Technology integration in geometry teaching and learning

A systematic review (2010–2022)

Authors

  • Gladys Sunzuma Bindura University Of Science Education, Zimbabwe

DOI:

https://doi.org/10.31129/LUMAT.11.3.1938

Keywords:

geometry, teaching, learning, education technology, systematic review

Abstract

Technology advancement provides an opportunity for helping both teachers and students to solve and improve mathematics teaching and learning performances. This systematic review aims to add to the discussion through a comprehensive overview of the integration of digital technologies into the teaching and learning of geometry at the secondary school level.  A systematic literature review was conducted following the preferred reporting items for systematic reviews and meta-analyses (PRISMA) guidelines, with a focus on publication trends, types of technologies used, types of contributions, learning domains and research methods. Twenty-nine articles published between 2010 and 2022 were searched from the ERIC database.  The findings showed that the majority of the articles were published in 2015 and the technologies that were used were GeoGebra, augmented reality, computer animation package, video-based cooperative, graphing calculator, micromedia flash, Powtoon animation, learning management system, interactive whiteboard, digital simulations-applets, iPads and tablet. Most of the reviewed articles focused on the effectiveness of the technologies in geometry teaching and learning. The findings indicated that the majority of the reviewed articles used quantitative research methods followed by qualitative methods studies. It is suggested that other studies be conducted with other databases and focus on challenges of integrating technology into the teaching and learning of geometry.

References

Abebayehu Y., & Hsiu-Ling, C. (2021). GeoGebra in mathematics education: a systematic review of journal articles published from 2010 to 2020. Interactive Learning Environments, DOI: 10.1080/10494820.2021.2016861

Ahmad, N. I. N., & Junaini, S. N. (2020). Augmented Reality for Learning Mathematics: A Systematic Literature Review. International Journal of Emergency Technology learning, 15(16), 106–122

Abd Rahim, F., Ujang, N., & Said, M. T. (2018). Geometri dan peranannya dalam reka bentuk ban dar Islamik. Malaysian Journal of Society and Space, 14(2), 82–96. https://doi.org/10.17576/geo-2018--1402-07

*Abdul Hanid, M., Mohamad Said, M., & Yahaya, N. (2022). Effects of augmented reality application integration with computational thinking in geometry topics. Education Information Technology 27, 9485–9521. https://doi.org/10.1007/s10639-022-10994-w

*Adelabu, F. M, Makgato, M., and Ramaligela, M.S., (2019). The Importance of Dynamic Geometry Computer Software on Learners’ Performance in Geometry. The Electronic Journal of e-Learning, 17(1), 52–63

Ayan, R., & Isiksal Bostan, M. (2016). Middle School Students? Reasoning in Nonlinear Proportional Problems in Geometry. International Journal of Science and Mathematics Education, 16, 1–16. https://doi.org/10.1007/s10763-016-9777-z

Akçayır, G., & Akçayır, M. (2018). The flipped classroom: A review of its advantages and challenges. Computers & Education, 126, 334–345. https://doi.org/10.1016/j.compedu.2018.07.021

*Akmalia, R., Fajriana; R., Nufus, H., & Wulandari, W. (2021). Development of powtoon animation learning media in improving understanding of mathematical concept. Malikussaleh Journal of Mathematics Learning, 4(2), 105–116.

*Baccaglini-Frank, A., & Mariotti, M.A. (2010). Generating Conjectures in Dynamic Geometry: The Maintaining Dragging Model. International Journal Computer Mathematics Learning 15, 225–253. https://doi.org/10.1007/s10758-010-9169-3

Bergstrom, C., & Zhang, D. (2016). Geometry interventions for K-12 students with and without disabilities: A research synthesis. International Journal of Educational Research, 80, 134–154. https://doi.org/10.1016/j.ijer.2016.04.004

*Brito, L. P., Almeida, L. S. & Osório, A. J. (2021). Seeing in believing: impact of digital simulation pedagogical use in spatial geometry classes. International Journal of Technology in Teaching and Learning, 17(2), 109–123

Christou, C., Pittalis, M., Mousoulides, N., & Jones, K. (2006). Developing the 3DMath dynamic geometry software: theoretical perspectives on design. International Journal, 13, 168–174. http://eprints.soton.ac.uk/42114/

