Integrating Augmented Reality Technology in Magnetic Field Learning: A Systematic Literature Review

Venny Haris, Siti Nursaila Alias, Shahrul Kadri Ayop

Abstract


The aim of this study was to uncover research trends in the use of augmented reality (AR) in magnetic field learning from 2012 to 2023. The review in this study followed the guidelines of Kitchenham, B. and Charters, which consisted of three stages: planning, conducting, and reporting the review. During the planning stages of the review, 107 articles were identified using keywords. The remaining articles were examined according to inclusion and exclusion criteria, so that 21 articles were further processed. A review stage is then carried out, followed by reporting of the review results. The results of this study suggest that the use of augmented reality (AR) to teach magnetic fields is primarily focused on teaching high school students. The aspects that have attracted the most attention when analyzing the implementation of AR in magnetic field education are learning/academic performance, perception and attitude. The most commonly used forms of AR in the study of magnetic fields are mobile applications, AR-based learning experiments, 3D simulations, and real-time simulations, all of which aim to explain abstract concepts and facilitate experimental explorations. Quantitative research design is the most commonly used approach in this field. The primary data collection tools used in this study include achievement tests, surveys, and questionnaires.

Keywords


Augmented Reality; Magnetic Field; Systematic Literature

Full Text:

PDF (English)

References


Handhika, J., Cari, C., Suparmi, A., & Sunarno, W. (2015). Exsternal representation to overcome misconception in physics. In International Conference on Mathematics, Science, and Education (Vol. 1, No. 1, pp. 1-4).

Setyani, N. D., Cari, S., Suparmi, S., & Handhika, J. (2017). Student’s concept ability of Newton’s law based on verbal and visual test. In International Journal of Science and Applied Science: Conference Series (Vol. 1, No. 2, pp. 162-169).

Demirci, N. (2006). Students’ conceptual knowledge about electricity and magnetism and its implications: an example of Turkish university. Science Education International, 17(1), 49-64.

Chasteen, S. V., & Pollock, S. J. (2009, November). A Research‐Based Approach to Assessing Student Learning Issues in Upper‐Division Electricity & Magnetism. In AIP Conference Proceedings (Vol. 1179, No. 1, pp. 7-10). American Institute of Physics.

Fidan, M., & Tuncel, M. (2019). Integrating augmented reality into problem based learning: The effects on learning achievement and attitude in physics education. Computers & Education, 142, 103635.

Kapp, S., Thees, M., Strzys, M. P., Beil, F., Kuhn, J., Amiraslanov, O., ... & Wehn, N. (2019). Augmenting Kirchhoff’s laws: Using augmented reality and smartglasses to enhance conceptual electrical experiments for high school students. The Physics Teacher, 57(1), 52-53.

Kuit, V. K., & Osman, K. (2021). CHEMBOND3D e-module effectiveness in enhancing students’ knowledge of chemical bonding concept and visual-spatial skills. European Journal of Science and Mathematics Education, 9(4), 252-264.

Zafeiropoulou, M., Volioti, C., Keramopoulos, E., & Sapounidis, T. (2021). Developing physics experiments using augmented reality game-based learning approach: A pilot study in primary school. Computers, 10(10), 126.

Dunleavy, M., Dede, C., & Mitchell, R. (2009). Affordances and limitations of immersive participatory augmented reality simulations for teaching and learning. Journal of science Education and Technology, 18, 7-22.

Peddie, J. (2017). Augmented reality: Where we will all live (Vol. 349). Cham: Springer.

Wu, H. K., Lee, S. W. Y., Chang, H. Y., & Liang, J. C. (2013). Current status, opportunities and challenges of augmented reality in education. Computers & education, 62, 41-49.

Azuma, R., Baillot, Y., Behringer, R., Feiner, S., Julier, S., & MacIntyre, B. (2001). Recent advances in augmented reality. IEEE computer graphics and applications, 21(6), 34-47.

Weng, C., Rathinasabapathi, A., Weng, A., & Zagita, C. (2019). Mixed reality in science education as a learning support: A revitalized science book. Journal of Educational Computing Research, 57(3), 777-807.

