This study intends to carry out a bibliometric analysis to answer the following research questions: What is the annual increase in publications of constructionism, constructivism, and computational thinking, and mathematics education?; Who are the most prolific writers of constructionism, constructivism, computational thinking, and mathematics education?; Which the most countries in the fields of constructivism, constructivism, computational thinking, and  mathematics education?; Who are the most frequently cited scientists? In the end, the biblioAnalysis function generates descriptive data from bibliographic data. Thus, this description has explained that these keywords are sufficient to describe the use of theory in learning computational thinking and mathematics. After we have completed our mapping, we will have a combined framework at our disposal, which will allow us to gain a deeper understanding of the possible connections that exist between constructionism, constructivism, computational thinking, and mathematics education.

Constructionism, Constructivism, Computational Thinking, Mathematics Education

Ackermann, E. (2001). Piaget’s constructivism, Papert’s constructionism: What’s the difference. Future of learning group publication, 5(3), 438.

Alekh, V., Vennila, V., Nair, R., Susmitha, V., Muraleedharan, A., Alkoyak-Yildiz, M., ... & Bhavani, R. R. (2018, June). Aim for the sky: Fostering a constructionist learning environment for teaching maker skills to children in india. In Proceedings of the Conference on Creativity and Making in Education (pp. 87-94).

Amineh, R. J., & Asl, H. D. (2015). Review of constructivism and social constructivism. Journal of Social Sciences, Literature and Languages, 1(1), 9-16.

Babu, S. K., Anitha, P., Unnikrishnan, R., Rahul, E. S., Sasi, D. D., Ayyappan, K., & Seshadri, R. (2019, December). Igniting the Maker Spirit: Design and Pilot Deployment of the Kappa Tangible Electronics Prototyping Kit. In 2019 IEEE Tenth International Conference on Technology for Education (T4E) (pp. 23-26). IEEE.

Baker, S., Dekov, S., Fakih, F., Medvesek, J., Shum, V., & Mohamedally, D. (2014, October). Supporting Situated STEM Learning: TouchDevelop Integration of the UCL Engduino over Bluetooth. In Proceedings of the 2nd Workshop on Programming for Mobile & Touch (pp. 17-20).

Benacka, J., & Reichel, J. (2013, February). Computer Modeling with Delphi. In International Conference on Informatics in Schools: Situation, Evolution, and Perspectives (pp. 138-146). Springer, Berlin, Heidelberg.

Burrows, A. C., Borowczak, M., Myers, A., Schwortz, A. C., & McKim, C. (2021). Integrated STEM for teacher professional learning and development:“I Need Time for Practice”. Education Sciences, 11(1), 21.

Castro, E., Cecchi, F., Valente, M., Buselli, E., Salvini, P., & Dario, P. (2018). Can educational robotics introduce young children to robotics and how can we measure it?. Journal of Computer Assisted Learning, 34(6), 970-977.

Chandler, J. L. (2017). An Introduction to the Foundations of Chemical Information Theory. Tarski–Lesniewski Logical Structures and the Organization of Natural Sorts and Kinds. Information, 8(1), 15.

Connolly, T. M., & Begg, C. E. (2006). A Constructivist-Based Approach to Teaching Database Analysis and Design. Journal of Information Systems Education, 17(1). 43-53

Cui, Z., & Ng, O. L. (2021). The Interplay Between Mathematical and Computational Thinking in Primary School Students’ Mathematical Problem-Solving Within a Programming Environment. Journal of Educational Computing Research, 59(5), 988-1012.

Eloy, A., Cruz, D., Thennakoon, K., & Grant, W. (2020, June). Buildagram: a constructionist environment for spatial reasoning. In Proceedings of the 2020 ACM Interaction Design and Children Conference: Extended Abstracts (pp. 280-283).

Goldenberg, E. P., & Carter, C. J. (2021). Programming as a language for young children to express and explore mathematics in school. British Journal of Educational Technology, 52(3), 969-985.

Gribble, J., Reimer, P., Rizo, A., Pauls, S., Caldwell, B., Macias, M., ... & Rosenbaum, L. (2020). Robot Block-based Coding in Preschool.

Healy, L., & Kynigos, C. (2010). Charting the microworld territory over time: design and construction in mathematics education. ZDM, 42(1), 63-76.

