Students often struggle with conceptual understanding and project-based skills in physics, particularly in abstract topics such as optical instruments. Traditional teaching methods and limited visualization tools contribute to these difficulties. This study addresses the need for innovative instructional resources by developing digital teaching materials integrated with Augmented Reality (AR) to enhance learning outcomes. This research employed a Research and Development (R&D) approach following the ADDIE model (Analysis, Design, Development, Implementation, and Evaluation). Instruments included a needs analysis questionnaire, expert validation sheets, and student practicality questionnaires. Descriptive statistics were used to analyze the data, with validation assessed using Aiken’s V and practicality evaluated using a Likert scale. The developed digital teaching materials underwent expert validation across five components: material substance, visual communication, learning design, software utilization, and AR integration. The average Aiken’s V score was 0.94, indicating high validity. Practicality testing with 35 grade XI students yielded an average score of 96, categorized as "very practical," showing the teaching materials were easy to use, engaging, and beneficial for learning. The findings support the potential of AR-based teaching materials to address conceptual gaps and foster student engagement. While validity and practicality were confirmed, further research is needed to measure effectiveness in improving learning outcomes. The AR-integrated digital teaching materials are valid and practical for supporting students' conceptual understanding and project skills in optical physics. These materials represent a promising tool for modernizing physics instruction in secondary education.

Digital Teaching Materials; Optical Instruments; Augmented Reality; Conceptual Understanding; Project Skills

Adriani, D., Lubis, P., & Triono, M. (2020). Teaching Material Development of Educational Research Methodology with ADDIE Models. 1. https://doi.org/10.4108/eai.4-12-2019.2293793

Amrullah, S. N. K. (2015). Pengembangan Media Pembelajaran Online Berbasis Scratch pada Pokok Bahasan Getaran.

Aryanta, I. K. D. (2021). Pengembangan “Bugar” Fisika Untuk Meningatkan Pemahaman Konsep Siswa. 1(1), 12–17.

Asrizal, Desnita, & Darvina, Y. (2020). Need Analysis to Develop Electronic Enrichment Book of Physics Based on Contextual Teaching and Environmental Potential. Journal of Physics: Conference Series, 1481(1).

Asrizal, Yurnetti, & Usman, E. A. (2022). ICT Thematic Science Teaching Material with 5E Learning Cycle Model to Develop Students’ 21St-Century Skills. Jurnal Pendidikan IPA Indonesia, 11(1), 61–72.

Azwar, S. (2015). Penyusunan Skala Psikologi Edisi 2. Pustaka Belajar.

Brainard, R., & Britten, J. (2023). Impact of Deep Reading in Case-Based Learning in Graduate Physiology Students. In Physiology (Vol. 38, Issue S1).

Branch, R. M. (2010). Instructional Design: The ADDIE Approach. Instructional Design: The ADDIE Approach, 1–203.

Cahyadi, R. A. H. (2019). Pengembangan Bahan Ajar Berbasis Addie Model. Halaqa: Islamic Education Journal, 3(1), 35–42.

Direktorat Pembinaan SMA. (2010). Juknis Pengembangan Bahan Ajar SMA. In Juknis Pengembangan Bahan Ajar. Depdiknas.

Fajriati, D. Y., & Putra, A. (2023). Validity and Practicality of Animation Video-Based Learning Media on Various Forces and Inertial Properties of Objects. Physics Learning and Education, 1(3), 137–145.

Fikri, H. (2020). Penilaian Keterampilan Proyek. Borneo: Journal of Islamic Studies, 3(2), 156–165.

Hafi, N. N., & Supardiyono. (2018). Pengembangan Buku Saku Fisika dengan Teknologi Augmented Reality Berbasis Android pada Materi Pemanasan Global. Inovasi Pendidikan Fisika, 07(02), 306–310.

Hidayat, A. G., & Haryati, T. (2025). Analisis Efektivitas Pembelajaran Menggunakan Pendekatan Deep Learning pada Sekolah Dasar. Kurikula: Jurnal Pendidikan, 9(2), 126–139.

Indrawaty, Y., Ichwan, M., & Putra, W. (2014). Media Pembelajaran Interaktif Pengenalan Anatomi Manusia Menggunakan Metode Augmented Reality (AR). Jurnal Itena Library, 4(4).

Katolik, U., & Mandira, W. (n.d.). Integrasi Pembelajaran Fisika Berbasis Proyek Untuk Meningkatkan Keterampilan Berpikir Kreatif Siswa Pada Materi Mekanika Fluida. 174–179.

Kencana, H. P., Iswanto, B. H., & Wibowo, F. C. (2021). Augmented Reality Geometrical Optics (AR-Gios) For Physics Learning In High Schools. Journal of Physics: Conference Series, 2019(1).

Lazoudis, A., Salmi, H., & Sotiriou, S. (2011). The “Science Center To Go” project. In Augmented Reality in Education.

