and what it knows, we define the perspective of each agent using an external function, and build a solver for epistemic logic around this. Modellers can customise the perspective function of agents, allowing new epistemic logics to be defined without changing the planner. We ran evaluations on well-known epistemic planning benchmarks to compare an existing state-of-the-art planner, and on new scenarios that demonstrate the expressiveness of the PWP approach. The results show that our PWP planner scales significantly better than the state-of-the-art planner that we compared against, and can express problems more succinctly.
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来源期刊
Journal of Artificial Intelligence Research
Journal of Artificial Intelligence Research 工程技术-计算机:人工智能
CiteScore
9.60
自引率
4.00%
发文量
98
审稿时长
4 months
期刊介绍: JAIR(ISSN 1076 - 9757) covers all areas of artificial intelligence (AI), publishing refereed research articles, survey articles, and technical notes. Established in 1993 as one of the first electronic scientific journals, JAIR is indexed by INSPEC, Science Citation Index, and MathSciNet. JAIR reviews papers within approximately three months of submission and publishes accepted articles on the internet immediately upon receiving the final versions. JAIR articles are published for free distribution on the internet by the AI Access Foundation, and for purchase in bound volumes by AAAI Press.
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