Technological developments influence educational changes. Various skills are needed to prepare society for the 21st Century. Educational robotics provides a comprehensive offering to provide the required skills and experience. This research aims for educators in an educational institution to know how robotics can be utilized in learning and teaching activities to provide convenience. Thus requiring any institution to be able to implement these skills in an institution, especially educational institutions. The type of research used is the study of literature/literature. Learning programs can be carried out by integrating Science, Technology, Engineering, and Mathematics/STEM and can be expanded with other subjects. The System Thinking Approach is a subject integration approach. The involvement of parents, teachers, university researchers, industry, and robotics course organizations is necessary for designing the robotics curriculum. The Approach Activity Template as a form of school operational curriculum can assist in the initial steps of program design. The Kurikulum Merdeka imposes a third of the learning load in an integrated manner and provides opportunities for robotics to be applied to create a Profil Pelajar Pancasila.

Abstrak

Perkembangan teknologi membawa pengaruh terhadap perubahan pendidikan. Berbagai keterampilan dibutuhkan untuk mempesiapkan masyarakat di Abad ke-21. Robotika pendidikan memberikan tawaran yang menyeluruh untuk membekalkan pengalaman keterampilan yang dibutuhkan. Tujuan dari penelitian ini adalah agar tenaga pendidik dalam sebuah institusi Pendidikan mengetahui bagaimana sebuah robotika dapat dimanfaatkan dalam pelaksanaan kegiatan belajar dan mengajar sehingga memberikan kemudahan pada setiap kegiatannya, Alasam dilakukan nya penelitian ini karena melihat peluang bagaimana masyarakat abad ke-21 mulai mengembangkan berbagai macam skill sehingga mengharuskan institusi manapun agar dapat mengimplementasikan keterampilan tersebut dalam sebuah institusi terutama institusi Pendidikan. Jenis penelitian yang digunakan adalah studi literatur/kepustakaan. Program pembelajaran dapat dilakukan melalui integrasi Science, Technology, Engineering, and Mathematics/STEM dan dapat diperluas dengan mata pelajaran lainnya. System Thinking Approach menjadi pendekatan integrasi mata pelajaran. Pelibatan orangtua, guru, peneliti universitas, industri, dan organisasi kursus robotika diperlukan dalam merancang kurikulum robotika. Approach Activity Template sebagai salah satu bentuk kurikulum operasional di sekolah dapat membantu langkah awal perancangan program. Kurikulum Merdeka membebankan sepertiga beban belajar dilakukan secara terintegrasi dan memberikan peluang bagi robotika diterapkan untuk menciptakan Profil Pelajar Pancasila.

Kata Kunci: Keterampilan abad 21; Kurikulum Merdeka; robotika pendidikan; system thinking approach

Angel-Fernandez, J. M., & Vincze, M. (2018). Towards a formal definition of educational robotics. Austrian Robotics Workshop, 1, 37-42.

Anwar, S., Bascou, N. A., Menekse, M., & Kardgar, A. (2019). A systematic review of studies on educational robotics. Journal of Pre-College Engineering Education Research, 9(2), 19-42.

Atmatzidou, S., & Demetriadis, S. (2016). Advancing students’ computational thinking skills through educational robotics: A study on age and gender relevant differences. Robotics and Autonomous Systems, 75, 661-670.

Bao, L., & Koenig, K. (2019). Physics education research for 21st century learning. Disciplinary and Interdisciplinary Science Education Research, 1(1), 1-12.

Ben-Bassat Levy, R., & Ben-Ari, M. (2018). The evaluation of robotics activities for facilitating STEM learning. Advances in Intelligent Systems and Computing, 630, 132-137.

Bertrand, M. G., & Namukasa, I. K. (2020). STEAM education: Student learning and transferable skills. Journal of Research in Innovative Teaching & Learning, 13(1), 43-56.

Çetin, M., & Demircan, H. Ö. (2020). Empowering technology and engineering for STEM education through programming robots: A systematic literature review. Early Child Development and Care, 190(9), 1323-1335.

Chalmers, C., & Nason, R. (2017). Systems thinking approach to robotics curriculum in schools. Robotics in STEM Education: Redesigning the Learning Experience, 1, 33-58

Chang, C. C., & Chen, Y. (2020). Using mastery learning theory to develop task-centered hands-on STEM learning of Arduino-based educational robotics: Psychomotor performance and perception by a convergent parallel mixed method. Interactive Learning Environments, 1, 1-16.

Ching, Y. H., Yang, D., Wang, S., Baek, Y., Swanson, S., & Chittoori, B. (2019). Elementary school student development of STEM attitudes and perceived learning in a STEM integrated robotics curriculum. TechTrends, 63(5), 590-601.

Chookaew, S., Howimanporn, S., Pratumsuwan, P., Hutamarn, S., Sootkaneung, W., & Wongwatkit, C. (2018). Enhancing high-school students’ computational thinking with educational robotics learning. Congress on Advanced Applied Informatics, 1, 204-208.

Dagienė, V., Futschek, G., & Stupurienė, G. (2019). Creativity in solving short tasks for learning computational thinking. Constructivist Foundations, 14(3), 382-396.

Eguchi, A. (2017). Robotics in STEM education. Robotics in STEM Education, 1(1), 3-32.

