Abstract
Precise spike timing and temporal coding are used extensively within the nervous system of insects and in the sensory periphery of higher order animals. However, conventional Artificial Neural Networks (ANNs) and machine learning algorithms cannot take advantage of this coding strategy, due to their rate-based representation of signals. Even in the case of artificial Spiking Neural Networks (SNNs), identifying applications where temporal coding outperforms the rate coding strategies of ANNs is still an open challenge. Neuromorphic sensory-processing systems provide an ideal context for exploring the potential advantages of temporal coding, as they are able to efficiently extract the information required to cluster or classify spatio-temporal activity patterns from relative spike timing. Here we propose a neuromorphic model inspired by the sand scorpion to explore the benefits of temporal coding, and validate it in an event-based sensory-processing task. The task consists in localizing a target using only the relative spike timing of eight spatially-separated vibration sensors. We propose two different approaches in which the SNNs learns to cluster spatio-temporal patterns in an unsupervised manner and we demonstrate how the task can be solved both analytically and through numerical simulation of multiple SNN models. We argue that the models presented are optimal for spatio-temporal pattern classification using precise spike timing in a task that could be used as a standard benchmark for evaluating event-based sensory processing models based on temporal coding.
Highlights
Information transmission in neural networks is often described in terms of the rate at which neurons emit action potentials
We present a step-by-step analysis of conventional algorithms and five different models based on spiking neural networks for classifying the data-set of spatio-temporal patterns using both supervised and unsupervised learning rules
When we study the dynamics of a single synapse i, we remove the discontinuities caused by the input signal by focusing on the range [si, t] where H(t) = 1, si being the time of arrival of a spike to a post-synaptic neuron
Summary
Information transmission in neural networks is often described in terms of the rate at which neurons emit action potentials. Event-Based Touch Localization noise (or noisy background activity) which can be assumed to be an additive signal to the sensory input one (Baudot et al, 2013) This linear separation of signal and noise has been used to justify rate- and/or population-coding by averaging across time and/or neuronal populations (Shadlen and Newsome, 1998; Dayan and Abbott, 2001). These observations led to the common assumption that the main mode of information transmission in most brain areas is encoded in the neurons average spikefrequency. Sand scorpions detect these waves using sensory hairs on their legs
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