Title :
Biologically Inspired SNN for Robot Control
Author :
Nichols, Eric ; McDaid, Liam J. ; Siddique, Naseer
Author_Institution :
Intell. Syst. Res. Centre, Univ. of Ulster, Derry, UK
Abstract :
This paper proposes a spiking-neural-network-based robot controller inspired by the control structures of biological systems. Information is routed through the network using facilitating dynamic synapses with short-term plasticity. Learning occurs through long-term synaptic plasticity which is implemented using the temporal difference learning rule to enable the robot to learn to associate the correct movement with the appropriate input conditions. The network self-organizes to provide memories of environments that the robot encounters. A Pioneer robot simulator with laser and sonar proximity sensors is used to verify the performance of the network with a wall-following task, and the results are presented.
Keywords :
laser beam applications; mobile robots; neurocontrollers; plasticity; sensors; sonar; walls; Pioneer robot simulator; biological system; biologically inspired spiking neural network; control structure; dynamic synapses; laser proximity sensor; long-term synaptic plasticity; mobile robot; robot control; short-term plasticity; sonar proximity sensor; temporal difference learning rule; wall-following task; Biological system modeling; Neurons; Neurotransmitters; Robot sensing systems; Dynamic synapses; self-organization; spiking neural network (SNN); temporal difference (TD) learning rule;
Journal_Title :
Cybernetics, IEEE Transactions on
DOI :
10.1109/TSMCB.2012.2200674