Lazuardy, S. (2012). Augmented Reality: Masa Depan Interaktivitas. https://doi.org/Http://Tekno. Kompas. Com/Read/2012/04/09/12354384/Augmente d. Reality. Masa. Depan. Interaktivitas.

Liu, B., Wan, X., Li, X., Zhu, D., & Liu, Z. (2024). An Augmented Reality Serious Game for Children’s Optical Science Education: Randomized Controlled Trial. JMIR Serious Games, 12(1), 1–13.

Mauludin, R., Sukamto, A. S., & Muhardi, H. (2017). Penerapan Augmented Reality Sebagai Media Pembelajaran Sistem Pencernaan pada Manusia dalam Mata Pelajaran Biologi. Jurnal Edukasi Dan Penelitian Informatika (JEPIN), 3(2), 117.

Meilani, G. R. (2018). Membangun Aplikasi Augmented Reality Dengan Unity. CV Garuda Mas Sejahtera.

Nusroh, H., Khalif, M. A., & Saputri, A. A. (2022). Developing Physics Learning Media Based on Augmented Reality to Improve Students’ Critical Thinking Skills. Physics Education Research Journal, 4(1), 23–28.

Prastowo, A. (2015). Panduan Kreatif Membuat Bahan Ajar Inovatif . Yogyakarta: Diva Press.

Pratiwi, M. A., & Jasril, I. R. (2020). Pengaruh Penggunaan Macromedia Flash 8.0 Terhadap Hasil Belajar Dasar Listrik Dan Elektronika. Voteteknika (Vocational Teknik Elektronika Dan Informatika), 7(4), 122.

Ratiyani, I., Subchan, W., & Hariyadi, S. (2014). Pengembangan Bahan Ajar Digital dan Aplikasinya dalam Model Siklus Pembelajaran 5E (Learning Cycle 5E) Terhadap Aktifitas dan Hasil Belajar (Siswa Kelas VII DI SMP Negeri 10 Probolinggo Tahun Pelajaran 2012/2013). Pancaran, 3(1), 79–88.

Rindaryati, N. (2021). E-Modul Counter Berbasis Flip Pdf pada Mata Pelajaran Penerapan Rangkaian Elektronika. Jurnal Imiah Pendidikan Dan Pembelajaran, 5(2), 192.

Samsudin, R., Sulaiman, R., Guan, T. T., Yusof, A. M., Firdaus, M., & Yaacob, C. (2021). Mobile Application Development Trough ADDIE Model. In International Journal of Academic Research in Progressive Education and Development (Vol. 10, Issue 2).

Sanaky, H. A. (2013). Media pembelajaran interaktif-inovatif. Yogyakarta: Kaukaba Dipantara.

Saputri, I., & Asrizal, A. (2023). Needs Analysis for Development of Digital Teaching Materials With Augmented Reality for Optical Instruments Materials. Physics Learning and Education, 1(3), 146–153.

Sari, F. F. K., & Atmojo, I. R. W. (2021). Analisis Kebutuhan Bahan Ajar Digital Berbasis Flipbook untuk Memberdayakan Keterampilan Abad 21 Peserta Didik pada Pembelajaran IPA Sekolah Dasar. Jurnal Basicedu, 5(6), 6079–6085.

Sriwahyuni, I., Risdianto, E., & Johan, H. (2019). Pengembangan Bahan Ajar Elektronik Menggunakan Flip Pdf Professional Pada Materi Alat-Alat Optik Di Sma. Jurnal Kumparan Fisika, 2(3), 145–152.

Sudjana. (2002). Metode Statistika. Bandung: Tarsito.

Sugiarto, A. (2022). Penggunaan Media Augmented Reality Assemblr Edu untuk Meningkatkan Pemahaman Konsep Peredaran Darah. Madaris: Jurnal Guru Inovatif, Januari 2022, 1-13

Sugihartini, N., & Yudiana, K. (2018). Addie Sebagai Model Pengembangan Media Instruksional Edukatif (Mie) Mata Kuliah Kurikulum Dan Pengajaran. Jurnal Pendidikan Teknologi Dan Kejuruan, 15(2), 277–286.

Sugiyono. (2019). Metode Penelitian Kuantitatif Kualitatif dan R&D. Alfabeta.

Teguh Martono, K. (2011). Augmented Reality sebagai Metafora Baru dalam Teknologi Interaksi Manusia dan Komputer. Jurnal Sistem Komputer, 1(2), 60–64.

Wulandari, R., Widodo, A., & Rochintaniawati, D. (2020). Penggunaan Aplikasi Augmented Reality Untuk Memfasilitasi Penguasaan Konsep Dan Keterampilan Berpikir Kreatif Peserta Didik. Jurnal Pendidikan Biologi, 11(2), 59.