The main problem in the manufacturing process in vocational schools is the limited number of manufacturing machines for the practical process because the equipment is very expensive. Therefore, the main objective of this activity is to provide training on manufacturing processes both theoretically and experimentally to vocational high school students in Tasikmalaya City. The results of this activity indicate that vocational high school students gain experience and knowledge in operating manufacturing machinery from start to finish.

Abizar, H., Fawaid, M., Nurtanto, M., Nurhaji, S., & Setiyani, S. (2021). Local Wisdom-Based 4-ON (Vision, Action, Passion, and Collaboration) Model in Competencies of Machining technique in Vocational Secondary Schools. Jurnal Pendidikan Teknologi dan Kejuruan, 27(1), 48-56.

Baronio, G., Motyl, B., & Paderno, D. (2016). Technical drawing learning tool‐level 2: An interactive self‐learning tool for teaching manufacturing dimensioning. Computer Applications in Engineering Education, 24(4), 519-528.

Bradley, R. K. (2022). Education in plastics manufacturing: Aluminum mold making and injection molding. International Journal of Mechanical Engineering Education, 50(3), 726-738.

Bull, G., Haj-Hariri, H., Atkins, R., & Moran, P. (2015). An educational framework for digital manufacturing in schools. 3D Printing and Additive Manufacturing, 2(2), 42-49.

Gomez, E., Caja, J., Barajas, C., Maresca, P., & Berzal, M. (2008). Development and application of a new interactive model for the teaching of manufacturing engineering technology. The International journal of engineering education, 24(5), 1018-1030.

Hung, W. N. P., & Leon, V. J. (2005). Manufacturing education and research at Texas A&M University: Responding to global trends. Journal of Manufacturing Systems, 24(3), 153-161.

Jackson, S., Wilson, J. R., & MacCarthy, B. L. (2004). A new model of scheduling in manufacturing: Tasks, roles, and monitoring. Human factors, 46(3), 533-550.

Jiang, A., Wang, F., Xia, D., Li, M., Qiang, L., Zhu, Z., ... & Yang, Y. (2019). Aluminum nanoparticles manufactured using a ball-milling method with ammonium chloride as a grinding aid: achieving energy release at low temperature. New Journal of Chemistry, 43(4), 1851-1856.

Jeong, Y. G., Lee, W. S., & Lee, K. B. (2018). Accuracy evaluation of dental models manufactured by CAD/CAM milling method and 3D printing method. The journal of advanced prosthodontics, 10(3), 245-251.

Lee, W. S., Lee, D. H., & Lee, K. B. (2017). Evaluation of internal fit of interim crown fabricated with CAD/CAM milling and 3D printing system. The journal of advanced prosthodontics, 9(4), 265-270.

Lund, H. B., & Karlsen, A. (2020). The importance of vocational education institutions in manufacturing regions: adding content to a broad definition of regional innovation systems. Industry and Innovation, 27(6), 660-679.

Martawijaya, D. H. (2012). Developing a teaching factory learning model to improve production competencies among mechanical engineering students in a vocational senior high school. Journal of Technical Education and Training, 4(2), 45-56.

Megri, A. C., Hamoush, S., Megri, I. Z., & Yu, Y. (2021). Advanced Manufacturing Online STEM Education Pipeline for Early-College and High School Students. Journal of Online Engineering Education, 12(2), 01-06.

Periyanan, P. R., Natarajan, U., & Yang, S. H. (2011). A study on the machining parameters optimization of micro-end milling process. International Journal of Engineering, Science and Technology, 3(6), 237-246.

Plambeck, E., & Ramdas, K. (2020). Alleviating poverty by empowering women through business model innovation: Manufacturing & service operations management insights and opportunities. Manufacturing & Service Operations Management, 22(1), 123-134.

Rahdiyanta, D., Anggoro, Y., Wijanarka, B. S., & Sasongko, B. T. (2020). The development of interactive learning media by manufacturing helical gear using milling machine. Journal of Physics: Conference Series, 1446(1), 012012.

Rosen, D. (2014). Design for additive manufacturing: past, present, and future directions. Journal of Mechanical Design, 136(9), 090301.

Simpson, T. W., Williams, C. B., & Hripko, M. (2017). Preparing industry for additive manufacturing and its applications: Summary & recommendations from a National Science Foundation workshop. Additive Manufacturing, 13, 166-178.

Sutton, A., Bosky, A., & Muller, C. (2016). Manufacturing gender inequality in the new economy: High school training for work in blue-collar communities. American sociological review, 81(4), 720-748.

Urgo, M., Terkaj, W., Mondellini, M., & Colombo, G. (2022). Design of serious games in engineering education: An application to the configuration and analysis of manufacturing systems. CIRP Journal of Manufacturing Science and Technology, 36, 172-184.

Wibisono, G., Wijanarka, B. S., & Theophile, H. (2020). The Link and Match between the Competency of Vocational High Schools Graduates and the Industry on CAD/CAM and CNC. Jurnal Pendidikan Teknologi dan Kejuruan, 26(1), 26-34.

Yudiono, H., Sumbodo, W., Salim, S., & Setiadi, R. (2019). Improving the milling machine competency learning outcomes through industrial project-based learning for vocational school students. Jurnal Pendidikan Vokasi, 9(2), 151-160.

Zhu, W., Fan, X., Brake, N., Liu, X., Li, X., Zhou, J., ... & Yoo, J. (2018). Engineering design and manufacturing education through research experience for high school teachers. Procedia Manufacturing, 26, 1340-1348.