Composition and decomposition of internal models in motor learning under altered kinematic and dynamic environments.

J. R. Flanagan; E. Nakano; H. Imamizu; R. Osu; T. Yoshioka; M. Kawato

doi:10.1523/jneurosci.19-20-j0005.1999

Composition and decomposition of internal models in motor learning under altered kinematic and dynamic environments.

J. R. Flanagan^*, E. Nakano, H. Imamizu, R. Osu, T. Yoshioka, M. Kawato

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

108 Citations (Scopus)

Abstract

The learning process of reaching movements was examined under novel environments whose kinematic and dynamic properties were altered. We used a kinematic transformation (visuomotor rotation), a dynamic transformation (viscous curl field), and a combination of these transformations. When the subjects learned the combined transformation, reaching errors were smaller if the subject first learned the separate kinematic and dynamic transformations. Reaching errors under the kinematic (but not the dynamic) transformation were smaller if subjects first learned the combined transformation. These results suggest that the brain learns multiple internal models to compensate for each transformation and has some ability to combine and decompose these internal models as called for by the occasion.

Original language	English
Pages (from-to)	RC34
Journal	The Journal of neuroscience : the official journal of the Society for Neuroscience
Volume	19
Issue number	20
DOIs	https://doi.org/10.1523/jneurosci.19-20-j0005.1999
Publication status	Published - 1999 Oct 15
Externally published	Yes

ASJC Scopus subject areas

Neuroscience(all)

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10.1523/jneurosci.19-20-j0005.1999

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abstract = "The learning process of reaching movements was examined under novel environments whose kinematic and dynamic properties were altered. We used a kinematic transformation (visuomotor rotation), a dynamic transformation (viscous curl field), and a combination of these transformations. When the subjects learned the combined transformation, reaching errors were smaller if the subject first learned the separate kinematic and dynamic transformations. Reaching errors under the kinematic (but not the dynamic) transformation were smaller if subjects first learned the combined transformation. These results suggest that the brain learns multiple internal models to compensate for each transformation and has some ability to combine and decompose these internal models as called for by the occasion.",

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AU - Yoshioka, T.

AU - Kawato, M.

PY - 1999/10/15

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N2 - The learning process of reaching movements was examined under novel environments whose kinematic and dynamic properties were altered. We used a kinematic transformation (visuomotor rotation), a dynamic transformation (viscous curl field), and a combination of these transformations. When the subjects learned the combined transformation, reaching errors were smaller if the subject first learned the separate kinematic and dynamic transformations. Reaching errors under the kinematic (but not the dynamic) transformation were smaller if subjects first learned the combined transformation. These results suggest that the brain learns multiple internal models to compensate for each transformation and has some ability to combine and decompose these internal models as called for by the occasion.

AB - The learning process of reaching movements was examined under novel environments whose kinematic and dynamic properties were altered. We used a kinematic transformation (visuomotor rotation), a dynamic transformation (viscous curl field), and a combination of these transformations. When the subjects learned the combined transformation, reaching errors were smaller if the subject first learned the separate kinematic and dynamic transformations. Reaching errors under the kinematic (but not the dynamic) transformation were smaller if subjects first learned the combined transformation. These results suggest that the brain learns multiple internal models to compensate for each transformation and has some ability to combine and decompose these internal models as called for by the occasion.

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Composition and decomposition of internal models in motor learning under altered kinematic and dynamic environments.

Abstract

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