Abstract
Different learning modes and mechanisms allow faster and better acquisition of skills as widely studied in humans and many animals. Specific neurons, called mirror neurons, are activated in the same way whether an action is performed or simply observed. This suggests that observing others performing movements allows to reinforce our motor abilities. This implies the presence of a biological mechanism that allows creating models of others' movements and linking them to the self-model for achieving mirroring. Inspired by such ability, we propose to build a map of movements executed by a teaching agent and mirror the agent's state to the robot's configuration space. Hence, in this study, a neural network is proposed to integrate a motor cortex-like differential map transforming motor plans from task-space to joint-space motor commands and a static map correlating joint-spaces of the robot and a teaching agent. The differential map is developed based on spiking neural networks while the static map is built as a self-organizing map. The developed neural network allows the robot to mirror the actions performed by a human teaching agent to its own joint-space and the reaching skill is refined by the complementary examples provided. Hence, experiments are conducted to quantify the improvement achieved thanks to the proposed learning approach and control scheme.
Highlights
IntroductionWith the aim to keep up with the pace of such demands, adaptability and novel learning techniques are essential in robots
Robots are involved nowadays in many demanding and challenging tasks
The representation capabilities of the self-organizing map (SOM) and motor cortex-like map (MCM) are matched together to allow the robot to reduce the error while reaching targets
Summary
With the aim to keep up with the pace of such demands, adaptability and novel learning techniques are essential in robots. One of the biologically inspired methods for learning is learning by demonstration or imitation, where the robot is taught by a teaching agent to execute a specific task. Specific neurons in several brain regions, called mirror neurons, are proven to trigger almost the same output while executing or observing the same task (Heyes, 2010; Cook et al, 2014). These neurons are considered a key component in learning and refining motor skills in primates (Oztop et al, 2006; Iacoboni, 2009).
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