CONF paugam:esann:2007/IDIAP A supervised learning approach based on STDP and polychronization in spiking neuron networks Paugam-Moisy, Hélène Martinez, R. Bengio, Samy EXTERNAL https://publications.idiap.ch/attachments/papers/2007/paugam-esann-2007.pdf PUBLIC https://publications.idiap.ch/index.php/publications/showcite/paugam:rr06-54 Related documents European Symposium on Artificial Neural Networks, ESANN 2007 IDIAP-RR 06-54 We propose a network model of spiking neurons, without preimposed topology and driven by STDP (Spike-Time-Dependent Plasticity,',','), a temporal Hebbian unsupervised learning mode, biologically observed. The model is further driven by a supervised learning algorithm, based on a margin criterion, that has effect on the synaptic delays linking the network to the output neurons, with classification as a goal task. The network processing and the resulting performance are completely explainable by the concept of polychronization, proposed by Izhikevich~\cite{Izh06NComp}. The model emphasizes the computational capabilities of this concept. REPORT paugam:rr06-54/IDIAP A supervised learning approach based on STDP and polychronization in spiking neuron networks Paugam-Moisy, Hélène Martinez, R. Bengio, Samy EXTERNAL https://publications.idiap.ch/attachments/reports/2006/paugam-idiap-rr-06-54.pdf PUBLIC Idiap-RR-54-2006 2006 IDIAP We propose a novel network model of spiking neurons, without preimposed topology and driven by STDP (Spike-Time-Dependent Plasticity,',','), a temporal Hebbian unsupervised learning mode, based on biological observations of synaptic plasticity. The model is further driven by a supervised learning algorithm, based on a margin criterion, that has effect on the synaptic delays linking the network to the output neurons, with classification as a goal task. The network processing and the resulting performance are completely explainable by the concept of polychronization, recently introduced by Izhikevich~\cite{Izh06NComp}. On the one hand, our model can be viewed as a new machine learning concept for classifying patterns by means of spiking neuron networks. On the other hand, as a model of natural neural networks, it provides a new insight on cell assemblies, a fundamental notion for understanding the cognitive processes underlying memory. {\bf Keywords.} Spiking neuron networks, Synaptic plasticity, STDP, Delay learning, Classifier, Cell assemblies, Polychronous groups.