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Education and Information Technologies

, Volume 24, Issue 6, pp 3591–3618 | Cite as

A predictive approach based on efficient feature selection and learning algorithms’ competition: Case of learners’ dropout in MOOCs

  • Mourdi YoussefEmail author
  • Sadgal Mohammed
  • El Kabtane Hamada
  • Berrada Fathi Wafaa
Article
  • 83 Downloads

Abstract

MOOCs are becoming more and more involved in the pedagogical experimentation of universities whose infrastructure does not respond to the growing mass of learners. These universities aim to complete their initial training with distance learning courses. Unfortunately, the efforts made to succeed in this pedagogical model are facing a dropout rate of enrolled learners reaching 90% in some cases. This makes the coaching, the group formation of learners, and the instructor/learner interaction challenging. It is within this context that this research aims to propose a predictive model allowing to classify the MOOCs learners into three classes: the learners at risk of dropping out, those who are likely to fail and those who are on the road to success. An automatic determination of relevant attributes for analysis, classification, interpretation and prediction from MOOC learners data, will allow instructors to streamline interventions for each class. To meet this purpose, we present an approach based on feature selection methods and ensemble machine learning algorithms. The proposed model was tested on a dataset of over 5,500 learners in two Stanford University MOOCs courses. In order to attest its performance (98.6%), a comparison was carried out based on several performance measures.

Keywords

Dropout Distance education Feature selection Algorithms competition Educational datamining MOOC 

Notes

Acknowledgements

This research was done through Stanford University’s Advanced Research Center on Online Learning (CAROL), which we thank immensely for all the facilities they provided for us. We also wish to express our full gratitude to Ms. Kathy Mirzaei for her responsiveness as well as her collaboration. We wish to warmly thank Mr. Mitchell Stevens, Director of Digital Research and Planning, as well as all the CAROL commission for the trust they have given us.

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Copyright information

© Springer Science+Business Media, LLC, part of Springer Nature 2019

Authors and Affiliations

  1. 1.Computer Science DepartementCADI AYYAD UniversityMarrakechMorocco

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