• DocumentCode
    3157738
  • Title

    F-MRI analysis of the human brain activities during manual control of a nonholonomic system

  • Author

    Kato, Shinpei ; Goto, Takakuni ; Homma, Noriyasu ; Yoshizawa, Makoto ; Yomogida, Yukihito ; Sassa, Yuko ; Sugiura, Motoaki ; Riera, Jorge ; Kawashima, Ryuta

  • Author_Institution
    Grad. Sch. of Eng., Tohoku Univ., Tohoku
  • fYear
    2008
  • fDate
    20-22 Aug. 2008
  • Firstpage
    1977
  • Lastpage
    1980
  • Abstract
    Humans can often conduct both linear and nonlinear control tasks after a sufficient number of trials, even if they initially do not have sufficient knowledge about the systempsilas dynamics and the way to control it. Theoretically, it is well known that some nonlinear systems cannot be stabilized asymptotically by any linear controllers. However, such differences between linear and nonlinear controls from the viewpoint of brain activities are still unclear. In this paper, we have conducted an F-MRI experiment using complex nonlinear control tasks where subjects are required to control a 2-link planar under actuated manipulator (2PUAM). The 2PUAM has nonholonomic constrains and cannot be stabilized asymptotically by any linear controller. Although there are similar activations such as in motor cortex and somatosensory cortex, some differences between linear and nonlinear cases have been observed by the F-MRI. According to the brain function mapping, the result implies that some additional information such as the shape of the manipulator and its trajectory, which are not needed for linear control tasks, may be required to control the 2PUAM. Therefore, this suggests that the difference in linear and nonlinear control tasks can be observed through the brain activities.
  • Keywords
    asymptotic stability; biomedical MRI; manipulators; nonlinear control systems; 2-link planar under actuated manipulator; F-MRI analysis; asymptotic stability; brain function mapping; human brain activities; linear-nonlinear control tasks; motor cortex; nonholonomic system; somatosensory cortex; Brain; Control systems; Human factors; Magnetic resonance imaging; Manipulator dynamics; Medical control systems; Motion control; Nonlinear control systems; Shape control; Trajectory; brain activities; f-MRI; manual control; nonholonomic system;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    SICE Annual Conference, 2008
  • Conference_Location
    Tokyo
  • Print_ISBN
    978-4-907764-30-2
  • Electronic_ISBN
    978-4-907764-29-6
  • Type

    conf

  • DOI
    10.1109/SICE.2008.4654986
  • Filename
    4654986