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Main Authors: Bouzouita, Manel, Zayer, Fakhreddine, Belgacem, Hamdi
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.05356
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author Bouzouita, Manel
Zayer, Fakhreddine
Belgacem, Hamdi
author_facet Bouzouita, Manel
Zayer, Fakhreddine
Belgacem, Hamdi
contents This paper introduces a perspective approach for simulating a memristive sensor tailored for low power biological analyte detection. The necessity for such innovation stems from the increasing demand for efficient biosensing technologies that can operate with minimal poxer consumption. Within this study, a numerical dynamic memristive model serves as a basis platform for implementing enhanced nanosensing method characterized by low cost and high sensitivity. Numerous simulations were conducted to validate the suitability of the dynamic memristive model's behaviour for emulating a chemical sensing approach. The simulated data is collected for deploying an AI application to ensure an advanced predictable biosensing intake function. All in all, this work paves the way for developing compact numerical models of memristive biosensors, addressing the pressing need for portable lox poxer consumption biosensing solutions.
format Preprint
id arxiv_https___arxiv_org_abs_2408_05356
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Simulation of Chemical Engineering Memristive Biosensor
Bouzouita, Manel
Zayer, Fakhreddine
Belgacem, Hamdi
Applied Physics
This paper introduces a perspective approach for simulating a memristive sensor tailored for low power biological analyte detection. The necessity for such innovation stems from the increasing demand for efficient biosensing technologies that can operate with minimal poxer consumption. Within this study, a numerical dynamic memristive model serves as a basis platform for implementing enhanced nanosensing method characterized by low cost and high sensitivity. Numerous simulations were conducted to validate the suitability of the dynamic memristive model's behaviour for emulating a chemical sensing approach. The simulated data is collected for deploying an AI application to ensure an advanced predictable biosensing intake function. All in all, this work paves the way for developing compact numerical models of memristive biosensors, addressing the pressing need for portable lox poxer consumption biosensing solutions.
title Simulation of Chemical Engineering Memristive Biosensor
topic Applied Physics
url https://arxiv.org/abs/2408.05356