Users-Centric Adaptive Learning System Based on Interval Type-2 Fuzzy Logic for Massively Crowded E-Learning Platforms

Abstract Technological advancements within the educational sector and online learning promoted portable data-based adaptive techniques to influence the developments within transformative learning and enhancing the learning experience. However, many common adaptive educational systems tend to focus on adopting learning content that revolves around pre-black box learner modelling and teaching models that depend on the ideas of a few experts. Such views might be characterized by various sources of uncertainty about the learner response evaluation with adaptive educational system, linked to learner reception of instruction. High linguistic uncertainty levels in e-learning settings result in different user interpretations and responses to the same techniques, words, or terms according to their plans, cognition, pre-knowledge, and motivation levels. Hence, adaptive teaching models must be targeted to individual learners’ needs. Thus, developing a teaching model based on the knowledge of how learners interact with the learning environment in readable and interpretable white box models is critical in the guidance of the adaptation approach for learners’ needs as well as understanding the way learning is achieved. This paper presents a novel interval type-2 fuzzy logic-based system which is capable of identifying learners’ preferred learning strategies and knowledge delivery needs that revolves around characteristics of learners and the existing knowledge level in generating an adaptive learning environment. We have conducted a large scale evaluation of the proposed system via real-word experiments on 1458 students within a massively crowded e-learning platform. Such evaluations have shown the proposed interval type-2 fuzzy logic system’s capability of handling the encountered uncertainties which enabled to achieve superior performance with regard to better completion and success rates as well as enhanced learning compared to the non-adaptive systems, adaptive system versions led by the teacher, and type-1-based fuzzy based counterparts.</jats:p

Computer-Driven Instructional Design with INTUITEL

INTUITEL is a research project that was co-financed by the European Commission with the aim to advance state-of-the-art e-learning systems via addition of guidance and feedback for learners. Through a combination of pedagogical knowledge, measured learning progress and a broad range of environmental and background data, INTUITEL systems will provide guidance towards an optimal learning pathway. This allows INTUITEL-enabled learning management systems to offer learners automated, personalised learning support so far only provided by human tutors INTUITEL is - in the first place - a design pattern for the creation of adaptive e-learning systems. It focuses on the reusability of existing learning material and especially the annotation with semantic meta data. INTUITEL introduces a novel approach that describes learning material as well as didactic and pedagogical meta knowledge by the use of ontologies. Learning recommendations are inferred from these ontologies during runtime. This way INTUITEL solves a common problem in the field of adaptive systems: it is not restricted to a certain field. Any content from any domain can be annotated. The INTUITEL research team also developed a prototype system. Both the theoretical foundations and how to implement your own INTUITEL system are discussed in this book

A Survey of Artificial Intelligence Techniques Employed for Adaptive Educational Systems within E-Learning Platforms

Abstract The adaptive educational systems within e-learning platforms are built in response to the fact that the learning process is different for each and every learner. In order to provide adaptive e-learning services and study materials that are tailor-made for adaptive learning, this type of educational approach seeks to combine the ability to comprehend and detect a person’s specific needs in the context of learning with the expertise required to use appropriate learning pedagogy and enhance the learning process. Thus, it is critical to create accurate student profiles and models based upon analysis of their affective states, knowledge level, and their individual personality traits and skills. The acquired data can then be efficiently used and exploited to develop an adaptive learning environment. Once acquired, these learner models can be used in two ways. The first is to inform the pedagogy proposed by the experts and designers of the adaptive educational system. The second is to give the system dynamic self-learning capabilities from the behaviors exhibited by the teachers and students to create the appropriate pedagogy and automatically adjust the e-learning environments to suit the pedagogies. In this respect, artificial intelligence techniques may be useful for several reasons, including their ability to develop and imitate human reasoning and decision-making processes (learning-teaching model) and minimize the sources of uncertainty to achieve an effective learning-teaching context. These learning capabilities ensure both learner and system improvement over the lifelong learning mechanism. In this paper, we present a survey of raised and related topics to the field of artificial intelligence techniques employed for adaptive educational systems within e-learning, their advantages and disadvantages, and a discussion of the importance of using those techniques to achieve more intelligent and adaptive e-learning environments.</jats:p

Student modeling for learning of object-oriented programming in e-learning environment

