Flexible strategies for sensory integration during motor planning.
about
Adult birdsong is actively maintained by error correction.Variations on a theme: Songbirds, variability, and sensorimotor error correction.Multisensory self-motion compensation during object trajectory judgments.Effects of Reliability and Global Context on Explicit and Implicit Measures of Sensed Hand Position in Cursor-Control TasksVocal learning is constrained by the statistics of sensorimotor experience.Preparedness for landing after a self-initiated fall.Adaptive tuning functions arise from visual observation of past movement.Object manipulation improvements due to single session training outweigh the differences among stimulation sites during vibrotactile feedback.Integration of auditory and somatosensory error signals in the neural control of speech movements.Dissociable effects of the implicit and explicit memory systems on learning control of reaching.Manipulating the edge of instabilityHeterogeneous representations in the superior parietal lobule are common across reaches to visual and proprioceptive targetsA learning-based approach to artificial sensory feedback leads to optimal integration.Integration of parallel mechanosensory and visual pathways resolved through sensory conflict.Multisensory integration in dynamical behaviors: maximum likelihood estimation across bimanual skill learningAnticipatory action planning in blind and sighted individuals.A self-organizing model of the visual development of hand-centred representationsProprioception is robust under external forces.The Arm Movement Detection (AMD) test: a fast robotic test of proprioceptive acuity in the armVisual feedback is not necessary for the learning of novel dynamics.Upper limb asymmetries in the matching of proprioceptive versus visual targets.Self versus environment motion in postural controlSensory reweighting in targeted reaching: effects of conscious effort, error history, and target salience.Using a compound gain field to compute a reach planNeural control of motion-to-force transitions with the fingertipCerebellar and prefrontal cortex contributions to adaptation, strategies, and reinforcement learningIntegration of egocentric and allocentric information during memory-guided reaching to images of a natural environment.Simulating the cortical 3D visuomotor transformation of reach depthGravity influences the visual representation of object tilt in parietal cortex.Behavioral investigation on the frames of reference involved in visuomotor transformations during peripheral arm reaching.Learning multisensory integration and coordinate transformation via density estimation.When kinesthesia becomes visual: a theoretical justification for executing motor tasks in visual space.Computations underlying the visuomotor transformation for smooth pursuit eye movements.How each movement changes the next: an experimental and theoretical study of fast adaptive priors in reaching.Sensory integration does not lead to sensory calibration.Effects of wrist tendon vibration on arm tracking in people poststroke.Direction-dependent integration of vision and proprioception in reaching under the influence of the mirror illusion.Effects of kinematic vibrotactile feedback on learning to control a virtual prosthetic arm.The generalization of visuomotor learning to untrained movements and movement sequences based on movement vector and goal location remappingNot noisy, just wrong: the role of suboptimal inference in behavioral variability
P2860
Q24657611-17CBC6E9-7453-4625-8DA3-537780604E60Q27022286-8B749089-B4D5-47DF-95F6-3EE25E513E17Q27303151-D398AA5A-C3B9-4AED-A9DA-FB7984F9F600Q27305289-2566A024-1932-4A56-916B-7A6411847F9CQ28710223-7A61F647-6981-4657-86AC-0E7BFFEB951FQ30224490-81212F93-DB85-4CCF-8CC6-6444D0E26359Q30380767-6582FAF8-253C-4C2C-BCF2-B6710225A4E0Q30460286-8C443331-D636-4FF3-B6FD-4CE52EF00DA5Q30465268-B5A759F2-3E35-437D-AA9A-CA49508F1F7DQ30478211-A6A3E0A2-5510-4D88-8110-ED6707AF1155Q30486860-8348CBCE-774B-4BAA-BEBD-9CFE6B97D713Q30500401-10883A82-BDC6-446A-9B7A-EEA8B3DAE4E5Q30612550-64263B03-5EA5-49BC-8E2C-089BADF56525Q30828880-DB465038-DF11-4898-B35A-A35789037D5DQ30829170-621C7E7C-C448-4520-8000-1083F82A0BE1Q30842202-DFC6716D-5881-4B14-8992-17DAC915588DQ31120835-B067984A-AAEC-4222-A6D3-0FD9B949B332Q31137917-CFF88C40-B22D-4412-9E52-93970231CC1AQ32187213-36396327-497D-4A72-9C16-294CDE717828Q33311285-E0DDF8CC-F410-4D97-A25A-0E68ADB0BD62Q33330795-BCF043DA-3B0D-4D99-ADA8-5ECE760C0D0BQ33533285-5A1FB751-56EF-4806-AECF-8167E7F502B5Q33593523-EDDC34CF-F6B3-4194-98F3-CCB18629D298Q33612616-D1C01BDD-CB11-4C1A-AF71-87ECA297F3E3Q33735307-E2656F0F-E479-45D6-AF03-4B4EECEC5C6FQ33988055-C09B8575-C81D-4BE7-A227-9DAE0D57DA6CQ34077894-6D94330B-ED74-46E4-9AF4-99370B16D82BQ34345884-9E18F8F8-C42A-4117-9999-715FE958FD6BQ34383381-DDC5DADF-08C1-4E13-A3E8-3D7043499788Q34525755-166B247D-7FDF-491B-882D-AEA583FB10B5Q34699674-FB61FF79-44C2-4529-BE50-8F6EDBBF4407Q34827482-506B74C4-9B3B-4A56-93D1-0F337E925B1DQ35138415-E5C41295-9EC6-4883-84CC-88E57CCB47CDQ35140774-7D890C13-20DD-4381-90BF-5813B8856B56Q35214785-D359E87D-EF3A-4641-87D8-446CC40C379EQ35217685-2C0C119C-C57A-4FD2-8977-2BFB6EC6DE6BQ35230608-8448DC72-A8E3-4E2D-9419-10FFEB9B6D0DQ35342831-57FCC84B-7732-49AD-9DE7-13D05475FE18Q35749578-03E9D9C4-CCAB-47D0-B8C7-204FF2E002BBQ35800943-DC6C9943-4F18-43A2-A835-4D6E929A2AC3
P2860
Flexible strategies for sensory integration during motor planning.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
2005年论文
@zh
2005年论文
@zh-cn
name
Flexible strategies for sensory integration during motor planning.
@en
type
label
Flexible strategies for sensory integration during motor planning.
@en
prefLabel
Flexible strategies for sensory integration during motor planning.
@en
P2860
P356
P1433
P1476
Flexible strategies for sensory integration during motor planning.
@en
P2093
Philip N Sabes
Samuel J Sober
P2860
P2888
P304
P356
10.1038/NN1427
P407
P577
2005-03-27T00:00:00Z