Litcius/Paper detail

GeoDRL: A Self-Learning Framework for Geometry Problem Solving using Reinforcement Learning in Deductive Reasoning

Shuai Peng, Di Fu, Yijun Liang, Liangcai Gao, Zhi Wei Tang

202315 citationsDOIOpen Access PDF

Abstract

Ensuring both interpretability and correctness is a great challenge in automated geometry problem solving (GPS), and the scarcity of labeled data hinders learning mathematical reasoning from samples. Therefore, we present GeoDRL, a self-learning geometry problem solving framework that integrates logic graph deduction and Deep Reinforcement Learning (DRL) to optimize geometry reasoning as a Markov Decision Process. GeoDRL employs a Graph Neural Network on a Geometry Logic Graph, updating the problem state using a symbolic system. Incorporating DRL into deductive reasoning enables GeoDRL to achieve unsupervised self-learning while maintaining correctness. GeoDRL, through unsupervised learning, exhibits enhanced accuracy in the Geometry3K dataset, improving by 11.1% over previous SOTA methods, and simultaneously boosts efficiency and interpretability.

Topics & Concepts

InterpretabilityCorrectnessComputer scienceArtificial intelligenceReinforcement learningGraphMachine learningTheoretical computer scienceAlgorithmIntelligent Tutoring Systems and Adaptive LearningAI-based Problem Solving and Planning
GeoDRL: A Self-Learning Framework for Geometry Problem Solving using Reinforcement Learning in Deductive Reasoning | Litcius