Litcius/Paper detail

Fast and deep neuromorphic learning with first-spike coding

Julian Göltz, Andreas Baumbach, Sebastian Billaudelle, Ákos F. Kungl, Oliver Breitwieser, Karlheinz Meier, Johannes Schemmel, Laura Kriener, Mihai A. Petrovici

202024 citationsDOI

Abstract

For a biological agent operating under environmental pressure, energy consumption and reaction times are of critical importance. Similarly, engineered systems also strive for short time-to-solution and low energy-to-solution characteristics. At the level of neuronal implementation, this implies achieving the desired results with as few and as early spikes as possible. In the time-to-first-spike coding framework, both of these goals are inherently emerging features of learning. Here, we describe a rigorous derivation of error-backpropagation-based learning for hierarchical networks of leaky integrate-and-fire neurons. This narrows the gap between previous existing models of first-spike-time learning and biological neuronal dynamics, thereby also enabling fast and energy-efficient inference on analog neuromorphic devices that inherit these dynamics from their biological archetypes.

Topics & Concepts

Neuromorphic engineeringSpike (software development)Computer scienceArtificial intelligenceInferenceEnergy consumptionBackpropagationCoding (social sciences)Spiking neural networkDeep learningNeural codingArtificial neural networkEngineeringElectrical engineeringMathematicsStatisticsSoftware engineeringAdvanced Memory and Neural ComputingNeural Networks and Reservoir ComputingNeural dynamics and brain function
Fast and deep neuromorphic learning with first-spike coding | Litcius