IMPACT OF GAMIFIED PLATFORMS AND SIMULATION WEBSITES ON TEACHING PROGRAMMING CONCEPTS IN THE IBDP COMPUTER SCIENCE
DOI:
https://doi.org/10.17501/24246700.2025.11107Keywords:
international baccalaureate diploma programme (IBDP), programming pedagogy, gamified platforms, student engagement, stem education, computer science pedagogyAbstract
The International Baccalaureate Diploma Programme (IBDP) Computer Science curriculum poses various challenges in teaching computational thinking (programming) concepts. As learners are from a variety of backgrounds other than computer science, they fail to understand the abstract concepts. This research examines how the gamified platforms and simulation-based tools help learners gauge the programming concepts. Even though there are studies that show the usage of gamification in STEM education, it lacks application in the IBDP Computer Science. This study incorporates a single-group quasi-experimental design with a wide range of pre- and post-assessments. Various assessment methods were incorporated to balance by including quantitative and qualitative data. Based on the results, it is evident that there is a 46% increase in learners’ comprehension of the IBDP Computer Science programming concepts and a significant improvement in their engagement level. With the qualitative data gathered, it is confirmed that the gamified platforms and simulation-based tools are fun and engaging for learners throughout their learning journey. It also enhances 21st-century skills like problem-solving and critical thinking amongst learners. Teachers gain actionable recommendations for integrating gamified and simulation-based tools to improve engagement and conceptual understanding in programming.
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Fernandes, A., Li, K., & Chen, Y. (2023). Gamification and computational thinking: A study on problem-solving in computer science education. International Journal of Educational Technology, 45(3), 112-130.
Johnson, R., & Smith, P. (2024). Enhancing programming pedagogy through simulation-based learning. Journal of Computer Science Education, 32(1), 56-78.
Lee, J., & Hammer, J. (2021). Gamification in education: A systematic review and meta-analysis of learning outcomes. Educational Psychology Review, 39(4), 765-792.
Lee, M., & Shute, V. (2020). The impact of gamified learning environments on student engagement and achievement. Computers & Education, 148, 103789. https://doi.org/10.1016/j.compedu.2019.103789
Li, Y., & Gao, W. (2023). Hybrid learning approaches: Integrating gamification and simulations in STEM education. Interactive Learning Environments, 31(2), 189-207.
Mujtaba, T., & Reiss, M. (2020). Simulation-based learning in computer science: Evaluating the effectiveness of interactive visualizations. International Journal of STEM Education, 7(1), 89-104.
Salen, K., & Zimmerman, E. (2022). Gamification and constructivist learning theories: Aligning game mechanics with pedagogical strategies. Journal of Digital Learning Research, 40(2), 201-223.
Santos, F., Mora, A., & González, C. (2021). Engagement and motivation in gamified learning: A study of digital platforms in computer science education. Journal of Educational Technology, 27(3), 145-167.
Williams, R., & Ahmed, H. (2022). Using interactive simulations to improve conceptual understanding in computer science. Advances in Engineering Education, 15(4), 58-74.
Zhang, L., Patel, N., & Kim, J. (2019). Game-based learning and computational thinking: Evidence from secondary school students. Journal of Emerging Technologies in Learning, 14(6), 99-115.
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Copyright (c) 2025 Sakthipreya V
This work is licensed under a Creative Commons Attribution 4.0 International License.
