Validitas Perangkat Pembelajaran Fisika Flipped Classroom Learning Cycle 5E Inquiry Berorientasi HOTS


  • Dens E. S. I. Asbanu Institut Pendidikan SoE
  • Landiana Laos Institut Pendidikan SoE



flipped classroom, HOTs, Inquiry, learning cycle 5E, work, and energy


This research aims to produce valid and reliable flipped classroom learning cycle 5E Inquiry physics learning devices that are suitable for use in learning. The research method is quantitative. The research subjects were learning tools, namely lesson plans, worksheets, and test instruments. The learning device validators consist of five people from expert elements of physics lecturers and teachers as practitioners. Data collection techniques used validation questionnaires. The data analysis technique used descriptive quantitative with the Aiken formula and percentage of agreement. The learning device is declared valid if the value of V aspects assessed is > 0.80 on the criteria of high validity and is reliable with a percentage of agreement > 75%. The results showed that the lesson plans, worksheets, and test instruments with a validity value of > 0.80 and a percentage of agreement > 75% meant they were reliable. Thus, it is concluded that the learning tools are valid and reliable so that they are suitable for use in learning. It is suggested that this learning tool can be used as an alternative solution to increase the HOTS of junior high school students.


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Aliffianto, A., Nur, M., & Madlazim, M. (2018). Validity and Effectiveness of Physics Learning Package based on Guided-Inquiry to Improve Science Process Skills of Senior High School Student. 157(Miseic), 35–37.

Alonzo, S. M. D., & Mistades, V. M. (2021). Students’ conceptual understanding and problem-solving of the Work-Energy and Impulse-Momentum Theorems in a flipped classroom. Journal of Physics: Conference Series, 1882(1).

Aşıksoy, G. (2018). The effects of the gamified flipped classroom environment (GFCE) on students’ motivation, learning achievements and perception in a physics course. Quality and Quantity, 52, 129–145.

Basriyah, K., Sulisworo, D., Maruto, G., Toifur, M., & Abd Rahman, N. H. (2020). Effects of the flipped classroom on understanding the thermodynamic concept at high school students. Universal Journal of Educational Research, 8(3 B), 51–58.

Dehghani, M., Sani, H. J., Pakmehr, H., & Malekzadeh, A. (2011). Relationship between students’ critical thinking and self-efficacy beliefs in Ferdowsi University of Mashhad, Iran. Procedia - Social and Behavioral Sciences, 15, 2952–2955.

Gloudemans, H. A., Schalk, R. M. J. D., & Reynaert, W. (2013). The relationship between critical thinking skills and self-efficacy beliefs in mental health nurses. Nurse Education Today, 33(3), 275–280.

Gurcay, D., & Ferah, H. O. (2018). High School Students’ Critical Thinking Related to Their Metacognitive Self-Regulation and Physics Self-Efficacy Beliefs. Journal of Education and Training Studies, 6(4), 125.

Hayati, S., & Lailatussaadah, L. (2016). Validitas Dan Reliabilitas Instrumen Pengetahuan Pembelajaran Aktif, Kreatif Dan Menyenangkan (Pakem) Menggunakan Model Rasch. Jurnal Ilmiah Didaktika, 16(2), 169.

Jauhariyah, M. N. R., Sunarti, T., Wasis, Supardiyono, Setyarsih, W., & Zainuddin, A. (2021). Analysis of physics questions based on HOTS criteria: The result of physics teacher training. Journal of Physics: Conference Series, 1805(1).

Jdaitawi, M. (2020). Does Flipped Learning Promote Positive Emotions in Science Education ? A Comparison between Traditional and Flipped Classroom Approaches. 18(6), 516–524.

Kalender, Z. Y., Marshman, E., Schunn, C. D., Nokes-Malach, T. J., & Singh, C. (2020). Damage caused by women’s lower self-efficacy on physics learning. Physical Review Physics Education Research, 16(1), 10118.

Lazendic-Galloway, J., Fitzgerald, M., & McKinnon, D. H. (2016). Implementing a studio-based flipped classroom in a first year astronomy course. International Journal of Innovation in Science and Mathematics Education, 24(5), 35–47.

Love, B., Hodge, A., Grandgenett, N., & Swift, A. W. (2014). Student learning and perceptions in a flipped linear algebra course. International Journal of Mathematical Education in Science and Technology, 45(3), 317–324.

