集体接地:应用数据库技术接地模板模型

Eriq Augustine, L. Getoor
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引用次数: 0

摘要

一阶模型的实例化或“接地”过程是逻辑推理的基本组成部分。它已经在定理证明、数据库理论和人工智能的背景下被广泛研究。在关系学习社区中,基础的概念已经扩展到使用更通用的模板来代替一阶逻辑公式的模型。为了执行推理,需要这些模板的基础来实例化可能世界上的分布。然而,由于使用相互关联的数据实例化通用模板产生了复杂的数据依赖性,因此接地通常是关系学习的关键计算瓶颈。当我们在关系学习的背景下激励我们的工作时,在概率数据库中也出现了类似的问题,特别是那些没有做出强元组独立性假设的数据库。在本文中,我们研究了如何利用关系数据库理论中的关键技术来提高接地过程的计算效率。我们引入了集体基础的概念,它不是将逻辑程序视为独立规则的集合,而是将其视为可以共享的相互依赖的工作负载的联合集合。我们介绍了集体接地的理论概念、集体接地系统中必要的组件、这些组件的实现,并展示了如何使用数据库理论来加快这些组件的速度。我们在七个流行的数据集上展示了集体接地的有效性,并显示使用集体接地可以减少70%的运行时间。我们的结果是完全可重复的,所有的代码、数据和实验脚本都包括在内。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Collective Grounding: Applying Database Techniques to Grounding Templated Models
The process of instantiating, or "grounding", a first-order model is a fundamental component of reasoning in logic. It has been widely studied in the context of theorem proving, database theory, and artificial intelligence. Within the relational learning community, the concept of grounding has been expanded to apply to models that use more general templates in the place of first-order logical formulae. In order to perform inference, grounding of these templates is required for instantiating a distribution over possible worlds. However, because of the complex data dependencies stemming from instantiating generalized templates with interconnected data, grounding is often the key computational bottleneck to relational learning. While we motivate our work in the context of relational learning, similar issues arise in probabilistic databases, particularly those that do not make strong tuple independence assumptions. In this paper, we investigate how key techniques from relational database theory can be utilized to improve the computational efficiency of the grounding process. We introduce the notion of collective grounding which treats logical programs not as a collection of independent rules, but instead as a joint set of interdependent workloads that can be shared. We introduce the theoretical concept of collective grounding, the components necessary in a collective grounding system, implementations of these components, and show how to use database theory to speed up these components. We demonstrate collective groundings effectiveness on seven popular datasets, and show up to a 70% reduction in runtime using collective grounding. Our results are fully reproducible and all code, data, and experimental scripts are included.
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