Cerebral Palsy (CP) affects fine motor development, causing obstacles in daily activities. Existing assistive technologies are often not interactive or adaptive enough, hindering independent learning in children with CP. Fine motor issues in learning are also related to a lack of engaging exercise methods. This research develops assistive technology based on visual feedback and computer vision as an innovative solution to improve fine motor skills in children with CP. This technology utilizes motion sensors for real-time visual feedback, helping children understand and correct movements effectively. The Research and Development (R&D) method was employed, focusing on needs analysis, design, and prototype development using the ADDIE model. Validation results demonstrated the system's feasibility and effectiveness. Subject matter experts scored an average of 3.75, media experts 3.5, and education practitioners 3.67. Trials at SLB ACD Pertiwi Mojokerto showed increased motivation and engagement among children during exercises. This technology is expected to become an effective solution for motor and coordination exercises at school and at home, motivating children with CP to practice and develop their motor skills.

Cerebral palsy, Assistive technology, Fine motor, Motion sensor

Aarts, P. B., van Hartingsveldt, M., Anderson, P. G., van den Tillaar, I., van der Burg, J., & Geurts, A. C. (2012). The Pirate Group Intervention Protocol: Description and a Case Report of a Modified Constraint‐Induced Movement Therapy Combined with Bimanual Training for Young Children with Unilateral Spastic Cerebral Palsy. Occupational therapy international, 19(2), 76-87.

Balf, C. L., & Ingram, T. T. S. (1955). Problems in the Classification of Cerebral Palsy in Childhood. British Medical Journal, 2(4932), 163.

Bhatt, D., Patel, C., Talsania, H., Patel, J., Vaghela, R., Pandya, S., ... & Ghayvat, H. (2021). CNN Variants for Computer Vision: History, Architecture, Application, Challenges and Future Scope. Electronics, 10(20), 2470.

Clark, C. N. (2020). Intelligent Clinical Augmentation: Developing a Novel Socially Assistive Robot for Children with Cerebral Palsy (Doctoral dissertation, University of Colorado at Denver).

Dewantoro, D. A., Susilawati, S. Y., & Pradipta, R. F. (2018). Family Environment Support in Early Intervention of Children with Cerebral Palsy. In 1st International Conference on Early Childhood and Primary Education (ECPE 2018) (pp. 30-33). Atlantis Press.

Eliasson, A. C., Krumlinde‐Sundholm, L., Gordon, A. M., Feys, H., Klingels, K., Aarts, P. B., ... & Hoare, B. (2014). Guidelines for Future Research in Constraint‐Induced Movement Therapy for Children with Unilateral Cerebral Palsy: An Expert Consensus. Developmental Medicine & Child Neurology, 56(2), 125-137.

Elnaggar, R. K. (2022). Effects of Plyometric Exercises on Muscle-Activation Strategies and Response-Capacity to Balance Threats in Children with Hemiplegic Cerebral Palsy. Physiotherapy Theory and Practice, 38(9), 1165-1173.

Gelkop, N., Burshtein, D. G., Lahav, A., Brezner, A., Al-Oraibi, S., Ferre, C. L., & Gordon, A. M. (2015). Efficacy of Constraint-Induced Movement Therapy and Bimanual Training in Children with Hemiplegic Cerebral Palsy in an Educational Setting. Physical & occupational therapy in pediatrics, 35(1), 24-39.

Hsiao, H. S., & Chen, J. C. (2016). Using a Gesture Interactive Game-Based Learning Approach To Improve Preschool Children's Learning Performance And Motor Skills. Computers & Education, 95, 151-162.

Lee, K., Oh, H., & Lee, G. (2022). Fully Immersive Virtual Reality Game-Based Training for an Adolescent with Spastic Diplegic Cerebral Palsy: A Case Report. Children, 9(10), 1512.

Rhoads, M. C., Da Matta, G. B., Larson, N., & Pulos, S. (2014). A Meta-Analysis of Visual Feedback for Motor Learning. Athletic insight, 6(1), 17.

Rosita, T., Rochyadi, E., & Sunardi, S. (2020). Teknologi Asistif dalam Pendidikan Inklusif. COLLASE (Creative of Learning Students Elementary Education), 3(6), 301-307.

Rothstein, A. L., & Arnold, R. K. (1976). Bridging the Gap: Application of Research Onvideotape Feedback and Bowling. Motor Skills: Theory into Practice, 1, 36-63.

Saunders, J. A., & Knill, D. C. (2004). Visual Feedback Control of Hand Movements. Journal Of Neuroscience, 24(13), 3223-3234.

Sujarwanto, S., Purwoko, B., Setiawan, B., & Adhe, K. R. (2023, March). Virtual Reality Development for the Physically Disabled. In International Joint Conference on Arts and Humanities 2022 (IJCAH 2022) (pp. 551-559). Atlantis Press.

Yu, W., Yang, C., McGreavy, C., Triantafyllidis, E., Bellegarda, G., Shafiee, M., ... & Li, Z. (2023). Identifying Important Sensory Feedback for Learning Locomotion Skills. Nature Machine Intelligence, 5(8), 919-932.