English

A 28-nm Convolutional Neuromorphic Processor Enabling Online Learning with Spike-Based Retinas

Neural and Evolutionary Computing 2020-05-14 v1 Emerging Technologies Image and Video Processing

Abstract

In an attempt to follow biological information representation and organization principles, the field of neuromorphic engineering is usually approached bottom-up, from the biophysical models to large-scale integration in silico. While ideal as experimentation platforms for cognitive computing and neuroscience, bottom-up neuromorphic processors have yet to demonstrate an efficiency advantage compared to specialized neural network accelerators for real-world problems. Top-down approaches aim at answering this difficulty by (i) starting from the applicative problem and (ii) investigating how to make the associated algorithms hardware-efficient and biologically-plausible. In order to leverage the data sparsity of spike-based neuromorphic retinas for adaptive edge computing and vision applications, we follow a top-down approach and propose SPOON, a 28-nm event-driven CNN (eCNN). It embeds online learning with only 16.8-% power and 11.8-% area overheads with the biologically-plausible direct random target projection (DRTP) algorithm. With an energy per classification of 313nJ at 0.6V and a 0.32-mm2^2 area for accuracies of 95.3% (on-chip training) and 97.5% (off-chip training) on MNIST, we demonstrate that SPOON reaches the efficiency of conventional machine learning accelerators while embedding on-chip learning and being compatible with event-based sensors, a point that we further emphasize with N-MNIST benchmarking.

Keywords

Cite

@article{arxiv.2005.06318,
  title  = {A 28-nm Convolutional Neuromorphic Processor Enabling Online Learning with Spike-Based Retinas},
  author = {Charlotte Frenkel and Jean-Didier Legat and David Bol},
  journal= {arXiv preprint arXiv:2005.06318},
  year   = {2020}
}

Comments

Accepted for presentation at the IEEE International Symposium on Circuits and Systems (ISCAS) 2020

R2 v1 2026-06-23T15:30:55.433Z