Transformasi Pembelajaran Biologi Menggunakan Video Animasi: Dampaknya terhadap Motivasi dan Pemahaman Konsep Siswa Pada Materi Klasifikasi Makhluk Hidup

Authors

  • Shebianda Meiny Warow Universitas Negeri Manado
  • Aser Yalindua Universitas Negeri Manado
  • Zusje W. M. Warouw Universitas Negeri Manado

DOI:

https://doi.org/10.61132/jucapenbi.v2i2.401

Keywords:

Animated video, Biology learning outcomes, Classification of living beings, Learning motivation, Science learning

Abstract

Low motivation to learn and limited conceptual understanding are significant challenges in learning biology at the junior high school level, especially in abstract material on the classification of living things. This study aims to analyze the influence of the use of animated videos on student learning motivation and learning outcomes. A quantitative approach with a pre-experimental design of one group pre-test and post-test was used in this study. The research sample consisted of 25 students in grade VIII of SMP Negeri 2 East Likupang. Data was collected through observation sheets to assess learning motivation and pre-test and post-test tests to evaluate learning outcomes. The results of the observation showed that the average motivation of students reached 86.32% in the outstanding category. The average pre-test score of 59.57 increased to 81.09 on the post-test, indicating a significant improvement in concept comprehension. The t-test corroborates these findings with a significant value at a 95% confidence level. These results show that animated videos can present a visualization of complex concepts in an engaging and contextual way, thereby increasing students' focus, active participation, and absorption of the material. In addition, the use of this media also supports the development of students' collaborative skills and critical thinking. This research confirms that animated videos are a strategic alternative in effective science learning, especially in school environments with limitations of conventional visual media. It is suggested that the application of this media be expanded to various materials and levels of education.

References

Almeida, M., Santos, J., & Correia, M. (2021). Enhanced AES implementation for mobile security applications. Journal of Cybersecurity Research, 15(3), 45–62. https://doi.org/10.1016/j.jcr.2021.03.005

Anderson, R., et al. (2022). Real-time performance of AES in instant messaging apps. In Proceedings of the 15th International Conference on Security Engineering (pp. 134–145). IEEE.

Android Developers. (2023). Security best practices for app developers. https://developer.android.com/security

Brown, T., & Davis, K. (2021). Hardware acceleration for AES in mobile devices. In 2021 Crypto Engineering Conference (pp. 77–83). ACM.

Chen, X., Wang, L., & Zhang, Y. (2022). Optimizing AES-256 for low-power Android devices. IEEE Transactions on Mobile Computing, 21(4), 1125–1138. https://doi.org/10.1109/TMC.2021.3095432

Daemen, J., & Rijmen, V. (2020). The advanced encryption standard: A comprehensive review. Cryptography Today, 8(2), 78–95.

Ferguson, N., Schneier, B., & Kohno, T. (2020). Cryptography engineering: Design principles and practical applications (2nd ed.). Wiley.

Google Security Team. (2022). Android cryptographic algorithms. https://source.android.com/security/encryption

Gupta, P., & Sharma, R. (2021). Comparative analysis of cryptographic algorithms for mobile messaging. International Journal of Information Security, 19(3), 201–215.

International Data Corporation. (2023). Mobile security threat report 2023. IDC.

Johnson, M. (2023, March 15). Rising threats to mobile data security. The Tech Times, p. B3.

Kaur, J., & Kaur, M. (2022). Energy-efficient AES implementation on Android platform. Mobile Security Journal, 12(1), 33–47.

Kim, Y., & Park, J. (2023). Adaptive key management for AES in Android. In Proceedings of the 10th Asia-Pacific Security Symposium (pp. 92–101).

Lee, S., & Wong, K. (2023). ARM-based optimization techniques for AES encryption. Journal of Mobile Computing, 7(2), 89–104.

National Institute of Standards and Technology. (2021). Advanced encryption standard (AES) (FIPS PUB 197). U.S. Department of Commerce.

Patel, N., & Doshi, A. (2021). Security-performance tradeoff in mobile cryptography. IEEE Security & Privacy, 19(4), 55–68.

Roberts, E. (2022). Advanced cryptographic techniques for mobile platforms [Doctoral dissertation, Massachusetts Institute of Technology].

Satria, A., & Sutabri, T. (2024). Pengembangan pembelajaran virtual reality berbasis metaverse menggunakan metode ADDIE.

Smith, A., & Lee, B. (2022). System and method for optimized AES implementation on mobile devices (U.S. Patent No. US11223344B2). U.S. Patent and Trademark Office.

Stallings, W. (2021). Cryptography and network security: Principles and practice (8th ed.). Pearson.

Sutabri, T. (2012). Konsep sistem informasi. Penerbit Andi.

Sutabri, T., & Napitupulu, D. (2019). Sistem informasi bisnis. Penerbit Andi.

Zhang, H., et al. (2022). Power-aware cryptographic solutions for Android applications. ACM Transactions on Mobile Technology, 11(3), 1–18.

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Published

2025-06-11

How to Cite

Shebianda Meiny Warow, Aser Yalindua, & Zusje W. M. Warouw. (2025). Transformasi Pembelajaran Biologi Menggunakan Video Animasi: Dampaknya terhadap Motivasi dan Pemahaman Konsep Siswa Pada Materi Klasifikasi Makhluk Hidup. Jurnal Cakrawala Pendidikan Dan Biologi, 2(2), 204–217. https://doi.org/10.61132/jucapenbi.v2i2.401

Issue

Vol. 2 No. 2 (2025): Juni : Jurnal Cakrawala Pendidikan dan Biologi

Section

Articles

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Copyright (c) 2025 Jurnal Cakrawala Pendidikan dan Biologi

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

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