about
Task dependency of grip stiffness--a study of human grip force and grip stiffness dependency during two different tasks with same grip forcesBehavioral and neural correlates of communication via pointingDoes the brain model Newton's laws?Physiological modules for generating discrete and rhythmic movements: action identification by a dynamic recurrent neural networkPhysiological modules for generating discrete and rhythmic movements: component analysis of EMG signals.Internal models and prediction of visual gravitational motion.Visuo-motor coordination and internal models for object interception.A modular theory of multisensory integration for motor control.Spatial, not temporal cues drive predictive orienting movements during navigation: a virtual reality study.Gravity influences top-down signals in visual processing.The perception of visually presented yaw and pitch turns: assessing the contribution of motion, static, and cognitive cues.Correction: Task Dependency of Grip Stiffness—A Study of Human Grip Force and Grip Stiffness Dependency during Two Different Tasks with Same Grip Forces.Viewing another person's body as a target object: a behavioural and PET study of pointing.Necessity is the mother of invention: reconstructing missing sensory information in multiple, concurrent reference frames for eye-hand coordination.Short-term memory for reaching to visual targets: psychophysical evidence for body-centered reference frames.Effect of gravity on human spontaneous 10-Hz electroencephalographic oscillations during the arrest reaction.Gravity-dependent estimates of object mass underlie the generation of motor commands for horizontal limb movements.Perception of affordances during long-term exposure to weightlessness in the International Space station.The control of stable postures in the multijoint arm.Do novel gravitational environments alter the grip-force/load-force coupling at the fingertips?Keep your head on straight: facilitating sensori-motor transformations for eye-hand coordination.Inertial torque during reaching directly impacts grip-force adaptation to weightless objects.A robotic model to investigate human motor control.Movement stability under uncertain internal models of dynamics.Viewer-centered frame of reference for pointing to memorized targets in three-dimensional space.Two reference frames for visual perception in two gravity conditions.Gravity and spatial orientation in virtual 3D-mazes.Measurements of human force control during a constrained arm motion using a force-actuated joystick.Central processes amplify and transform anisotropies of the visual system in a test of visual-haptic coordination.Gait transitions in simulated reduced gravityIndependence of bilateral symmetry detection from a gravitational reference frameViewer-centered and body-centered frames of reference in direct visuomotor transformationsPerception and reproduction of force direction in the horizontal planeHand trajectory formation during whole body reaching movements in manThe Kinelite Project: a new powerful motion analyser for Spacelab and space stationInternal reference frames for representation and storage of visual information: the role of gravityDoes gravity play an essential role in the asymmetrical visual perception of vertical and horizontal line length?Reference frames and internal models for visuo-manual coordination: what can we learn from microgravity experiments?Gravity affects the preferred vertical and horizontal in visual perception of orientationServo Hypotheses for the Biological Control of Movement
P50
Q28661308-CEA81CFA-A4BA-4016-AE2E-C94353A86B06Q33851445-9F889ADC-F93F-4175-A8A4-D030556B3D85Q33953128-E2D5DB3D-8E39-45E9-A5E6-13489049C1E4Q34198527-6465C4AB-E4FD-4C7D-B63E-63CA1D3BE415Q34882697-897D5B2A-75C8-41FB-B0B5-9B43AD7CC94DQ37171341-6F5B46BC-D442-4EEA-B4B2-824908621E14Q37367270-3B5039EC-BACE-437C-83C0-D6F539922F90Q37536666-37DBBE6D-7677-4C97-9BEA-1511AFC10DEAQ40770446-37073811-58D0-49D9-8763-8C1B5365CFF6Q41853474-359C6580-D2B9-43CC-951C-8F2C5BF5A46DQ43690295-CF398265-C256-4ED0-B63C-2B0AE062A3FEQ47147792-26CF7B35-9902-45AD-9077-2306B7E75B8FQ47204379-3C64B189-FD64-4833-A83D-308E8AEC9DBCQ48157105-3182BEBE-412A-412A-8569-BD2F1F3B773EQ48380136-33080951-361F-45D0-8B7A-D2995F038E2EQ48398729-FA4EB03E-175D-48A4-B0B2-CAA441F2AA6CQ48799644-5EE5442E-8761-433B-938E-7885B5C201D5Q48970682-AF1AF4B8-5315-446E-95ED-FA75C3539995Q48975081-3BDB937D-17CB-4E33-AC6F-5022D8595FA0Q49162599-A9E155A7-97EC-4A89-B462-8A0C6764E7EBQ50055486-1ED59D16-C04C-40AF-996B-D66B3A6F64D4Q50571280-2046E89F-DA31-4DAF-92FB-83450D1F91C0Q51547030-76999E14-98FD-4589-AC7C-5FF08CA02479Q51906213-B4E3B08D-2EC3-47DB-B741-03C0C914C09AQ52041596-A5A0C900-C99C-495B-BC7A-9B6AF082C592Q52045547-09DC2D5F-6E5F-402D-B557-6247758DEB6AQ52090345-0BF4E63E-6A64-47E1-9C30-6FCEBE818817Q52349863-C4F7C8B7-B6E0-484D-B2E1-204A26538CD0Q53033268-A3E00FC7-DB9D-41F2-9056-4D338B8E6F7FQ61786148-EFCC21DE-7327-4952-8BE2-702B7667405FQ71936042-68ACAF4A-0D27-44C8-BC64-5184C665F367Q73257816-9749C693-351E-4FE7-9F67-79E57D9A6FC2Q73703109-BB553505-E459-4984-9321-BEE37B6E5B5BQ74313890-2E92BDCC-B312-482C-9294-8EE1D5D0153CQ74475795-3564FBDB-42F7-4381-B71A-2FA616C8E749Q74828041-8E38A399-BD15-445A-9923-BD5D8EB47B38Q74828045-918B78DF-DBD1-4318-9662-16B6BA310745Q77486473-B9F54682-6329-4730-898B-F0B7A9F5062BQ77733195-5598C0A3-3632-469D-9155-78BC6D3CDC6DQ78969207-3EC5CBF0-D1CF-4980-B04E-55ED09DA49FD
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Joseph McIntyre
@ast
Joseph McIntyre
@en
Joseph McIntyre
@es
Joseph McIntyre
@nl
Joseph McIntyre
@sl
type
label
Joseph McIntyre
@ast
Joseph McIntyre
@en
Joseph McIntyre
@es
Joseph McIntyre
@nl
Joseph McIntyre
@sl
prefLabel
Joseph McIntyre
@ast
Joseph McIntyre
@en
Joseph McIntyre
@es
Joseph McIntyre
@nl
Joseph McIntyre
@sl
P108
P1053
K-6395-2015
P106
P21
P31
P3829
P496
0000-0003-4974-4257
P569
2000-01-01T00:00:00Z