Arici, F., Yildirim, P., Caliklar, Ş., & Yilmaz, R. M. (2019). Research trends in the use of augmented reality in science education: Content and bibliometric mapping analysis. Computers & education, 142, 103647.

Wulandari, S., Wibowo, F. C., & Astra, I. M. (2021, October). A review of research on the use of augmented reality in physics learning. In Journal of Physics: Conference Series (Vol. 2019, No. 1, p. 012058). IOP Publishing.

Rahmat, A. D., Kuswanto, H., & Wilujeng, I. (2023). A systematic literature review of integrating augmented reality technology in science learning. Jurnal Inovasi Teknologi Pembelajaran, 10(2), 172-181.

Yilmaz, O. (2021). Augmented Reality in Science Education: An Application in Higher Education. Shanlax International Journal of Education, 9(3), 136-148.

Permana, A. H., Muliyati, D., Bakri, F., Dewi, B. P., & Ambarwulan, D. (2019, February). The development of an electricity book based on augmented reality technologies. In Journal of Physics: Conference Series (Vol. 1157, No. 3, p. 032027). IOP Publishing.

Ropawandi, D., Halim, L., & Husnin, H. (2022). Augmented reality (AR) technology-based learning: the effect on physics learning during the covid-19 pandemic. International Journal of Information and Education Technology, 12(2), 132-140.

Bakri, F., Ambarwulan, D., & Muliyati, D. (2018). Pengembangan Buku Pembelajaran Yang Dilengkapi Augmented Reality Pada Pokok Bahasan Gelombang Bunyi Dan Optik. Gravity: Jurnal Ilmiah Penelitian dan Pembelajaran Fisika, 4(2).

Ibisono, H. S., Achmadi, H. R., & Suprapto, N. (2020). Efektivitas buku saku berbasis augmented reality pada materi gerak planet untuk meningkatkan prestasi belajar peserta didik SMA. Inovasi Pendidikan Fisika, 9(02), 200-206.

Suprapto, N., Ibisono, H. S., & Mubarok, H. (2021). The use of physics pocketbook based on augmented reality on planetary motion to improve students’ learning achievement. JOTSE: Journal of Technology and Science Education, 11(2), 526-540.

Dünser, A., Walker, L., Horner, H., & Bentall, D. (2012, November). Creating interactive physics education books with augmented reality. In Proceedings of the 24th Australian computer-human interaction conference (pp. 107-114).

Altmeyer, K., Kapp, S., Thees, M., Malone, S., Kuhn, J., & Brünken, R. (2020). The use of augmented reality to foster conceptual knowledge acquisition in STEM laboratory courses—Theoretical background and empirical results. British Journal of Educational Technology, 51(3), 611-628.

Cai, S., Liu, C., Wang, T., Liu, E., & Liang, J. C. (2021). Effects of learning physics using Augmented Reality on students’ self‐efficacy and conceptions of learning. British Journal of Educational Technology, 52(1), 235-251.

Akçayır, M., Akçayır, G., Pektaş, H. M., & Ocak, M. A. (2016). Augmented reality in science laboratories: The effects of augmented reality on university students’ laboratory skills and attitudes toward science laboratories. Computers in Human Behavior, 57, 334-342.

Liu, Q., Yu, S., Chen, W., Wang, Q., & Xu, S. (2021). The effects of an augmented reality based magnetic experimental tool on students' knowledge improvement and cognitive load. Journal of computer assisted learning, 37(3), 645-656.

Sun, J. C. Y., Ye, S. L., Yu, S. J., & Chiu, T. K. (2023). Effects of wearable hybrid AR/VR learning material on high school students’ situational interest, engagement, and learning performance: The case of a physics laboratory learning environment. Journal of Science Education and Technology, 32(1), 1-12.

Prastya, B. M. Y., Budiawanti, S., & Wahyuningsih, D. (2023). Development Of Physics Learning Media PHY-ART (Physics With Augmented Reality Technology) To Empower Student’s Laboratory Skills. JIPF (Jurnal Ilmu Pendidikan Fisika), 8(2), 192-199.

