English

Neural Network Training with Asymmetric Crosspoint Elements

Machine Learning 2022-02-01 v1 Emerging Technologies Systems and Control Systems and Control

Abstract

Analog crossbar arrays comprising programmable nonvolatile resistors are under intense investigation for acceleration of deep neural network training. However, the ubiquitous asymmetric conductance modulation of practical resistive devices critically degrades the classification performance of networks trained with conventional algorithms. Here, we describe and experimentally demonstrate an alternative fully-parallel training algorithm: Stochastic Hamiltonian Descent. Instead of conventionally tuning weights in the direction of the error function gradient, this method programs the network parameters to successfully minimize the total energy (Hamiltonian) of the system that incorporates the effects of device asymmetry. We provide critical intuition on why device asymmetry is fundamentally incompatible with conventional training algorithms and how the new approach exploits it as a useful feature instead. Our technique enables immediate realization of analog deep learning accelerators based on readily available device technologies.

Keywords

Cite

@article{arxiv.2201.13377,
  title  = {Neural Network Training with Asymmetric Crosspoint Elements},
  author = {Murat Onen and Tayfun Gokmen and Teodor K. Todorov and Tomasz Nowicki and Jesus A. del Alamo and John Rozen and Wilfried Haensch and Seyoung Kim},
  journal= {arXiv preprint arXiv:2201.13377},
  year   = {2022}
}
R2 v1 2026-06-24T09:11:16.220Z