Resumen
Se presenta el prototipo virtual y el físico de un exoesqueleto para niños de entre 6 y 12 años, diseñado con base en el análisis funcional de requerimientos, considerando que tenga la posibilidad de ajustarse conforme al crecimiento del usuario, además de adaptarse para realizar el ciclo básico de la marcha con base en las restricciones que presente la discapacidad del paciente. Su característica principal es el ajuste para las diferentes longitudes que forman las extremidades inferiores de los niños (fémur, tibia y pie). Como resultado se tiene la parte mecánica validada por el análisis cinemático y dinámico realizados en los programas ADAMSView™ y Matlab ®, además de las simulaciones del sistema de control en el prototipo virtual. También se presenta el prototipo experimental y los resultados de pruebas preliminares de funcionamiento mecánico.
Palabras Clave: exoesqueleto, miembro inferior, configurable, niños.

Abstract
The virtual and the real prototype of an exoskeleton for children between 6 and 12 years old is presented, designed based on the functional analysis of requirements, considering that it has the possibility of adjusting according to the development of the user, in addition to adapting to perform the basic gait cycle based on the restrictions that present the patient's disability. Its main feature is the adjustment for the different lengths that form the lower limbs of children (femur, tibia, and foot). As a result, the mechanical part validated by the kinematic and dynamic analysis performed in the ADAMSView™ and Matlab ® programs, in addition to the control system simulations in the virtual prototype, is available. The experimental prototype and preliminary mechanical operation test results are also presented.
Keywords: exoskeleton, lower limb, configurable, children.

Bayon C., Raya R., Lara S. L., Ó. Ramírez, I. S. J, and Rocon E., Robotic Therapies for Children with Cerebral Palsy: A Systematic Review, Transl. Biomed., vol. 7, no. 1, pp. 1–10, 2016.

Blanco Ortega A., Magadán Salazar A., Gómez Becerra F. A., Guzmán Valdivia C. H., and Antúnez Leyva E., Diseño de sistemas mecatrónicos: prototipos virtuales, Pistas Educativas, vol. 40, enero 2019, pp. 1421–1439, 2018.

Canela M., Ama A. J., and Pons J. L., Design of a Pediatric Exoskeleton for the Rehabilitation of the Physical Disabilities Caused by Cerebral Palsy, vol. 1, pp. 255–258, 2013.

Cestari M., Sanz-Merodio D., and Garcia E., A New and Versatile Adjustable Rigidity Actuator with Add-on Locking Mechanism (ARES-XL), Actuators, vol. 7, no. 1, p. 1, 2018.

Copilusi C. and Ploscaru C., Exoskeleton for children walking rehabilitation: Theoretical studies and simulation, 2016 20th IEEE Int. Conf. Autom. Qual. Testing, Robot. AQTR 2016 - Proc., 2016.

Cornejo J. L., Santana J. F., and Salinas S. A., Exoskeleton for gait rehabilitation of children: Conceptual design, 2017 Int. Conf. Rehabil. Robot., no. 057, pp. 452–454, 2017.

Diaz, I. Lower-Limb Robotic Rehabilitation: Literature Review and Challenges., J. Robot., 2011.

Fouz M. A., Fouda K., Alfayad S., and Dychus E., Child Lower Limb Exoskeleton: Sizing and Modeling, Int. J. Sci. Eng. Res., vol. 7, no. 12, December 2016, 2017.

Garcia E., Cestari M., and Sanz-Merodio D., Wearable Exoskeletons for the Physical Treatment of Children with Quadriparesis, 14th IEEE-RAS Int. Conf. Humanoid Robot., pp. 425–430, 2014.

Garcia E., Sanchez F., and Arevalo J. C., Development of the ATLAS lower-limb active orthosis, september, pp. 6–8, 2011.

Geonea I., Ceccarelli M., and Carbone G., Design and Analysis of an Exoskeleton for People with Motor Disabilities, 14th IFToMM World Congr., 2015.

Gorrostieta E., Rodriguez Resendiz J., Vargas Soto E., Zuñiga Aviles L. A., and Tovar Arriaga S., Mechatronics methodology: 15 years of experience Metodología mecatrónica: 15 años de experiencia, Ing. e Investig., vol. 35, no. 3, pp. 107–114, 2015.

Lerner Z. F., Damiano D. L., and Bulea T. C., A lower-extremity exoskeleton improves knee extension in children with crouch gait from cerebral palsy, Sci. Transl. Med., vol. 9, no. 404, pp. 1–11, 2017.

Lerner Z. F., Damiano D. L., and Bulea T. C., A robotic exoskeleton to treat crouch gait from cerebral palsy: Initial kinematic and neuromuscular evaluation,” Proc. Annu. Int. Conf. IEEE Eng. Med. Biol. Soc. EMBS, vol. 2016-Octob, pp. 2214–2217, 2016.

Larriva, J., Guillermo E., Trelles J. y Vele O., Diseño y construcción de un robot bípedo experimental, Redalyc.Universitas, Revista de Ciencias Sociales y Humanas, 8, pp. 137–151. 2006

Tomiyama T., Gu P., Jin Y., Lutters D., Kind C., and Kimura F., Design methodologies: Industrial and educational applications, CIRP Ann. - Manuf. Technol., vol. 58, no. 2, pp. 543–565, 2009.