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Enhancing the Performance of Automated Grade Prediction in MOOC using Graph Representation Learning (2310.12281v1)

Published 18 Oct 2023 in cs.LG and cs.AI

Abstract: In recent years, Massive Open Online Courses (MOOCs) have gained significant traction as a rapidly growing phenomenon in online learning. Unlike traditional classrooms, MOOCs offer a unique opportunity to cater to a diverse audience from different backgrounds and geographical locations. Renowned universities and MOOC-specific providers, such as Coursera, offer MOOC courses on various subjects. Automated assessment tasks like grade and early dropout predictions are necessary due to the high enroLLMent and limited direct interaction between teachers and learners. However, current automated assessment approaches overlook the structural links between different entities involved in the downstream tasks, such as the students and courses. Our hypothesis suggests that these structural relationships, manifested through an interaction graph, contain valuable information that can enhance the performance of the task at hand. To validate this, we construct a unique knowledge graph for a large MOOC dataset, which will be publicly available to the research community. Furthermore, we utilize graph embedding techniques to extract latent structural information encoded in the interactions between entities in the dataset. These techniques do not require ground truth labels and can be utilized for various tasks. Finally, by combining entity-specific features, behavioral features, and extracted structural features, we enhance the performance of predictive machine learning models in student assignment grade prediction. Our experiments demonstrate that structural features can significantly improve the predictive performance of downstream assessment tasks. The code and data are available in \url{https://github.com/DSAatUSU/MOOPer_grade_prediction}

