The Chronotron: A Neuron That Learns to Fire Temporally Precise Spike Patterns

• Published in: PloS one Vol. 7; no. 8; p. e40233
• Main Author: Florian, Răzvan V.
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 06.08.2012; Public Library of Science (PLoS)
• Subjects: Action Potentials - physiology; Algorithms; Analysis; Biology; Coding; Computer memory; Computer Simulation; Distance learning; Firing pattern; Information processing; Learning; Lower bounds; Mathematical models; Memory; Memory - physiology; Models, Neurological; Neural coding; Neurogenesis; Neurons; Neurons - physiology; Neurosciences; Noise reduction; Online education; Online instruction; Science; Singers; Spikes; Synapses - physiology; Temporal variations; Time Factors; United States > US
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0040233

In many cases, neurons process information carried by the precise timings of spikes. Here we show how neurons can learn to generate specific temporally precise output spikes in response to input patterns of spikes having precise timings, thus processing and memorizing information that is entirely temporally coded, both as input and as output. We introduce two new supervised learning rules for spiking neurons with temporal coding of information (chronotrons), one that provides high memory capacity (E-learning), and one that has a higher biological plausibility (I-learning). With I-learning, the neuron learns to fire the target spike trains through synaptic changes that are proportional to the synaptic currents at the timings of real and target output spikes. We study these learning rules in computer simulations where we train integrate-and-fire neurons. Both learning rules allow neurons to fire at the desired timings, with sub-millisecond precision. We show how chronotrons can learn to classify their inputs, by firing identical, temporally precise spike trains for different inputs belonging to the same class. When the input is noisy, the classification also leads to noise reduction. We compute lower bounds for the memory capacity of chronotrons and explore the influence of various parameters on chronotrons' performance. The chronotrons can model neurons that encode information in the time of the first spike relative to the onset of salient stimuli or neurons in oscillatory networks that encode information in the phases of spikes relative to the background oscillation. Our results show that firing one spike per cycle optimizes memory capacity in neurons encoding information in the phase of firing relative to a background rhythm.