The GReaNs platform (which stands for Gene Regulatory evolutionary artificial Networks) is an artificial life software platform that has been previously shown to allow the evolution of networks for signal processing and animat control [1]. The structure of the resulting network in this model is encoded in a linear genome, without imposing any restrictions on the size of the genome or the size of the network. We extended this model to encode spiking neural networks [4]. In previous work using GReaNs [1], each node in the artificial network has been considered to be an analog of a biological transcriptional unit. However, the nodes can also be seen as artificial neurons. Our extension has introduced to GReaNs two models of spiking neurons (LIF: leaky integrate and fire neurons with a fixed threshold [2] and AdEx: adaptive-exponential integrate and fire [3]). Here we use GReaNs for the evolution of spiking networks for pattern recognition. The genetic algorithm used in GReaNS is based on evolving the number of the neurons and the weights of the connections, but the synaptic delays are constant. We evolved a network that generates spikes at a maximum firing rate when the network is presented with one spike from five input neurons in a specific order, and that stays silent when the order is reversed. We also used three inputs, each with one spike, requiring the network to fire at a maximum rate for a specific temporal order of spikes and to remain silent for all the other permutations. In further work, we plan to investigate the generalization abilities of the evolved networks and the robustness of their behaviour to noise. GReaNs can export a PyNN script, which allows the simulation of an evolved network on different backends, including neuromorphic real-time hardware for real time simulation.
References
Wróbel B, Joachimczak M: Using GReaNs (Genetic Regulatory evolving artificial Networks) for 3-dimensional Asymmetrical Pattern Formation and Morphogenesis. Proceedings of DevLeaNN: Workshop on Development and Learning in Artificial Neural Networks. 2011, 26-28.
Dayan P, Abbott LF: Theoretical neuroscience. Boston. 2001, MIT Press
Gerstner W, Brette R: Adaptive exponential integrate-and-fire model as an effective description of neuronal activity. J Neurophysiol. 2005, 94: 3637-3642. 10.1152/jn.00686.2005.
Wróbel B, Abdelmotaleb A, Joachimczak M: Evolving spiking neural networks in the GReaNs (Gene Regulatory Evolving Artificial Networks) platform. EvoNet2012: Evolving Networks, from Systems/Synthetic Biology to Computational Neuroscience Workshop at Artificial Life XIII. 2012, 19-22.
Davison AP, Brüderle D, Eppler JM, Kremkow J, Muller E, Pecevski DA, Perrinet L and Yger P: PyNN: a common interface for neuronal network simulators. Front Neuroinform. 2009, 2-11.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
About this article
Cite this article
Abdelmotaleb, A., Schilstra, M., Davey, N. et al. From evolving artificial gene regulatory networks to evolving spiking neural networks for pattern recognition. BMC Neurosci 14 (Suppl 1), P423 (2013). https://doi.org/10.1186/1471-2202-14-S1-P423
Published:
DOI: https://doi.org/10.1186/1471-2202-14-S1-P423