English

Oscillator-Based Associative Memory with Exponential Capacity: Theory, Algorithms, and Hardware Implementation

Neural and Evolutionary Computing 2026-04-03 v1

Abstract

Associative memory systems enable content-addressable storage and retrieval of patterns, a capability central to biological neural computation and artificial intelligence. Classical implementations such as Hopfield networks face fundamental limitations in memory capacity, scaling at most linearly with network size. We present an associative memory architecture based on Kuramoto oscillator networks with honeycomb topology in which memories are encoded as stable phase-locked configurations. The honeycomb network consists of multiple cycles that share nodes in a chain-like arrangement, creating a one-dimensional lattice of chained+loops. We prove that this architecture achieves exponential memory capacity: a network of NN oscillators can store (2nc/41)m(2\lceil n_c/4 \rceil - 1)^m distinct patterns, where mm honeycomb cycles each contain ncn_c oscillators. Moreover, we fully characterize all stable configurations and prove that each memory's basin of attraction maintains a guaranteed minimum size independent of network scale. Simulations using charge-density-wave (CDW) oscillators validate predicted phase-locking behavior, demonstrating practical realizability in neuromorphic hardware.

Keywords

Cite

@article{arxiv.2604.01469,
  title  = {Oscillator-Based Associative Memory with Exponential Capacity: Theory, Algorithms, and Hardware Implementation},
  author = {Arie Ogranovich and Taosha Guo and Arvind R. Venkatakrishnan and Madelyn Shapiro and Francesco Bullo and Fabio Pasqualetti},
  journal= {arXiv preprint arXiv:2604.01469},
  year   = {2026}
}

Comments

Submitted to IEEE Transactions on Control of Network Systems

R2 v1 2026-07-01T11:50:02.234Z