Population based Mean of Multiple Computations networks: A building block for kinematic models

Abstract: Abstract-Population based encodings allow to represent probabilistic and fuzzy state estimates. Such a representation will be introduced and applied for the case of a redundant manipulator. Following the Mean of Multiple Computations principle, a neural network model (PbMMC) is presented in which the overall complexity is divided into multiple local relationships. This allows to solve inverse, forward and mixed kinematic problems. The local transformations in between the kinematic variables can be sufficiently… Show more

“…This encoding shows place-cell-like activations and fits well to recently described posture cells in rats [15]. Overall, the presented model addresses nicely different aspects on the neuronal organization of functional internal models: First, it shows a population-based encoding which in a next step might be exploited to encode noisy or faulty information in a probabilistic way [23]. Secondly, the MMC principle is based on redundant frames of reference as are assumed to be used inside the brain.…”

Setup of a Recurrent Neural Network as a Body Model for Solving Inverse and Forward Kinematics as well as Dynamics for a Redundant Manipulator

“…This encoding shows place-cell-like activations and fits well to recently described posture cells in rats [15]. Overall, the presented model addresses nicely different aspects on the neuronal organization of functional internal models: First, it shows a population-based encoding which in a next step might be exploited to encode noisy or faulty information in a probabilistic way [23]. Secondly, the MMC principle is based on redundant frames of reference as are assumed to be used inside the brain.…”

Setup of a Recurrent Neural Network as a Body Model for Solving Inverse and Forward Kinematics as well as Dynamics for a Redundant Manipulator