Explainable AI for Workflow Verification in VIPLE

人工智能技术学报(英文) Pub Date : 2020-12-28 DOI:10.37965/jait.2020.0023

G. Luca, Yinong Chen

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引用次数: 1

Abstract

Teaching students the concepts behind computational thinking is a difficult task, often gated by the inherent difficulty of programming languages. In the classroom, teaching assistants may be required to interact with students to help them learn the material. Time spent in grading and offering feedback on assignments removes from this time to help students directly. As such, we offer a framework for developing an explainable Artificial Intelligence that performs automated analysis of student code while offering feedback and partial credit. The creation of this system is dependent on three core components. Those components are a knowledge base, a set of conditions to be analyzed, and a formal set of inference rules. In this paper, we develop such a system for our own language by employing Pi-Calculus and Hoare Logic. Our detailed system can also perform self-learning of rules. Given solution files, the system is able to extract the important aspects of the program and develop feedback that explicitly details the errors students make when they veer away from these aspects. The level of detail and expected precision can be easily modified through parameter tuning and variety in sample solutions.

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VIPLE中用于工作流验证的可解释人工智能

教学生计算思维背后的概念是一项艰巨的任务，通常受到编程语言固有难度的限制。在课堂上，可能需要助教与学生互动，帮助他们学习材料。花在评分和提供作业反馈上的时间从直接帮助学生的时间中删除。因此，我们提供了一个开发可解释人工智能的框架，该框架可以对学生代码进行自动分析，同时提供反馈和部分学分。这个系统的建立取决于三个核心组成部分。这些组成部分是一个知识库、一组要分析的条件和一组正式的推理规则。在本文中，我们利用圆周率演算和霍尔逻辑为我们自己的语言开发了这样一个系统。我们的详细系统还可以进行规则的自学习。给定解决方案文件，系统能够提取程序的重要方面，并开发反馈，明确详细说明学生在偏离这些方面时所犯的错误。通过参数调整和样本解决方案的多样性，可以很容易地修改细节级别和预期精度。

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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来源期刊

人工智能技术学报(英文)

CiteScore

8.70

自引率

0.00%

发文量