Clark-Wilson, A., Robutti, O., & Thomas, M. (2020). Teaching with digital technology. ZDM Mathematics Education, 52(7), 1223–1242. https://doi.org/10.1007/s11858-020-01196-0

*Diaz-Nunja, L., Rodríguez-Sosa, J., & Lingán, S.K. (2018). Teaching of Geometry with the GeoGebra Software in High School Students of an Educational Institution in Lima, Propósitos y Representaciones 6(2), 217–251. Doi: http://dx.doi.org/10.20511/pyr2018.v6n2.251

Dockendorff, M., & Solar, H. (2018). ICT integration in mathematics initial teacher training and its impact on visualization: The case of GeoGebra. International Journal of Mathematical Education in Science and Technology, 49(1), 66–84. https://doi.org/10.1080/0020739x.2017.1341060

*Doğan, M. İçel, R. (2011). The role of dynamic geometry software in the process of learning: GeoGebra example about triangles International Journal of Human Sciences, 8(1). Available: http://www.InsanBilimleri.com/En

*Duroisin, N., Temperman, G., & De Lièvre, B (2015). Restrict or Share the Use of the Interactive Whiteboard? The Consequences on the Perception, the Learning Processes and the Performance of Students within a Learning Sequence on Dynamic Geometry. The Turkish Online Journal of Educational Technology, 14(2), 144–154

Duman, G., Orhon, G., & Gedik, N. (2015). Research trends in mobile assisted language learning from 2000 to 2012. ReCALL, 27(2), 197–216. https://doi.org/10.1017/S0958344014000287

*Fukawa-Connelly, T., & Silverman, J. (2015). The development of mathematical argumentation in an unmoderated, asynchronous multi-User dynamic geometry environment. Contemporary Issues in Technology and Teacher Education, 15(4), 445–488.

*Gambari, A.I., Falode, C.O., & Adegbenro, D. (2014). Effectiveness of Computer Animation and Geometrical Instructional Model on Mathematics Achievement and Retention among Junior Secondary School Students. European Journal of Science and Mathematics Education, 2, 127–146.

*Gambari, A.I., Shittu, A. T., Daramola, F. O., & James, M. (2016). Effects Of Video-Based Cooperative, Competitive And Individualized Instructional Strategies On The Performance Of Senior Secondary Schools Students In Geometry. Malaysian Online Journal of Educational Sciences, 4(4), 31–47

*Gómez-Chacón, I.M., Romero Albaladejo, I.M. & del Mar García López, M. (2016). Zig-zagging in geometrical reasoning in technological collaborative environments: a Mathematical Working Space-framed study concerning cognition and affect. ZDM Mathematics Education 48, 909–924 https://doi.org/10.1007/s11858-016-0755-2

*Gülburnu, M. (2022). Secondary School Students' Views on Geometry Teaching via Three-Dimensional Dynamic Geometry Software Cabri 3D: Solid Volume Measurement. International Journal of Curriculum and Instruction, 14(1), 1088–1105

Gutiérrez, A. (1996). Visualization in 3-dimensionalgeometry: In search of a framework. In L. Puig, and A. Gutiérrez (Eds.), Proceedings of the 20th PME Conference (pp. 56-79).

Hollebrands, K.F., & Okumuş, S. (2018). Secondary mathematics teachers’ instrumental integration in technology-rich geometry classrooms. The Journal of Mathematical Behavior, 49, 82–94.

Horsman, R., (2019). International perspectives on the teaching and learning of geometry in secondary schools. Research in Mathematics Education, 21(1), 96–100. https://doi.org/10.1080/14794802.2018.1531055

Hwang, W.-Y., Su, J.-H., Huang, Y.-M., & Dong, J.-J. (2009). A Study of Multi-Representation of Geometry Problem solving with virtual manipulatives and whiteboard system. Educational Technology & Society, 12 (3), 229–247.

*İbili, E., Çat, M., Resnyansky, D., Şahin, S., & Billinghurst, M. (2020). An assessment of geometry teaching supported with augmented reality teaching materials to enhance students’ 3D geometry thinking skills, International Journal of Mathematical Education in Science and Technology, 51(2), 224–246

Jones, K. (2000), Critical Issues in the Design of the Geometry Curriculum. In Bill Barton (Ed). Readings in mathematics education (pp. 75-90). Auckland, New Zealand.