Muktar Mutia, H. K. (n.d.). Modul Penyusunan Soal Ketrampilan Berpikir Tingkat Tinggi (Higher Order Thinking Skills) Fisika 主 (J. Hadi Samsul, Abdi (ed.)).

Rafon, J. E., & Mistades, V. M. (2020). Interactive engagement in rotational motion via flipped classroom and 5e instructional model. International Journal of Information and Education Technology, 10(12), 905–910.

Riduwan. (2012). Metode & Teknik Menyusun Proposal Penelitian. Alfabeta.

Sani, I. N., Bahar, A., Kimia, P., & Bengkulu, U. (2020). PERBANDINGAN MODEL PEMBELAJARAN PROBLEM SOLVING DAN PROBLEM BASED LEARNING TERHADAP KEMAMPUAN BERPIKIR KRITIS SISWA KELAS XI MIA MAN 2 KOTA BENGKULU PENDAHULUAN Ilmu kimia merupakan salah satu cabang dari Ilmu Pengetahuan Alam ( IPA ) yang baru dipelajari. 4(2), 107–116.

Saputri, A. C., Sajidan, Rinanto, Y., Afandi, & Prasetyanti, N. M. (2019). Improving students’ critical thinking skills in cell-metabolism learning using Stimulating Higher Order Thinking Skills model. International Journal of Instruction, 12(1), 327–342.

Saputro, A. D., Atun, S., Wilujeng, I., Ariyanto, A., & Arifin, S. (2020). Enhancing pre-service elementary teachers’ self-efficacy and critical thinking using problem-based learning. European Journal of Educational Research, 9(2), 765–773.

Schallert, S., Lavicza, Z., & Vandervieren, E. (2020). Merging flipped classroom approaches with the 5E inquiry model: a design heuristic. International Journal of Mathematical Education in Science and Technology, 0(0), 1–18.

Setiawan, A., Malik, A., Suhandi, A., & Permanasari, A. (2018). Effect of Higher Order Thinking Laboratory on the Improvement of Critical and Creative Thinking Skills. IOP Conference Series: Materials Science and Engineering, 306(1).

Siu-Ping, N., & Chak-Him, F. (2020). Flipped Classroom With Simulation Assists Students Learning the Vector Knowledge. Journal of Education and Training Studies, 8(12), 35.

Skills, C., & Education, P. (2018). 21st Century Skilss Journal. 11(3), 1–16.

Sulisworo, D., Basriyah, K., Sari, L., & Toifur, M. (2019). Comparing the Effectiveness of Flipped Classroom and Online Learning on Improving Critical Thinking Skills in High School Physics Learning. 349(Iccd), 645–649.

Talmi, I., Hazzan, O., & Katz, R. (2018). Intrinsic Motivation and 21st-Century Skills in an Undergraduate Engineering Project : The Formula Student Project. 8(4), 46–58.

Torío, H. (2019). Journal of Technology and Science Education. 9(3), 404–419.

Ugwuanyi, C. S., Nduji, C. C., Elejere, U. C., & Omeke, N. E. (2020). Effect of Flipped Classroom and Think Pair Share Strategy on Achievement and Retention Among Senior Secondary School Physics Students. International Journal of Sciences: Basic and Applied Research, 52(2), 136–148.


Voigt, M., Fredriksen, H., & Rasmussen, C. (2020). Leveraging the design heuristics of realistic mathematics education and culturally responsive pedagogy to create a richer flipped classroom calculus curriculum. ZDM - Mathematics Education, 52(5), 1051–1062.

Wahyuningsih, Y., Rchmawati, I., Setiawan, A., & Ngazizah, N. (2018). HOTS (Higher Order Thinking Skills) dan Kaitannya dengan Keterampilan Generik SAINS dalam Pembelajaran IPA SD. Prosiding Seminar Nasional Pendidikan Dasar, 227–234.

Yüksel, G., & Alcı, B. (2012). Self-efficacy and critical thinking dispositions as predictors of success in school practicum. International Online Journal of Educational Sciences, 4(1), 81–90.




How to Cite

Asbanu , D. E. S. I., & Laos, L. (2023). Validitas Perangkat Pembelajaran Fisika Flipped Classroom Learning Cycle 5E Inquiry Berorientasi HOTS. JIPFRI (Jurnal Inovasi Pendidikan Fisika Dan Riset Ilmiah), 7(1), 12–19.



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