English

A Multi-Channel Auditory Signal Encoder with Adaptive Resolution Using Volatile Memristors

Audio and Speech Processing 2025-12-08 v1

Abstract

We demonstrate and experimentally validate an end-to-end hybrid CMOS-memristor auditory encoder that realises adaptive-threshold, asynchronous delta-modulation (ADM)-based spike encoding by exploiting the inherent volatility of HfTiOx devices. A spike-triggered programming pulse rapidly raises the ADM threshold Delta (desensitisation); the device's volatility then passively lowers Delta when activity subsides (resensitisation), emphasising onsets while restoring sensitivity without static control energy. Our prototype couples an 8-channel 130 nm encoder IC to off-chip HfTiOx devices via a switch interface and an off-chip controller that monitors spike activity and issues programming events. An on-chip current-mirror transimpedance amplifier (TIA) converts device current into symmetric thresholds, enabling both sensitive and conservative encoding regimes. Evaluated with gammatone-filtered speech, the adaptive loop-at matched spike budget-sharpens onsets and preserves fine temporal detail that a fixed-Delta baseline misses; multi-channel spike cochleagrams show the same trend. Together, these results establish a practical hybrid CMOS-memristor pathway to onset-salient, spike-efficient neuromorphic audio front-ends and motivate low-power single-chip integration.

Keywords

Cite

@article{arxiv.2512.05701,
  title  = {A Multi-Channel Auditory Signal Encoder with Adaptive Resolution Using Volatile Memristors},
  author = {Dongxu Guo and Deepika Yadav and Patrick Foster and Spyros Stathopoulos and Mingyi Chen and Themis Prodromakis and Shiwei Wang},
  journal= {arXiv preprint arXiv:2512.05701},
  year   = {2025}
}

Comments

11 pages, 17 figures, submitted to IEEE Transactions on Circuits and Systems I: Regular Papers for possible publications

R2 v1 2026-07-01T08:11:30.118Z