E-Learning environment offers some interesting benefits over traditional learning environments. Students’ learning in e-learning environment can be independent of distance, time, computing platform and classroom size. E-Learning also provides diversity and completeness of knowledge. In an e-learning environment, students learn by going through learning materials provided through a web-based learning management system. However, most of the learning management systems are nothing more than a network of statically linked hypertext pages. To better support the learning activities of a large number of students with different learning styles, and diverse background and learning goals, there is a need for a more adaptive and intelligence learning management system. To achieve this objective, this system must be able to provide a more personalised approach for learners. This is particularly important in the learning of programming, since different learner would normally face with different problem. The most important component for developing a more adaptive and intelligent learning management system is the students model. The purpose of this paper is to investigate and then to propose a students model for learning of object-oriented programming in an e-learning environment. The development of this model is based on our experience in handling courses on object-oriented programming at Open University Malaysia (OUM) over more than four years. (Authors' abstract

On the automatic compilation of e-learning models to planning

[EN] This paper presents a general approach to automatically compile e-learning models to planning, allowing us to easily generate plans, in the form of learning designs, by using existing domain-independent planners. The idea is to compile, first, a course defined in a standard e-learning language into a planning domain, and, second, a file containing students learning information into a planning problem. We provide a common compilation and extend it to three particular approaches that cover a full spectrum of planning paradigms, which increases the possibilities of using current planners: (i) hierarchical, (ii) including PDDL (Planning Domain Definition Language) actions with conditional effects and (iii) including PDDL durative actions. The learning designs are automatically generated from the plans and can be uploaded, and subsequently executed, by learning management platforms. We also provide an extensive analysis of the e-learning metadata specification required for planning, and the pros and cons on the knowledge engineering procedures used in each of the three compilations. Finally, we include some qualitative and quantitative experimentation of the compilations in several domain-independent planners to measure its scalability and applicability.This work has been supported by the Spanish MICINN under projects TIN2008-06701-C03 and Consolider Ingenio 2010 CSD2007-00022, by the Mexican National Council of Science and Technology and the regional projects CCG08-UC3M/TIC-4141 and Prometeo GVA 2008/051.Garrido Tejero, A.; Fernandez, S.; Onaindia De La Rivaherrera, E.; Morales, L.; Borrajo, D.; Castillo, L. (2013). On the automatic compilation of e-learning models to planning. Knowledge Engineering Review. 28(2):121-136. https://doi.org/10.1017/S0269888912000380S121136282Garrido A. , Onaindía E. 2010. On the application of planning and scheduling techniques to E-learning. In Proceedings of the 23rd International Conference on Industrial, Engineering & Other Applications of Applied Intelligent Systems (IEA-AIE 2010)—Lecture Notes in Computer Science 6096, 244–253. Springer.Ullrich C 2008. Pedagogically founded courseware generation for web-based learning, No. 5260, Lecture Notes in Artificial Intelligence 5260, Springer.Sicilia M.A. , Sánchez-Alonso S. , García-Barriocanal E. 2006. On supporting the process of learning design through planners. CEUR Workshop Proceedings: Virtual Campus 2006 Post-Proceedings. Barcelona, Spain, 186(1), 81–89.IMSLD 2003. IMS Learning Design Specification. Version 1.0 (February, 2003). Retrieved December, 2012, from http://www.imsglobal.org/learningdesign.Sharable Content Object Reference Model (SCORM) 2004. Retrieved December, 2012, from http://scorm.com.Garrido A. , Onaindia E. , Morales L. , Castillo L. , Fernandez S. , Borrajo D. 2009. Modeling E-learning activities in automated planning. In Proceedings of the 3rd International Competition on Knowledge Engineering for Planning and Scheduling (ICKEPS-2009), Thessaloniki, Greece, 18–27.Essalmi, F., Ayed, L. J. B., Jemni, M., Kinshuk, & Graf, S. (2010). A fully personalization strategy of E-learning scenarios. Computers in Human Behavior, 26(4), 581-591. doi:10.1016/j.chb.2009.12.010Camacho D. , R-Moreno M.D. , Obieta U. 2007. CAMOU: a simple integrated e-learning and planning techniques tool. In 4th International Workshop on Constraints and Language Processing, Roskilde University, Denmark, 1–11.Fox, M., & Long, D. (2003). PDDL2.1: An Extension to PDDL for Expressing Temporal Planning Domains. Journal of Artificial Intelligence Research, 20, 61-124. doi:10.1613/jair.1129KONTOPOULOS, E., VRAKAS, D., KOKKORAS, F., BASSILIADES, N., & VLAHAVAS, I. (2008). An ontology-based planning system for e-course generation. Expert Systems with Applications, 35(1-2), 398-406. doi:10.1016/j.eswa.2007.07.034Fuentetaja R. , Borrajo D. , Linares López C. 2009. A look-ahead B&B search for cost-based planning. In Proceedings of CAEPIA'09, Murcia, Spain, 105–114.Limongelli C. , Sciarrone F. , Vaste G. 2008. LS-plan: an effective combination of dynamic courseware generation and learning styles in web-based education. In Adaptive Hypermedia and Adaptive Web-Based Systems, 5th International Conference, AH 2008, Nejdl, W., Kay, J., Pu, P. & Herder, E. (eds.)., 133–142. Springer.Castillo L. , Fdez.-Olivares J. , García-Perez O. Palao F. 2006. Efficiently handling temporal knowledge in an HTN planner. In Proceedings of 16th International Conference on Automated Planning and Scheduling (ICAPS 2006), Borrajo, D. & McCluskey, L. (eds.). AAAI, 63–72.Castillo, L., Morales, L., González-Ferrer, A., Fdez-Olivares, J., Borrajo, D., & Onaindía, E. (2009). Automatic generation of temporal planning domains for e-learning problems. Journal of Scheduling, 13(4), 347-362. doi:10.1007/s10951-009-0140-xUllrich, C., & Melis, E. (2009). Pedagogically founded courseware generation based on HTN-planning. Expert Systems with Applications, 36(5), 9319-9332. doi:10.1016/j.eswa.2008.12.043Boticario J. , Santos O. 2007. A dynamic assistance approach to support the development and modelling of adaptive learning scenarion based on educational standards. In Proceedings of Workshop on Authoring of Adaptive and Adaptable Hypermedia, International Conference on User Modelling, Corfu, Greece, 1–8.IMSMD 2003. IMS Learning Resource Meta-data Specification. Version 1.3 (August, 2006). Retrieved December, 2012, from http://www.imsglobal.org/metadata.Mohan P. , Greer J. , McCalla G. 2003. Instructional planning with learning objects. In IJCAI-03 Workshop Knowledge Representation and Automated Reasoning for E-Learning Systems, Acapulco, Mexico, 52–58.Alonso C. , Honey P. 2002. Honey-alonso Learning Style Theoretical Basis (in Spanish). Retrieved December 2012, from http://www.estilosdeaprendizaje.es/menuprinc2.htm

