Perception and control of upper limb movement: Insights gained by analysis of sensory and motor variability

Domkin, Dmitry

January 2005

Chronic neck-shoulder pain is associated with impairments of proprioception and motor control. Thus, assessment of proprioceptive and motor function may be powerful tools both for research and clinical practice. However, insufficient knowledge of certain features of human sensorimotor control hampers both development and interpretation of results of clinically relevant tests. For example, evidence is lacking which proprioception submodalities are reflected in common tests of proprioception. For testing motor function, a better understanding of the control of goal directed arm movements is needed. The purpose of the thesis was to gain further insights into the sensorimotor control of the upper limb in healthy subjects, with implications for clinical testing. The main aims were: (1) to study relationships of outcomes of different tests of shoulder proprioception and (2) to study control strategies in bimanual pointing tasks by analysis of the structure of joint angle variability with the Uncontrolled Manifold (UCM) method. Correlations between proprioceptive acuity in different variants of ipsilateral position-matching and velocity-discrimination were studied. The main finding was that two uncorrelated mechanisms based either on perception of position or movement might underlie perception of limb location in ipsilateral position-matching. The results provided important information for interpretation of common and development of novel tests of shoulder proprioception. The structure of joint angle variance was computed with respect to several task variables during bimanual pointing. Joint angle variability was decomposed in variance affecting and not affecting a task variable. The results showed that the variance in joint space was structured according to the predictions of the UCM hypothesis. It was also shown that the arms were united into one synergy to significantly larger degree than joints within each arm were united into single-arm synergies. It was concluded that the UCM approach might quantify components of motor variability during repetitive motor tasks.

Medicine

proprioception

kinaesthesia

position sense

movement sense

position-matching

velocity-discrimination

correlation

uncontrolled manifold

variability

synergy

upper limb

motor control

Medicin

Analysis and generation of highly dynamic motions of anthropomorphic systems : application to parkour / Analyse et génération des mouvements hautement dynamiques des systèmes anthropomorphes : application au Parkour

Maldonado Toro, Galo Xavier

08 December 2017

Cette thèse propose une approche interdisciplinaire originale du traitement du mouvement humain corps-complet grâce à l'utilisation couplée d'approches issues de la biomécanique, du contrôle moteur et de la robotique. Les méthodes biomécaniques sont utilisées pour l'enregistrement, le traitement et l'analyse du mouvement humain. L'approche << Uncontrolled Manifold >> du contrôle moteur est étendue à l'étude des mouvements hautement dynamiques. Ceci permet de déterminer si d'éventuelles tâches dynamiques sont contrôlées et stabilisées par le cerveau, puis d'inférer une organisation hiérarchique des tâches motrices. Le formalisme de l'espace des tâches utilisé en robotique pour la génération de mouvement corps-complet ainsi que la hiérarchie des tâches extraites dans l'étude du contrôle moteur sont utilisés pour simuler des mouvements humains hautement dynamiques. Cette approche permet de mieux comprendre le mouvement humain et de générer des mouvements inspirés de l'humain pour d'autres systèmes anthropomorphes tel que des robots ou avatars. La discipline du Parkour, impliquant des actions hautement dynamiques tels que des sauts et des techniques d'atterisage, est choisie pour illustrer l'approche proposée. / This thesis proposes an original and interdisciplinary approach to the treatment of whole-body human movements through the synergistic utilization of biomechanics, motor control and robotics. Robust methods of biomechanics are used to record, process and analyze whole-body human motions. The Uncontrolled Manifold approach (UCM) of motor control is extended to study highly dynamic movements processed in the biomechanical study, in order to determine if hypothesized dynamic tasks are being controlled stably by the central nervous system. This extension permits also to infer a hierarchical organization of the controlled dynamic tasks. The task space formalism of motion generation in robotics is used to generate whole-body motion by taking into account the hierarchy of tasks extracted in the motor control study. This approach permits to better understand the organization of human dynamic motions and provide a new methodology to generate whole-body human motions with anthropomorphic systems. A case study of highly dynamic and complex movements of Parkour, including jumps and landings, is utilized to illustrate the proposed approach.

Redondance

Mouvement corps-complet

Biomécanique

Contrôle moteur

Robotique

Mouvement inspiré de l'homme

Espace de tâches

Uncontrolled Manifold

Parkour

Mouvement hautement dynamique

Redundancy

Xhole-body motion

Biomechanics

Motor control

Robotics

Human-inspired motion