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Temporal dynamics of TiOx memristor for reservoir computing applications

Temporal dynamics of TiOx memristor for reservoir computing applications
Temporal dynamics of TiOx memristor for reservoir computing applications
The growing computational demands of artificial intelligence have accelerated the development of energy-efficient neuromorphic systems capable of processing spatiotemporal information. Reservoir computing (RC) offers a promising approach with low training complexity, particularly when implemented using emerging devices such as memristors. In this work, we present a memristor-based RC system employing vertically stacked Pt/TiOx/Au volatile memristors that inherently exhibit short-term plasticity. These devices enable temporal information encoding via pulse-driven modulation and natural relaxation. Through a modified MNIST classification task, we demonstrate that the system performance deteriorates significantly with delayed readout and small levels of device variation, highlighting the need for robust timing strategies. A virtual memristor model was also developed to evaluate system performance on the Mackey-Glass chaotic time-series forecasting task, achieving up to 93.6% prediction accuracy by tuning the internal time constant. These findings highlight the importance of precise readout control and variation resilience in the design of practical memristor-based RC systems for real-world neuromorphic applications.
0022-3727
Wang, Alexander-Hanyu
94ff0c41-9d26-4600-9e3f-8f70fe1816cf
Fan, Xiyue
ebef92f2-72cf-456e-a0ba-21b2769edaf3
Zhang, Zixuan
8720bf45-6462-451a-9e0c-1776543eac41
Kapur, Omesh
2be52575-505f-472f-ad9c-ce6fe84c20fd
Huang, Ruomeng
55c6fba5-0275-4471-af5c-fb0dd2daaa64
Simanjuntak, Firman
a5b8dd07-002c-4520-9f67-2dc20d2ff0d5
Chong, Harold
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Thomas, David Barrie
5701997d-7de3-4e57-a802-ea2bd3e6ab6c
Wang, Alexander-Hanyu
94ff0c41-9d26-4600-9e3f-8f70fe1816cf
Fan, Xiyue
ebef92f2-72cf-456e-a0ba-21b2769edaf3
Zhang, Zixuan
8720bf45-6462-451a-9e0c-1776543eac41
Kapur, Omesh
2be52575-505f-472f-ad9c-ce6fe84c20fd
Huang, Ruomeng
55c6fba5-0275-4471-af5c-fb0dd2daaa64
Simanjuntak, Firman
a5b8dd07-002c-4520-9f67-2dc20d2ff0d5
Chong, Harold
795aa67f-29e5-480f-b1bc-9bd5c0d558e1
Thomas, David Barrie
5701997d-7de3-4e57-a802-ea2bd3e6ab6c

Wang, Alexander-Hanyu, Fan, Xiyue, Zhang, Zixuan, Kapur, Omesh, Huang, Ruomeng, Simanjuntak, Firman, Chong, Harold and Thomas, David Barrie (2025) Temporal dynamics of TiOx memristor for reservoir computing applications. Journal of Physics D: Applied Physics, [015101]. (doi:10.1088/1361-6463/ae23de).

Record type: Article

Abstract

The growing computational demands of artificial intelligence have accelerated the development of energy-efficient neuromorphic systems capable of processing spatiotemporal information. Reservoir computing (RC) offers a promising approach with low training complexity, particularly when implemented using emerging devices such as memristors. In this work, we present a memristor-based RC system employing vertically stacked Pt/TiOx/Au volatile memristors that inherently exhibit short-term plasticity. These devices enable temporal information encoding via pulse-driven modulation and natural relaxation. Through a modified MNIST classification task, we demonstrate that the system performance deteriorates significantly with delayed readout and small levels of device variation, highlighting the need for robust timing strategies. A virtual memristor model was also developed to evaluate system performance on the Mackey-Glass chaotic time-series forecasting task, achieving up to 93.6% prediction accuracy by tuning the internal time constant. These findings highlight the importance of precise readout control and variation resilience in the design of practical memristor-based RC systems for real-world neuromorphic applications.

Text
Wang_2026_J._Phys._D__Appl._Phys._59_015101 (1) - Version of Record
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Accepted/In Press date: 25 November 2025
Published date: 24 December 2025
Learn more about School of Electronics and Computer Science research Learn more about Cyber Physical Systems research Learn more about Sustainable Electronic Technologies research

Identifiers

Local EPrints ID: 508510
URI: http://eprints.soton.ac.uk/id/eprint/508510
DOI: doi:10.1088/1361-6463/ae23de
ISSN: 0022-3727
PURE UUID: 67298438-3400-48e6-b65d-e233f3dda888
ORCID for Firman Simanjuntak: ORCID iD orcid.org/0000-0002-9508-5849
ORCID for Harold Chong: ORCID iD orcid.org/0000-0002-7110-5761
ORCID for David Barrie Thomas: ORCID iD orcid.org/0000-0002-9671-0917

Catalogue record

Date deposited: 23 Jan 2026 18:05
Last modified: 24 Jan 2026 03:12

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Contributors

Author: Alexander-Hanyu Wang
Author: Xiyue Fan
Author: Zixuan Zhang
Author: Omesh Kapur
Author: Ruomeng Huang
Author: Firman Simanjuntak ORCID iD
Author: Harold Chong ORCID iD
Author: David Barrie Thomas ORCID iD

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