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Interpretable MOOC dropout prediction using different Ensemble Methods and XAI

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Abstract

Massive open online course (MOOC) has been around for a while, but started to gain traction since 2012 when Coursera was established. MOOCs use pre-recorded lectures and scheduled weekly tests to provide content and access to students over the internet. Even though there was a high expectation that it would revolutionize the education system, due to the mode of one-way content delivery, the goal was too far-fetched. The flexibility in deadlines and no restrictions of classroom exams meant students were not bound to finish on time. Hence, most students did not finish the course and dropped out. The dataset used in our research was the KDDCUP 2015 dataset, which was publicly available by the organizers of XuetangX platform. We used about 12 features namely browser access, navigate, average chapter delays, server sequential etc to comprehend the possibility of dropout. In this paper, we aim to predict dropout of a learner so that it can be prevented through manual interaction. Additionally, we have implemented XAI to interpret our models to suggest MOOC platforms which feature impact dropout the most. We used different ensemble learning techniques, namely voting classifier and stacking. Our voting classifier uses five of our best performing machine learning models. Then we evaluate the model by using multiple metrics such as precision, recall, F1-score, ROC curve and AUC score. Finally, we managed to obtain a recall of 97.636% with stacking and f1-score of 91.603% with hard voting classifier.

Description

Cataloged from PDF version of thesis.
Includes bibliographical references (pages 53-55).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2023.

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Thesis