English

Heterogeneous quantization regularizes spiking neural network activity

Neurons and Cognition 2024-09-30 v1 Neural and Evolutionary Computing

Abstract

The learning and recognition of object features from unregulated input has been a longstanding challenge for artificial intelligence systems. Brains are adept at learning stable representations given small samples of noisy observations; across sensory modalities, this capacity is aided by a cascade of signal conditioning steps informed by domain knowledge. The olfactory system, in particular, solves a source separation and denoising problem compounded by concentration variability, environmental interference, and unpredictably correlated sensor affinities. To function optimally, its plastic network requires statistically well-behaved input. We present a data-blind neuromorphic signal conditioning strategy whereby analog data are normalized and quantized into spike phase representations. Input is delivered to a column of duplicated spiking principal neurons via heterogeneous synaptic weights; this regularizes layer utilization, yoking total activity to the network's operating range and rendering internal representations robust to uncontrolled open-set stimulus variance. We extend this mechanism by adding a data-aware calibration step whereby the range and density of the quantization weights adapt to accumulated input statistics, optimizing resource utilization by balancing activity regularization and information retention.

Keywords

Cite

@article{arxiv.2409.18396,
  title  = {Heterogeneous quantization regularizes spiking neural network activity},
  author = {Roy Moyal and Kyrus R. Mama and Matthew Einhorn and Ayon Borthakur and Thomas A. Cleland},
  journal= {arXiv preprint arXiv:2409.18396},
  year   = {2024}
}
R2 v1 2026-06-28T18:58:58.947Z