Ekawati, M. (2019). Teori belajar menurut aliran psikologi kognitif serta implikasinya dalam proses belajar dan pembelajaran. E-Tech, 7(2), 1-12.

Fridberg, M. & Redfors, A. (2021). Teachers’ and children’s use of words during early childhood STEM teaching supported by robotics. International Journal of Early Years Education, 29, 1-15.

Indarta, Y., Jalinus, N., Waskito, W., Samala, A. D., Riyanda, A. R., & Adi, N. H. (2022). Relevansi kurikulum merdeka belajar dengan model pembelajaran Abad 21 dalam perkembangan Era Society 5.0. Edukatif : Jurnal Ilmu Pendidikan, 4(2), 3011-3024.

Ioannou, A., & Makridou, E. (2018). Exploring the potentials of educational robotics in the development of computational thinking: A summary of current research and practical proposal for future work. Education and Information Technologies, 23(6), 2531-2544.

Irawati, D., Iqbal, A. M., Hasanah, A., & Arifin, B. S. (2022). Profil pelajar Pancasila sebagai upaya mewujudkan karakter bangsa. Edumaspul: Jurnal Pendidikan, 6(1), 1224-1238.

Johnson, J. (2003). Children, robotics, and education. Artificial Life and Robotics, 7(2), 16-21.

Jung, S. E., & Won, E. S. (2018). Systematic review of research trends in robotics education for young children. Sustainability, 10(4), 1-24.

Kopcha, T. J., McGregor, J., Shin, S., Qian, Y., Choi, J., Hill, R., Mativo, J., & Choi, I. (2017). Developing an Integrative STEM curriculum for robotics education through educational design research. Journal of Formative Design in Learning, 1(1), 31-44.

Lammer, L., Lepuschitz, W., Kynigos, C., Giuliano, A., & Girvan, C. (2017). ER4STEM educational robotics for science, technology, engineering and mathematics. Robotics in Education: Research and Practices for Robotics in STEM Education, 457, 95-101.

Lestariningrum, A. (2022). Konsep pembelajaran terdefirensiasi dalam kurikulum merdeka jenjang PAUD. Prosiding Semdikjar: Seminar Nasional Pendidikan dan Pembelajaran, 5, 1179-1184.

Merdan, M., Lepuschitz, W., Koppensteiner, G., & Balogh, R. (2016). Robotics in education research and practices for robotics in STEM education. Robotics in Education: Advances in Intelligent Systems and Computing, 457, 1-13.

Nur‘Inayah, N. (2021). Integrasi dimensi profil pelajar Pancasila dalam mata pelajaran pendidikan agama islam menghadapi era 4.0 di SMK Negeri Tambakboyo. Journal of Education and Learning Sciences, 1(1), 1-13.

Pilendia, D. (2020). Pemanfaatan Adobe Flash sebagai dasar pengembangan bahan ajar fisika: Studi literatur. Jurnal Tunas Pendidikan, 2(2), 1-10.

Rahmadayanti, D., & Hartoyo, A. (2022). Potret kurikulum merdeka, wujud merdeka belajar di sekolah dasar. Jurnal Basicedu, 6(4), 7174-7187.

Roussou, E., & Rangoussi, M. (2020). On the use of robotics for the development of computational thinking in Kindergarten: Educational intervention and evaluation. Robotics in Education: Current Research and Innovations, 1023, 31-44.

Sullivan, A., & Bers, M. U. (2016). Robotics in the early childhood classroom: Learning outcomes from an 8-week robotics curriculum in pre-kindergarten through second grade. International Journal of Technology and Design Education, 26(1), 3-20.

Susilowati, E. (2022). Implementasi kurikulum merdeka belajar pada mata pelajaran pendidikan agama Islam. Al-Miskawaih: Journal of Science Education, 1(1), 115-132.

Tsai, M. J., Wang, C. Y., Wu, A. H., & Hsiao, C. Y. (2021). The development and validation of the Roboticsl Learning Self-Efficacy Scale (RLSES). Journal of Educational Computing Research, 59(6), 1056-1074.

Tzagkaraki, E., Papadakis, S., & Kalogiannakis, M. (2021). Exploring the use of educational robotics in primary school and its possible place in the curricula. Educational Robotics International Conference, 982, 216-229.

Weng, C., Matere, I. M., Hsia, C. H., Wang, M. Y., & Weng, A. (2022). Effects of LEGO robotic on freshmen students’ computational thinking and programming learning attitudes in Taiwan. Library Hi Tech, 40(4), 947-962.

Widodo, A., Indraswati, D., & Sobri, M. (2019). Analisis nilai-nilai kecakapan abad 21 dalam buku siswa SD/MI kelas V sub tema 1 manusia dan lingkungan. Tarbiyah: Jurnal Ilmiah Kependidikan, 8(2), 125-134.

Witherspoon, E. B., Higashi, R. M., Schunn, C. D., Baehr, E. C., & Shoop, R. (2017). Developing computational thinking through a virtual robotics programming curriculum. ACM Transactions on Computing Education, 18(1), 1-20.

Yilmaz, M., Ozcelik, S., Yilmazer, N., & Nekovei, R. (2013). Design-oriented enhanced robotics curriculum. IEEE Transactions on Education, 56(1), 137-144.