AdPisika: an adaptive e-learning system utilizing k-means clustering, decision tree, and bayesian network based on felder-silverman model to enhance physics academic performance

Amid the shift to online learning during the COVID-19 outbreak, the academic performance of students has become a concern. To address this, Adaptive Learning Systems (ALS) have emerged, these help in assessing students and delivering personalized content. This study develops an ALS incorporating K-means Clustering, Decision Tree, and Bayesian Network techniques, based on the Felder-Silverman Learning Style Model (FSLSM). The aim is to optimize learning materials based on students' current Knowledge Level (KL) and their Learning Style (LS). The students who utilized the proposed system showed substantial improvements in their performance across the Electromagnetic Spectrum, Light, Electricity, and Magnetism modules, with increases of 28.8%, 41.4%, 31.9%, and 32.9%, respectively. These findings provide strong evidence that the adaptive e-learning system had a significant positive impact on post-test scores compared to pre-test scores, surpassing the outcomes achieved with the traditional learning approach. With a silhouette score of 0.7 for K-Means clustering, an accuracy of 87.5% for Decision Tree, and a 95.1% acceptance value for the distribution of learning objects using the Bayesian Network, the proposed adaptive system demonstrated successful implementation of these machine learning algorithms. Furthermore, the proposed system received "excellent" ratings for functional stability, performance efficiency, compatibility, and reliability, with mean values of 4.49, 4.43, 4.43, 4.8, and 4.47 respectively