A comparative study of methods for a priori prediction of MCQ difficulty-Reference-Cited by-同舟云学术

A comparative study of methods for a priori prediction of MCQ difficulty

Published:2021-03-09 Issue:3 Volume:12 Page:449-465
ISSN:2210-4968
Container-title:Semantic Web
language:
Short-container-title:SW

Author:

Kurdi Ghader¹,Leo Jared¹,Matentzoglu Nicolas¹,Parsia Bijan¹,Sattler Uli¹,Forge Sophie²,Donato Gina²,Dowling Will²

Affiliation:

1. Department of Computer Science, The University of Manchester, Oxford Road, Manchester, M139PL, UK

2. Elsevier, 1600 John F. Kennedy Boulevard, Philadelphia, PA 19103, USA

Abstract

Successful exams require a balance of easy, medium, and difficult questions. Question difficulty is generally either estimated by an expert or determined after an exam is taken. The latter provides no utility for the generation of new questions and the former is expensive both in terms of time and cost. Additionally, it is not known whether expert prediction is indeed a good proxy for estimating question difficulty. In this paper, we analyse and compare two ontology-based measures for difficulty prediction of multiple choice questions, as well as comparing each measure with expert prediction (by 15 experts) against the exam performance of 12 residents over a corpus of 231 medical case-based questions that are in multiple choice format. We find one ontology-based measure (relation strength indicativeness) to be of comparable performance (accuracy = 47%) to expert prediction (average accuracy = 49%).

Publisher

IOS Press

Subject

Computer Networks and Communications,Computer Science Applications,Information Systems

Reference49 articles.

1. Automatic generation of multiple choice questions using surface-based semantic relations;Afzal;International Journal of Computational Linguistics (IJCL),2015

2. M. Al-Yahya, Ontology-based multiple choice question generation, The Scientific World Journal 2014 (2014).

3. T. Alsubait, B. Parsia and U. Sattler, Generating multiple choice questions from ontologies: Lessons learnt, in: OWLED, 2014, pp. 73–84.

4. Rubrics for assessment item difficulty in engineering courses

5. B.S. Bloom, M.D. Engelhart, E.J. Furst, W.H. Hill and D.R. Krathwohl, Taxonomy of Educational Objectives, Handbook I: The Cognitive Domain, Vol. 19, David McKay Co Inc, New York, 1956.

Cited by 5 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Novel Feature-Based Difficulty Prediction Method for Mathematics Items Using XGBoost-Based SHAP Model;Mathematics;2024-05-08

2. Comparing Estimated and Real Item Difficulty Using Multi-Facet Rasch Analysis;Eğitimde ve Psikolojide Ölçme ve Değerlendirme Dergisi;2023-12-31

3. Text-based Question Difficulty Prediction: A Systematic Review of Automatic Approaches;International Journal of Artificial Intelligence in Education;2023-09-08

4. Multiple-Choice Questions Difficulty Prediction with Neural Networks;Methodologies and Intelligent Systems for Technology Enhanced Learning, 13th International Conference;2023

5. Supporting contextualized learning with linked open data;Journal of Web Semantics;2021-07