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References (39)
  1. G. Christensen, A. Steinmetz, B. Alcorn, A. Bennett, D. Woods, and E. Emanuel, “The mooc phenomenon: Who takes massive open online courses and why?” Available at SSRN 2350964, 2013.
  2. T. Dillahunt, Z. Wang, and S. D. Teasley, “Democratizing higher education: Exploring mooc use among those who cannot afford a formal education,” International Review of Research in Open and Distributed Learning, vol. 15, no. 5, pp. 177–196, 2014.
  3. E. Ossiannilsson, “Moocs for lifelong learning, equity, and liberation,” MOOC (Massive Open Online Courses), 2021.
  4. S. Papadakis, “Moocs 2012-2022: An overview,” Advances in Mobile Learning Educational Research, vol. 3, no. 1, pp. 682–693, 2023.
  5. N. M. Castillo, J. Lee, F. T. Zahra, and D. A. Wagner, “Moocs for development: Trends, challenges, and opportunities,” International Technologies & International Development, vol. 11, no. 2, p. 35, 2015.
  6. T. Daradoumis, R. Bassi, F. Xhafa, and S. Caballé, “A review on massive e-learning (mooc) design, delivery and assessment,” in 2013 eighth international conference on P2P, parallel, grid, cloud and internet computing.   IEEE, 2013, pp. 208–213.
  7. A. McAuley, B. Stewart, G. Siemens, and D. Cormier, “The mooc model for digital practice,” 2010.
  8. L. Czerniewicz, A. Deacon, J. Small, and S. Walji, “Developing world moocs: A curriculum view of the mooc landscape,” 2014.
  9. Q. Qi, Y. Liu, F. Wu, X. Yan, and N. Wu, “Temporal models for personalized grade prediction in massive open online courses,” in Proceedings of ACM Turing Celebration Conference-China, 2018, pp. 67–72.
  10. J. Fan, Y. Jiang, Y. Liu, and Y. Zhou, “Interpretable mooc recommendation: a multi-attention network for personalized learning behavior analysis,” Internet Research, vol. 32, no. 2, pp. 588–605, 2022.
  11. T.-Y. Yang, C. G. Brinton, C. Joe-Wong, and M. Chiang, “Behavior-based grade prediction for moocs via time series neural networks,” IEEE Journal of Selected Topics in Signal Processing, vol. 11, no. 5, pp. 716–728, 2017.
  12. M. Adnan, A. Habib, J. Ashraf, S. Mussadiq, A. A. Raza, M. Abid, M. Bashir, and S. U. Khan, “Predicting at-risk students at different percentages of course length for early intervention using machine learning models,” Ieee Access, vol. 9, pp. 7519–7539, 2021.
  13. D. J. Lemay and T. Doleck, “Grade prediction of weekly assignments in moocs: mining video-viewing behavior,” Education and Information Technologies, vol. 25, pp. 1333–1342, 2020.
  14. P. G. de Barba, G. E. Kennedy, and M. D. Ainley, “The role of students’ motivation and participation in predicting performance in a mooc,” Journal of Computer Assisted Learning, vol. 32, no. 3, pp. 218–231, 2016.
  15. B. Xu and D. Yang, “Motivation classification and grade prediction for moocs learners,” Computational intelligence and neuroscience, vol. 2016, pp. 4–4, 2016.
  16. Z. Ren, H. Rangwala, and A. Johri, “Predicting performance on mooc assessments using multi-regression models,” arXiv preprint arXiv:1605.02269, 2016.
  17. Y. Chen and M. Zhang, “Mooc student dropout: Pattern and prevention,” in Proceedings of the ACM Turing 50th Celebration Conference-China, 2017, pp. 1–6.
  18. W. Xing and D. Du, “Dropout prediction in moocs: Using deep learning for personalized intervention,” Journal of Educational Computing Research, vol. 57, no. 3, pp. 547–570, 2019.
  19. J.-W. Tzeng, C.-A. Lee, N.-F. Huang, H.-H. Huang, and C.-F. Lai, “Mooc evaluation system based on deep learning,” International Review of Research in Open and Distributed Learning, vol. 23, no. 1, pp. 21–40, 2022.
  20. A. Chauhan, “Massive open online courses (moocs): Emerging trends in assessment and accreditation,” Digital Education Review, no. 25, pp. 7–17, 2014.
  21. P. M. Moreno-Marcos, C. Alario-Hoyos, P. J. Muñoz-Merino, and C. D. Kloos, “Prediction in moocs: A review and future research directions,” IEEE transactions on Learning Technologies, vol. 12, no. 3, pp. 384–401, 2018.
  22. A. Grover and J. Leskovec, “node2vec: Scalable feature learning for networks,” in Proceedings of the 22nd ACM SIGKDD international conference on Knowledge discovery and data mining, 2016, pp. 855–864.
  23. B. Perozzi, R. Al-Rfou, and S. Skiena, “Deepwalk: Online learning of social representations,” in Proceedings of the 20th ACM SIGKDD international conference on Knowledge discovery and data mining, 2014, pp. 701–710.
  24. H. Karimi, J. Huang, and T. Derr, “A deep model for predicting online course performance,” Association for the Advancement of Artificial Intelligence, 2020.
  25. H. Karimi, T. Derr, J. Huang, and J. Tang, “Online academic course performance prediction using relational graph convolutional neural network.” International Educational Data Mining Society, 2020.
  26. H. Karimi, T. Derr, K. T. Torphy, K. A. Frank, and J. Tang, “A roadmap for incorporating online social media in educational research,” Teachers College Record, vol. 121, no. 14, pp. 1–24, 2019.
  27. H. Karimi, T. Derr, K. Torphy, K. A. Frank, and J. Tang, “Towards improving sample representativeness of teachers on online social media: A case study on pinterest.”   Artificial Intelligence in Education: 21st International Conference, AIED 2020, Ifrane, Morocco, July 6–10, 2020, Proceedings, Part II 21, 2020, pp. 130–134.
  28. H. Karimi, K. T. Knake, and K. A. Frank, “Teachers in social media: A gender-aware behavior analysis,” in 2022 IEEE International Conference on Big Data (Big Data).   IEEE, 2022, pp. 1842–1849.
  29. K. T. Knake, H. Karimi, S. Hu, K. A. Frank, and J. Tang, “Educational research in the twenty-first century: Leveraging big data to explore teachers’ professional behavior and educational resources accessed within pinterest,” The Elementary School Journal, vol. 122, no. 1, pp. 86–111, 2021.
  30. H. Karimi, J. Tang, X. Weiss, and J. Huang, “Automatic identification of teachers in social media using positive unlabeled learning,” in 2021 IEEE International Conference on Big Data (Big Data).   IEEE, 2021, pp. 643–652.
  31. A. Ramesh, D. Goldwasser, B. Huang, H. Daumé III, and L. Getoor, “Modeling learner engagement in moocs using probabilistic soft logic,” in NIPS workshop on data driven education, vol. 21, 2013, p. 62.
  32. C. G. Brinton and M. Chiang, “Mooc performance prediction via clickstream data and social learning networks,” in 2015 IEEE conference on computer communications (INFOCOM).   IEEE, 2015, pp. 2299–2307.
  33. C. Piech, J. Bassen, J. Huang, S. Ganguli, M. Sahami, L. J. Guibas, and J. Sohl-Dickstein, “Deep knowledge tracing,” Advances in neural information processing systems, vol. 28, 2015.
  34. B.-H. Kim, E. Vizitei, and V. Ganapathi, “Gritnet 2: Real-time student performance prediction with domain adaptation,” arXiv preprint arXiv:1809.06686, pp. 1–8, 2018.
  35. H. Li, H. Wei, Y. Wang, Y. Song, and H. Qu, “Peer-inspired student performance prediction in interactive online question pools with graph neural network,” in Proceedings of the 29th ACM International Conference on Information & Knowledge Management, 2020, pp. 2589–2596.
  36. J. Fang, L. Tang, J. Yang, and M. Peng, “Social interaction in moocs: The mediating effects of immersive experience and psychological needs satisfaction,” Telematics and Informatics, vol. 39, pp. 75–91, 2019.
  37. S. Shatnawi, M. M. Gaber, and M. Cocea, “Automatic content related feedback for moocs based on course domain ontology,” in Intelligent Data Engineering and Automated Learning–IDEAL 2014: 15th International Conference, Salamanca, Spain, September 10-12, 2014. Proceedings 15.   Springer, 2014, pp. 27–35.
  38. P. Bonacich, “Some unique properties of eigenvector centrality,” Social networks, vol. 29, no. 4, pp. 555–564, 2007.
  39. X. Wang, D. Bo, C. Shi, S. Fan, Y. Ye, and S. Y. Philip, “A survey on heterogeneous graph embedding: methods, techniques, applications and sources,” IEEE Transactions on Big Data, 2022.
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