In Physics education, experiments play a crucial role in students' cognitive activities, showcasing the characteristic of Physics as an empirical science. The effective use and application of information technology and digital tools in teaching are efficient solutions for innovating teaching and learning methods, aiming to develop students' capabilities, including problem-solving skills. The research objective of this project is to construct a measurement system and utilize experiments with the AddeStation computer interface system in teaching Oscillatory Motion in Physics 11. The theoretical foundation research method is employed to design the teaching process and construct an assessment toolset. The current situation investigation method is used to assess the usage status of equipment in teaching Oscillatory Motion in high schools within the Yen Bai province. The experimental method is employed to collect data and qualitatively and quantitatively analyze the effectiveness of the experiments and the teaching process that has been developed. The results indicate that the use of the seven experiments constructed during the teaching of Oscillatory Motion is feasible and contributes to the development of students' problem-solving abilities.

Experiments; Computer interface; Oscillatory motion; AddeStation; Physics 11

[1] Ministry of Education and Training, General Education Physics Program issued with Circular No. 32/2018/TT-BDGĐT on December 26, 2018, 2018.

[2] N. H. Nguyen (Editor), X. T. Nguyen, and A. T. Nguyen, Guidance on Using Laboratory Equipment in Teaching High School Physics, Hanoi University of Education Publishing House, 2014.

[3] N. H. Nguyen, “Some directions on the method of using teaching physics equipment,” Journal of Educational Research, no. 5, pp. 29-30,1998.

[4] X. Q. Pham, “Design and construction of a computer-connected experimental kit and software support for harmonic oscillation investigation - Physics class 12,” Journal of Educational Research, no. 135, pp. 37-38, 2006.

[5] Steinberg, “Effect of computer-based laboratory instruction on future teachers’ understanding of nature of science,” JI. of Computers in Mathematics and Science Teaching, no. 22, pp. 185-205, 2023.

[6] Bernhard, “Physics Learning and Microcomputer Based Laboratory (MBL) - Learning effects of using MBL as a technological and as a cognitive tool,” Science Education Research in the Knowledge Based Society, Thessanoliki, pp. 21-25, 2001.

[7] L. Hucke and H. E. Fischer, “The Link of Theory and Practice in Traditional and in Computer-based University Laboratory Experiments,” Teaching and Learning in the Science Laboratory, vol. 16, pp. 205-218, 2002.

[8] D. E. P. Nggadas and A. Ariswan, “The mastery of physics concepts between students are learning by ICT and laboratory experiments based teaching,” Momentum: Physics Education Journal, vol. 3, no. 1, pp. 21-31, 2019.

[9] R. Trumper and Gelbman, “Investigating electromagnetic induction trough a minicomputer-based laboratory,” Phy. Educ., no. 35, pp. 90-95, 2000.