Sun, J. C. Y., Ye, S. L., Yu, S. J., & Chiu, T. K. (2023). Effects of wearable hybrid AR/VR learning material on high school students’ situational interest, engagement, and learning performance: The case of a physics laboratory learning environment. Journal of Science Education and Technology, 32(1), 1-12.

Wang, H. Y., Duh, H. B. L., Li, N., Lin, T. J., & Tsai, C. C. (2014). An investigation of university students’ collaborative inquiry learning behaviors in an augmented reality simulation and a traditional simulation. Journal of Science Education and Technology, 23, 682-691.

Dewi, I. S., Mashurin, A. H., Anidhea, N. O., Jauhariyah, M. N., Prahani, B. K., Safitri, N. S., & Mubarok, H. (2021, December). Bibliometric Analysis of Research Developments in the Field of Augmented Reality in Physics Education (2012-2021*). In International Joint Conference on Science and Engineering 2021 (IJCSE 2021) (pp. 471-478). Atlantis Press.

Al-Masarweh, R. Y. (2021). A Review of Augmented Reality in Physics Education and physics laboratory experiments (Applications, Advantages, Challenges). Turkish Online Journal of Qualitative Inquiry, 12(9).

Kitchenham, B., & Charters, S. (2007). Guidelines for performing systematic literature reviews in software engineering version 2.3. Engineering, 45(4ve), 1051.

Abdusselam, M. S., & Karal, H. (2020). The effect of using augmented reality and sensing technology to teach magnetism in high school physics. Technology, Pedagogy and Education, 29(4), 407-424.

Radu, I., & Schneider, B. (2019, May). What can we learn from augmented reality (AR)? Benefits and drawbacks of AR for inquiry-based learning of physics. In Proceedings of the 2019 CHI conference on human factors in computing systems (pp. 1-12).

Widyanti, R., Herlina, K., Zahara, M., & Agustina, L. (2021, February). Physics teachers’ perceptions and anxieties about the use of technology-integrated learning resources on magnetic field material: A preliminary research on augmented reality-integrated STEM learning. In Journal of Physics: Conference Series (Vol. 1796, No. 1, p. 012082). IOP Publishing.

Matsutomo, S., Miyauchi, T., Noguchi, S., & Yamashita, H. (2012). Real-time visualization system of magnetic field utilizing augmented reality technology for education. IEEE transactions on magnetics, 48(2), 531-534.

Harun, Tuli, N., & Mantri, A. (2020). Experience Fleming’s rule in electromagnetism using augmented reality: Analyzing impact on students learning. Procedia Computer Science, 172, 660-668.

Bakri, F., Sumardani, D., & Muliyati, D. (2019, December). The 3D simulation of Lorentz Force based on augmented reality technology. In journal of physics: Conference series (Vol. 1402, No. 6, p. 066038). IOP Publishing.

Abdüsselam, M. S. (2014). Teachers' and Students' Views on Using Augmented Reality Environments in Physics Education: 11th Grade Magnetism Topic Example. Pegem Journal of Education & Instruction/Pegem Egitim ve Ögretim, 4(1).

Buesing, M., & Cook, M. (2013). Augmented reality comes to physics. The Physics Teacher, 51(4), 226-228.

Radu, I., Huang, X., Kestin, G., & Schneider, B. (2023). How augmented reality influences student learning and inquiry styles: A study of 1-1 physics remote AR tutoring. Computers & Education: X Reality, 2, 100011.

Faridi, H., Tuli, N., Mantri, A., Singh, G., & Gargrish, S. (2021). A framework utilizing augmented reality to improve critical thinking ability and learning gain of the students in Physics. Computer Applications in Engineering Education, 29(1), 258-273.

Liu, X., Liu, Y., & Wang, Y. (2019, March). Real time 3d magnetic field visualization based on augmented reality. In 2019 IEEE Conference on Virtual Reality and 3D User Interfaces (VR) (pp. 1052-1053). IEEE.

