Related papers: TEXEL: A neuromorphic processor with on-chip learning for beyond-CMOS device integration

TEXEL: A neuromorphic processor with on-chip learning for beyond-CMOS device integration

URL: http://arxiv.org/abs/2410.15854v1
Date: Mon, 21 Oct 2024 10:30:24 GMT
Title: TEXEL: A neuromorphic processor with on-chip learning for beyond-CMOS device integration
Authors: Hugh Greatorex, Ole Richter, Michele Mastella, Madison Cotteret, Philipp Klein, Maxime Fabre, Arianna Rubino, Willian Soares Girão, Junren Chen, Martin Ziegler, Laura Bégon-Lours, Giacomo Indiveri, Elisabetta Chicca,
Abstract summary: TEXEL is a mixed-signal neuromorphic architecture designed to explore the integration of on-chip learning circuits and novel two- and three-terminal devices. In this paper, we demonstrate the readiness of TEXEL for device integration through comprehensive chip measurements and simulations.
Score: 2.2998185860354057
License: http://creativecommons.org/licenses/by-sa/4.0/
Abstract: Recent advances in memory technologies, devices and materials have shown great potential for integration into neuromorphic electronic systems. However, a significant gap remains between the development of these materials and the realization of large-scale, fully functional systems. One key challenge is determining which devices and materials are best suited for specific functions and how they can be paired with CMOS circuitry. To address this, we introduce TEXEL, a mixed-signal neuromorphic architecture designed to explore the integration of on-chip learning circuits and novel two- and three-terminal devices. TEXEL serves as an accessible platform to bridge the gap between CMOS-based neuromorphic computation and the latest advancements in emerging devices. In this paper, we demonstrate the readiness of TEXEL for device integration through comprehensive chip measurements and simulations. TEXEL provides a practical system for testing bio-inspired learning algorithms alongside emerging devices, establishing a tangible link between brain-inspired computation and cutting-edge device research.

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