The desire to follow student learning within intelligent tutoring systems in near real time has led to the development of several models anticipating the correctness of the next item as students work through an assignment. Such models have in- cluded Bayesian Knowledge Tracing (BKT), Performance Factors Analysis (PFA), and more recently with developments in Deep Learning, Deep Knowledge Tracing (DKT). The DKT model, based on the use of a recurrent neural network, exhibited promising results in paper [PBH+15]. Thus far, however, the model has only considered the knowledge components of the problems and correctness as input, neglecting the breadth of other features col- lected by computer-based learning platforms. This work seeks to improve upon the DKT model by incorporating more features at the problem-level and student-level. With this higher dimensional input, an adaption to the original DKT model struc- ture is also proposed, incorporating an Autoencoder network layer to convert the input into a low dimensional feature vector to reduce both the resource requirement and time needed to train. Experimental results show that our adapted DKT model, which includes more combinations of features, can effectively improve accuracy.

Creator

• Zhang, Liang

Contributors

• Heffernan, Neil

Degree

• MS

Unit

• Data Science

Publisher

• Worcester Polytechnic Institute

Language

• English

Identifier

• etd-041417-091804

Keyword

• Deep Learning
• RNN
• Knowledge tracing
• DKT

Advisor

• Heffernan, Neil

Defense date

• 2017-04-14

Year

• 2017

Date created

• 2017-04-14

Resource type

• Thesis

Rights statement

• In Copyright

Last modified

• 2021-02-01