Symbolic Reasoning in Latent Space: Classical Planning as an Example

Neuro-Symbolic Artificial Intelligence Pub Date : 2021-12-22 DOI:10.3233/faia210349

Masataro Asai, Hiroshi Kajino, A. Fukunaga, Christian Muise

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Abstract

Symbolic systems require hand-coded symbolic representation as input, resulting in a knowledge acquisition bottleneck. Meanwhile, although deep learning has achieved significant success in many fields, the knowledge is encoded in a subsymbolic representation which is incompatible with symbolic systems. To address the gap between the two fields, one has to solve Symbol Grounding problem: The question of how a machine can generate symbols automatically. We discuss our recent work called Latplan, an unsupervised architecture combining deep learning and classical planning. Given only an unlabeled set of image pairs showing a subset of transitions allowed in the environment (training inputs), Latplan learns a complete propositional PDDL action model of the environment. Later, when a pair of images representing the initial and the goal states (planning inputs) is given, Latplan finds a plan to the goal state in a symbolic latent space and returns a visualized plan execution. We discuss several key ideas that made Latplan possible which would hopefully extend to many other symbolic paradigms outside classical planning.

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潜在空间中的符号推理:以经典规划为例

符号系统需要手工编码的符号表示作为输入，导致知识获取的瓶颈。与此同时，尽管深度学习在许多领域取得了显著的成功，但知识被编码为与符号系统不兼容的子符号表示。为了解决这两个领域之间的差距，人们必须解决符号接地问题:机器如何自动生成符号的问题。我们讨论了我们最近的作品Latplan，这是一个结合了深度学习和经典规划的无监督建筑。给定一组未标记的图像对，显示环境中允许的过渡子集(训练输入)，Latplan学习环境的完整命题PDDL动作模型。然后，当给定一对表示初始状态和目标状态的图像(规划输入)时，Latplan在符号潜在空间中找到一个到目标状态的计划，并返回一个可视化的计划执行。我们讨论了使拉丁规划成为可能的几个关键思想，这些思想有望扩展到经典规划之外的许多其他符号范式。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Neuro-Symbolic Artificial Intelligence

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