D. J. Reinkensmeyer and V. Dietz, Neurorehabilitation Technology, 2016.

C. Bayón, O. Ramirez, M. D. Castillo, J. I. Serrano, R. Raya et al., CPWalker: Robotic Platform for Gait Rehabilitation in Patients with Cerebral Palsy, IEEE Int. Conf. on Robotics and Automation, pp.3736-3741, 2016.

G. Sumathy and A. Renjith, A Survey of Vision and Speech Stimulation for cerebral Palsy Rehabilitation, Int. Conf. on Control, Instrumentation, Communication and Computational Technologies, pp.1315-1319, 2014.

M. Bax, M. Goldstein, P. Rosenbaum, A. Leviton, and N. Paneth, Proposed definition and classification of cerebral palsy, Developmental Medicine and Child Neurology, vol.47, pp.571-576, 2005.

M. Stavsky, O. Mor, S. A. Mastrolia, S. Greenbaum, N. G. Than et al., Cerebral Palsy-Trends in Epidemiology and Recent Development in Prenatal Mechanisms of Disease, Treatment, and Prevention, Front. Pediatr, vol.21, pp.1-10, 2017.

. Kb, J. H. Nelson, and . Ellenberg, Antecedents of cerebral palsy. Multivariate analysis of risk, N. Engl. J. Med, vol.2, pp.81-86, 1986.

E. Blair and F. Stanley, When can cerebral palsy be prevented? The generation of causal hypotheses by multivariate analysis of a casecontrol study, Paediatr Perinat Epidemiol, vol.3, pp.272-301, 1993.

. Jk, K. B. Grether, and . Nelson, Maternal infection and cerebral palsy in infants of normal birth weight, JAMA, vol.3, pp.207-211, 1997.

T. M. Shea, E. N. Allred, O. Dammann, D. Hirtz, K. Kuban et al., The ELGAN study of the brain and related disorders in extremely low gestational age newborns, Early Hum Dev, vol.11, pp.719-725, 2009.

H. Barbeau and S. Rossignol, Enhancement of locomotor recovery following spinal cord injury, Curr Opin Neurol, vol.6, pp.517-524, 1994.

F. Patané, S. Rossi, F. Sette, J. Taborri, and P. Cappa, WAKE-Up Exoskeleton to Assist Children With Cerebral Palsy: Design and Preliminary Evaluation in Level Walking, IEEE Trans. ON Neural Systems and Rehabilitation Engineering, vol.25, pp.906-916, 2017.

M. Wu, J. Kim, P. Arora, D. J. .-g-spira, and Y. Zhang, Locomotor training through a 3D cable-driven robotic system for walking function in children with cerebral palsy: a pilot study, IEEE Int. Conf of Engineering in Medecine and Biology Society, pp.3529-3532, 2014.

A. Deep and R. Jaswal, Role of Management & Virtual Space for the Rehabilitation of Children Affected with Cerebral Palsy: A Review, IEEE Int. Conf on Signal Processing, Computing and Control, pp.293-299, 2017.

O. N. Berdina, T. A. Bairova, L. V. Rychkova, and S. A. Sheptunov, The Pediatric Robotic-Assisted Rehabilitation Complex for Children and Adolescents with Cerebral Palsy: Background and Product Design, Int. Conf. Quality Management, Transport and Information Security, Information Technologies, pp.360-363, 2017.

A. J. Mcdaid, C. Lakkhananukun, and J. Park, Paediatric robotic gait trainer for children with cerebral palsy, IEEE Int. Conf. on Rehabilitation Robotics, pp.780-785, 2015.

G. C. Burdea, D. Cioi, A. Kale, W. E. Janes, S. A. Ross et al., Robotics and Gaming to Improve Ankle Strength, Motor Control, and Function in Children With Cerebral PalsyA Case Study Series, IEEE Trans. Neural Systems and Rehabilitation Engineering, vol.21, pp.165-173, 2013.

D. Ganjwala, Multilevel orthopedic surgery for crouch gait in cerebral palsy: An evaluation using functional mobility and energy cost, Indian J. Orthop, vol.45, issue.4, pp.314-319, 2011.

K. Tedroff, K. Löwing, K. D. Jacobson, and E. Aström, Does loss of spasticity matter? a 10-year follow-up after selective dorsal rhizotomy in cerebral palsy, Dev. Med. Child Neurol, vol.53, issue.8, pp.724-729, 2011.

B. C. Friedman and R. D. Goldman, Use of botulinum toxin a in management of children with cerebral palsy, Can. Fam. Physician, vol.57, issue.9, pp.1006-1073, 2011.

F. Mahamud and A. Anuar, Usage of Robotic Rehabilitation Technology for Lower Limbs Therapy of Children with Cerebral Palsy -A Review, IEEE Int. Symposium on Robotics and Manufacturing Automation, pp.126-130, 2014.

S. Cuccurullo, Physical Medicine and Rehabilitation Board Review, 2004.

H. Rifai, M. S. Ben-abdessalem, A. Chemori, S. Mohammed, and Y. Amirat, Augmented L1 Adaptive Control of an Actuated Knee Joint Exoskeleton: From Design to Real-Time Experiments, IEEE Int. Conf. on Robotics and Automation, pp.5708-5714, 2016.
URL : https://hal.archives-ouvertes.fr/lirmm-01723920

C. Copilusi and C. Ploscaru, Exoskeleton for children walking rehabilitation: theoretical studies and simulation, IEEE Int. Conf. on Automation, Quality and Testing, Robotics, 2016.

F. Barroso, C. Santos, and J. C. Moreno, Influence of the robotic exoskeleton Lokomat on the control of human gait: an electromyographic and kinematic analysis, 3rd Portuguese Meeting in Bioengineering, 2013.

J. Chen, J. Hochstein, C. Kim, D. Damiano, and T. Bulea, Design Advancements toward a Wearable Pediatric Robotic Knee Exoskeleton for Overground Gait Rehabilitation, IEEE Int. Conf. on Biomedical Robotics and Biomechatronics, pp.37-42, 2018.

M. Babaiasl, S. N. Goldar, M. H. Barhaghtalab, and V. Meigoli, Sliding Mode Control of an Exoskeleton Robot for Use in Upper-Limb Rehabilitation, Int. Conf. on Robotics and Mechatronics, pp.694-701, 2015.

M. Ghezal, I. Guiatni, C. S. Boussioud, and . Renane, Design and Robust Control of a 2 DOFs Lower Limb Exoskeleton, Int. Conf. on Communications and Electrical Engineering, 2018.

S. Mefoued, Commande robuste référencée intention d'une orthèse active pour l'assistance fonctionnelle aux mouvements du genou, 2012.