Composition and decomposition learning of reaching movements under altered environments

An examination of the multiplicity of internal models

Eri Nakano, John R. Flanagan, Hiroshi Imamizu, Rieko Osu, Toshinori Yoshioka, Mitsuo Kawato

研究成果: Article

4 引用 (Scopus)

抄録

We have studied the learning processes of reaching movements under novel environments whose kinematic and dynamic properties are altered. In the experiments, we have used, as the kinematic transformation, a rotational transformation which is displayed by rotating a cursor indicating hand position in the orthogonal coordinate system on a CRT; a viscous transformation using viscous field as the dynamic transformation; and a combined transformation of these two transformations. It is observed that the hand trajectory approaches a straight line along with learning and accurately reaches the target. When the combined transformation is learned after the rotational transformation and viscous transformation are learned first, respectively, the final error becomes smaller and the path length also becomes shorter than the case when the combined transformation is learned first. Moreover, the final error and path length of the movement under rotation al transformation and viscous transformation when the combined transformation is learned first also become smaller than the case when the rotational and viscous transformations are learned first. These results suggest that the central nervous system has learned separately the multiple internal models which compensate the respective transformations, and has composed or decomposed the respective internal models in accordance with the environmental changes. It may be considered that such multiplicity of internal models makes, it possible for the living body to flexibly cope with the environments or tools having various dynamic and kinematic properties.

元の言語English
ページ(範囲)80-94
ページ数15
ジャーナルSystems and Computers in Japan
33
発行部数11
DOI
出版物ステータスPublished - 2002 10
外部発表Yes

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Multiplicity
Kinematics
Decomposition
Internal
Decompose
Chemical analysis
Cathode ray tubes
Neurology
Trajectories
Model
Movement
Learning
Path Length
Experiments
Dynamic Properties
Learning Process
Straight Line
Rotating
Trajectory

ASJC Scopus subject areas

  • Theoretical Computer Science
  • Information Systems
  • Hardware and Architecture
  • Computational Theory and Mathematics

これを引用

Composition and decomposition learning of reaching movements under altered environments : An examination of the multiplicity of internal models. / Nakano, Eri; Flanagan, John R.; Imamizu, Hiroshi; Osu, Rieko; Yoshioka, Toshinori; Kawato, Mitsuo.

:: Systems and Computers in Japan, 巻 33, 番号 11, 10.2002, p. 80-94.

研究成果: Article

Nakano, Eri ; Flanagan, John R. ; Imamizu, Hiroshi ; Osu, Rieko ; Yoshioka, Toshinori ; Kawato, Mitsuo. / Composition and decomposition learning of reaching movements under altered environments : An examination of the multiplicity of internal models. :: Systems and Computers in Japan. 2002 ; 巻 33, 番号 11. pp. 80-94.
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