Jones, K. & Tzekaki, M. (2016). Research on the teaching and learning of geometry. In A Gutiérrez, GC Leder & P Boero (eds). The second handbook of research on the psychology of mathematics education: The journey continues. Rotterdam, The Netherlands

*Kandemir, M.A., & Demirbag Keskin, P. (2019). Effect of graphing calculator program supported problem solving instruction on mathematical achievement and attitude. International Journal of Research in Education and Science, 5(1), 203–223.

Krathwohl, D. R. (2002). A revision of Bloom’s taxonomy: An overview. Theory Into Practice, 41(4), 212–218. https://doi.org/10.1207/s15430421tip4104_2

Kuzniak, A. (2018). Thinking about the teaching of geometry through the lens of the theory of geometric working spaces. In P Herbst, U Cheah, P Richard & K Jones (eds). International perspectives on the teaching and learning of 12 Smith, Julie, Gierdien geometry in secondary schools. Cham, Switzerland: Springer. https://doi.org/10.1007/978- 3-319-77476-3_2

*Kaushal, K., & Chun-Yen, C. (2015). Incorporating GeoGebra into Geometry Learning - A Lesson from India. EURASIA Journal of Mathematics, Science & Technology Education, 11(1), 77–86

Klančar, A., Cotič, M., & Žakelj, A. (2019). Učenje in poučevanje geometrije z uporabo informacijsko-komunikacijske tehnologije v osnovni šoli [Learning and teaching geometry using ICT in elementary school]. Založba Univerze na Primorskem. https://doi.org/10.26493/978-961-7055-63-4

*Komatsu, K., & Jones, K. (2020). Interplay between Paper-and-Pencil Activity and Dynamic-Geometry-Environment Use during Generalisation and Proving. Digital Experiences in Mathematics Education, 2020(6), 123–143. https://doi.org/10.1007/s40751-020-00067-3

Lee, H. S., & Hollebrands, K. F. (2006). Students’ use of technological features while solving a mathematics problem. Journal of Mathematical Behavior, 25(3), 252–266.

*Lin, H, K., Chen, M., & Chang, K. (2015). Assessing the effectiveness of learning solid geometry by using an augmented reality assisted learning system. Interactive Learning Environments, 23(6), 799–810.

*Lin, J.R. H., & Lin, S.S.J. (2014). Cognitive load for configuration comprehension in computer-supported geometry problem solving: An eye movement perspective. International Journal of Science and Mathematics Education 2014(12), 605–627 https://doi.org/10.1007/s10763-013-9479-8

*Mailizar., & Johar, R. (2021). Examining Students’ Intention to Use Augmented Reality in a Project-Based Geometry Learning Environment. International Journal of Instruction, 14(2), 773–790.

Mohamed, M. Z., Hidayat, R., Suhaizi, N. N., Sabri, N. M., Mahmud, M. K. H., & Baharuddin, S. N. (2022). Artificial intelligence in mathematics education: A systematic literature review. International Electronic Journal of Mathematics Education, 17(3),

Mensah, J. Y., & Nabie, M. J. (2021). The effect of PowerPoint instruction on high school students’ achievement and motivation to learn geometry. International Journal of Technology in Education (IJTE), 4(3), 331–350. https://doi.org/10.46328/ijte.55

NCTM. (2000). Principles and Standards for School Mathematics. Reston: National Council of Teachers of Mathematics.

*Ng, O., & Sinclair, N. (2015). Area Without Numbers”: Using Touchscreen Dynamic Geometry to Reason About Shape. Canadian Journal of Science, Mathematics and technology Education. 15(1), 84–101

Nursyahidah, F., Saputro, B, A., & Prayito, M. (2016). Kemampuan Penalaran Matematis Siswa SMP dalam Belajar Garis dan Sudut dengan GeoGebra. Suska Journal of Mathematics Education, 2(1), 13–19

Olsson, J. (2018). The contribution of reasoning to the utilization of feedback from software when solving mathematical problems. International Journal of Science and Mathematics Education, 16(4), 715–735. https://doi.org/10.1007/s10763-016-9795-x

