A Neuromorphic Single-Electron Circuit for Noise-Shaping Pulse-Density Modulation

Author:

Kikombo Andrew Kilinga1,Asai Tetsuya1,Oya Takahide2,Schmid Alexandre3,Leblebici Yusuf3,Amemiya Yoshihito1

Affiliation:

1. Hokkaido University, Japan

2. Yokohama National University, Japan

3. Swiss Federal Institute of Technology (EPFL), Switzerland

Abstract

We propose a bio-inspired circuit performing pulse-density modulation with single-electron devices. The proposed circuit consists of three single-electron neuronal units, receiving the same input and are connected to a common output. The output is inhibitorily fedback to the three neuronal circuits through a capacitive coupling. The circuit performance was evaluated through Monte-Carlo based computer simulations. We demonstrated that the proposed circuit possesses noise-shaping characteristics, where signal and noises are separated into low and high frequency bands respectively. This significantly improved the signal-to-noise ratio (SNR) by 4.34 dB in the coupled network, as compared to the uncoupled one. The noise-shaping properties are as a result of i) the inhibitory feedback between the output and the neuronal circuits, and ii) static noises (originating from device fabrication mismatches) and dynamic noises (as a result of thermally induced random tunneling events) introduced into the network.

Publisher

IGI Global

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