Wang, Y. (2022). Effects of augmented reality game-based learning on students’ engagement. International Journal of Science Education, Part B, 12(3), 254-270.

Yu, S., Liu, Q., Ma, J., Le, H., & Ba, S. (2023). Applying Augmented reality to enhance physics laboratory experience: does learning anxiety matter?. Interactive Learning Environments, 31(10), 6952-6967.

Liu, Q., Xu, S., Yu, S., Yang, Y., Wu, L., & Ba, S. (2019, July). Design and Implementation of an AR-Based Inquiry Courseware—Magnetic Field. In 2019 International Symposium on Educational Technology (ISET) (pp. 134-138). IEEE.

Cai, S., Chiang, F. K., Sun, Y., Lin, C., & Lee, J. J. (2017). Applications of augmented reality-based natural interactive learning in magnetic field instruction. Interactive Learning Environments, 25(6), 778-791.

Ibáñez, M. B., De Castro, A. J., & Kloos, C. D. (2017, July). An empirical study of the use of an augmented reality simulator in a face-to-face physics course. In 2017 IEEE 17th International Conference on Advanced Learning Technologies (ICALT) (pp. 469-471). IEEE.

Ibáñez, M. B., Di Serio, Á., Villarán, D., & Kloos, C. D. (2014). Experimenting with electromagnetism using augmented reality: Impact on flow student experience and educational effectiveness. Computers & education, 71, 1-13.

Indra, M., Munadi, S., & Widari, T. (2023). The Correlation of Motivation and Habit with Learning Outcomes in New Normal Era. Jurnal Iqra': Kajian Ilmu Pendidikan, 8(1), 51-70.

Alhadi, S., & Saputra, W. N. E. (2017, May). The relationship between learning motivation and learning outcome of junior high school students in Yogyakarta. In 1st Yogyakarta International Conference on Educational Management/Administration and Pedagogy (YICEMAP 2017) (pp. 138-141). Atlantis Press.

Manalu, S. A. (2014). The relationship among motivation, attitudes, and learning achievement of English as a foreign language at Del Institute of Technology. Proceedings of ISELT FBS Universitas Negeri Padang, 2, 379-385.

Zahara, M., Abdurrahman, A., Herlina, K., Widyanti, R., & Agustiana, L. (2021, February). Teachers’ perceptions of 3D technology-integrated student worksheet on magnetic field material: A preliminary research on augmented reality in STEM learning. In Journal of Physics: Conference Series (Vol. 1796, No. 1, p. 012083). IOP Publishing.

Matsumoto, S., Manabe, T., Cingoski, V., & Noguchi, S. (2017). A Computer Aided Education System Based on Augmented Reality by Immersion to 3-D Magnetic Field. IEEE Transactrion on Magnetics, 53(6).

Sırakaya, M., & Alsancak Sırakaya, D. (2022). Augmented reality in STEM education: A systematic review. Interactive Learning Environments, 30(8), 1556-1569.

Arzak, K. A., & Prahani, B. K. (2023). Practicality of Augmented Reality Books in Physics Learning: A Literature Review. JPPS (Jurnal Penelitian Pendidikan Sains), 12(2), 138-154.




DOI: http://dx.doi.org/10.26737/jipf.v9i2.5159

Refbacks

  • There are currently no refbacks.


Copyright (c) 2024 venny haris, Siti Nursaila Alias, Shahrul Kadri Ayop

Creative Commons License
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

Publisher

Institute of Managing and Publishing of Scientific Journals
STKIP Singkawang

Jl. STKIP, Kelurahan Naram, Kecamatan Singkawang Utara, Kota Singkawang, Kalimantan Barat, Indonesia

Website: http://journal.stkipsingkawang.ac.id/index.php/JIPF
Email: [email protected]

 


JIPF Indexed by:

 

Copyright (c) JIPF (Jurnal Ilmu Pendidikan Fisika)

ISSN 2477-8451 (Online) and ISSN 2477-5959 (Print)