Page, M. J., McKenzie, J. E., Bossuyt, P. M., Boutron, I., Hoffmann, T. C., Mulrow, C. D., Shamseer, L., Tetzlaff, J. M., Akl, E. A., Brennan, S. E., Chou, R., Glanville, J., Grimshaw, J. M., Hróbjartsson, A., Lalu, M. M., Li, T., Loder, E. W., Mayo-Wilson, E., McDonald, S., McGuinness, L. A., Stewart A.L., Thomas, J., Tricco, A.C., Welch. V. A., Whiting, P., & Moher, D. (2021). The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. BMJ (Clinical research ed.), 372, n71. https://doi.org/10.1136/bmj.n71

*Perry, D. R., & Steck, A. K. (2015). Increasing Student Engagement, Self-Efficacy, and Meta-Cognitive Self-Regulation in the High School Geometry Classroom: Do iPads Help? Computers in the Schools, 32(2), 122–143, DOI: 10.1080/07380569.2015.1036650

Petrus, Z., Karmila., & Riady, A. (2017). Deskripsi Kemampuan Geometri Siswa SMP Berdasarkan Teori Van Hiele. Pedagogy, 2(1), 145–160

*Praveen, S., & Kwan Eu, L. ( 2013). Effectiveness of Using GeoGebra on Students' Understanding in Learning Circles. Malaysian Online Journal of Educational Technology, 1(4) 1–11

*Prasad, P. V. (2016). Leveraging Interactive Geometry Software to Prompt Discussion. Mathematics Teaching in the Middle School, 22(4), 226–233. https://doi.org/10.5951/mathteacmiddscho.22.4.0226

*Samur Turk, H., & Akyüz, D. (2016). The Effects of Using Dynamic Geometry on Eighth Grade Students’ Achievement and Attitude towards Triangles. International Journal for Technology in Mathematics Education, 95–102. https://hdl.handle.net/11511/35759

Septia, T., Prahmana, R. C. I., Pebrianto, & Wahyu, R. (2018). Improving Students Spatial Reasoning with Course LAB. Journal on Mathematics Education, 9(2), 327–336

*Shaame, A.A., Anatory, J., Osaki, K.M., & Mrutu, S.I. (2020). Exploring a Learning Management System as a Way to Improve Students’ Understanding of Geometry in Secondary Schools. Africa Education Review, 17, 17–40.

*Sherman, M. F., & Cayton, C. (2015). Using appropriate tools strategically for instruction. Mathematics Teacher, 109(4), 306–310.

Sutiarso, S., Coesamin, M., & Nurhanurawati. (2018). The effect of various media scaffolding on increasing understanding of geometry concepts in elementary school students. Journal on Mathematics Education, 9(1), 95–102.

Tay, M. K, & Mensah-Wonkyi, T. (2018). Effect of using GeoGebra on senior high school students’ performance in circle theorems. African Journal of Educational Studies in Mathematics and Sciences, 14, 1–17

*Viseu, F., Rocha, H., & Monteiro, J. M. (2022). Rethinking Digital Technology versus Paper and Pencil in 3D Geometry. Journal of Learning for Development, 9(2), 267–278

*Yani, M., & Rosma, F. (2020). Improving Students' Spatial Ability by Using Macromedia Flash on Geometry Materials. Malikussaleh Journal of Mathematics Learning, 3(1), 18–22

Yang, Q.F., Lin, C. J., & Hwang, G.J. (2019). Research focuses and findings of flipping mathematics classes: A review of journal publications based on the technology-enhanced learning model. Interactive Learning Environments, 29(4), 1–34. https://doi.org/10.1080/10494820.2019.1602842

Žakelj, A., & Klančar, A. (2022). The role of visual representations in geometry learning. European Journal of Educational Research, 11(3), 1393–1411. https://doi.org/10.12973/eu-jer.11.3.1393

Zhong, B., & Xia, L. (2020). A systematic review on exploring the potential of educational robotics in mathematics education. International Journal of Science and Mathematics Education, 18(1), 79–101. https://doi.org/10.1007/

Downloads

Published

2023-08-22

How to Cite

Sunzuma, G. (2023). Technology integration in geometry teaching and learning: A systematic review (2010–2022). LUMAT: International Journal on Math, Science and Technology Education, 11(3), 1–18. https://doi.org/10.31129/LUMAT.11.3.1938

Similar Articles

<< < 16 17 18 19 20 21 22 23 24 25 > >> 

You may also start an advanced similarity search for this article.