English

Evolving Spiking Neural Networks for Nonlinear Control Problems

Neural and Evolutionary Computing 2019-03-05 v1 Robotics

Abstract

Spiking Neural Networks are powerful computational modelling tools that have attracted much interest because of the bioinspired modelling of synaptic interactions between neurons. Most of the research employing spiking neurons has been non-behavioural and discontinuous. Comparatively, this paper presents a recurrent spiking controller that is capable of solving nonlinear control problems in continuous domains using a popular topology evolution algorithm as the learning mechanism. We propose two mechanisms necessary to the decoding of continuous signals from discrete spike transmission: (i) a background current component to maintain frequency sufficiency for spike rate decoding, and (ii) a general network structure that derives strength from topology evolution. We demonstrate that the proposed spiking controller can learn significantly faster to discover functional solutions than sigmoidal neural networks in solving a classic nonlinear control problem.

Keywords

Cite

@article{arxiv.1903.01180,
  title  = {Evolving Spiking Neural Networks for Nonlinear Control Problems},
  author = {Huanneng Qiu and Matthew Garratt and David Howard and Sreenatha Anavatti},
  journal= {arXiv preprint arXiv:1903.01180},
  year   = {2019}
}

Comments

conference: ssci 2018

R2 v1 2026-06-23T07:57:19.898Z