Kahn, K., Sendova, E., Sacristán, A. I., & Noss, R. (2011). Young students exploring cardinality by constructing infinite processes. Technology, Knowledge and Learning, 16(1), 3-34.

Kelter, J., Peel, A., Bain, C., Anton, G., Dabholkar, S., Horn, M. S., & Wilensky, U. (2021). Constructionist co‐design: A dual approach to curriculum and professional development. British Journal of Educational Technology, 52(3), 1043-1059.

Kelter, J., Peel, A., Bain, C., Anton, G., Dabholkar, S., Horn, M. S., & Wilensky, U. (2021). Constructionist co‐design: A dual approach to curriculum and professional development. British Journal of Educational Technology, 52(3), 1043-1059.

Kynigos, C., & Diamantidis, D. (2021). Creativity in engineering mathematical models through programming. ZDM–Mathematics Education, 1-14.

Kynigos, C., & Psycharis, G. (2013). Designing for instrumentalisation: Constructionist perspectives on instrumental theory. International Journal for Technology in Mathematics Education, 20(1), 15-19.

Latsi, M., & Kynigos, C. (2021). Mathematical Assemblages Around Dynamic Aspects of Angle in Digital and Physical Space. International Journal of Science and Mathematics Education, 1-22.

Li, L. Y., Chang, C. W., & Chen, G. D. (2009, August). Researches on using robots in education. In International conference on technologies for e-learning and digital entertainment (pp. 479-482). Springer, Berlin, Heidelberg.

Morado, M. F., Melo, A. E., & Jarman, A. (2021). Learning by making: A framework to revisit practices in a constructionist learning environment. British Journal of Educational Technology, 52(3), 1093-1115.

Ng, O. L. (2021). How ‘tall’is the triangle? Constructionist learning of shape and space with 3D Pens. International Journal of Mathematical Education in Science and Technology, 52(9), 1426-1432.

Ng, O. L., & Cui, Z. (2021). Examining primary students’ mathematical problem-solving in a programming context: towards computationally enhanced mathematics education. ZDM–Mathematics Education, 53(4), 847-860.

Ng, O. L., & Ferrara, F. (2020). Towards a materialist vision of ‘learning as making’: The case of 3D printing pens in school mathematics. International Journal of Science and Mathematics Education, 18(5), 925-944.

Ng, O. L., & Tsang, W. K. (2021). Constructionist Learning in School Mathematics: Implications for Education in the Fourth Industrial Revolution. ECNU Review of Education, 2096531120978414.

Ng, O. L., Liu, M., & Cui, Z. (2021). Students’ in-moment challenges and developing maker perspectives during problem-based digital making. Journal of Research on Technology in Education, 1-15.

Noss, R., & Hoyles, C. (2019). Micromundos, construccionismo y matemáticas. Educación matemática, 31(2), 7-21.

Olabe, J. C., Basogain, X., & Olabe, M. A. (2020, November). Educational Makerspaces and Conceptual Art Projects Supporting STEAM Education. In 2020 The 4th International Conference on Education and E-Learning (pp. 142-149).

Papert, S. A. (2020). Mindstorms: Children, computers, and powerful ideas. Basic books.

Peters, J., Cornu, R. L., & Collins, J. (2003). Towards constructivist teaching and learning (Report on research conducted in conjunction with the learning to learn project). Magill: University of South Australia.

Piaget, J. (1968), Six Psychological Studies, Vintage Books, New York, NY.

Piaget, J. (1970). Genetic epistemology. In Genetic epistemology. Columbia University Press.

Pipere, A., & Micule, I. (2014). Mathematical Identity for a Sustainable Future: An Interpretative Phenomenological Analysis. Journal of Teacher Education for Sustainability, 16(1), 5-31.

Solomon, C., Harvey, B., Kahn, K., Lieberman, H., Miller, M. L., Minsky, M., ... & Silverman, B. (2020). History of logo. Proceedings of the ACM on Programming Languages, 4(HOPL), 1-66.

Spangsberg, T. H. (2017, November). Teaching programming to non-STEM novices: A didactical study of computational thinking and non-STEM computing education. In Proceedings of the 17th Koli Calling International Conference on Computing Education Research (pp. 201-202).

Westaway, L., Kaiser, G., & Graven, M. (2020). What Does Social Realism Have to Offer for Research on Teacher Identity in Mathematics Education?. International Journal of Science and Mathematics Education, 18(7), 1229-1247.