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2000

Cerebellar learning of accurate predictive control for fast-reaching movements

14 years 9 days ago
Cerebellar learning of accurate predictive control for fast-reaching movements
Long conduction delays in the nervous system prevent the accurate control of movements by feedback control alone. We present a new, biologically plausible cerebellar model to study how fast arm movements can be executed in spite of these delays. To provide a realistic test-bed of the cerebellar neural model, we embed the cerebellar network in a simulated biological motor system comprising a spinal cord model and a six-muscle two-dimensional arm model. We argue that if the trajectory errors are detected at the spinal cord level, memory traces in the cerebellum can solve the temporal mismatch problem between eerent motor commands and delayed error signals. Moreover, learning is made stable by the inclusion of the cerebello-nucleo-olivary loop in the model. It is shown that the cerebellar network implements a nonlinear predictive regulator by learning part of the inverse dynamics of the plant and spinal circuit. After learning, fast accurate reaching movements can be generated.
Jacob Spoelstra, Nicolas Schweighofer, Michael A.
Added 17 Dec 2010
Updated 17 Dec 2010
Type Journal
Year 2000
Where BC
Authors Jacob Spoelstra, Nicolas Schweighofer, Michael A. Arbib
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