Bernoulli wavelet method for non-linear fractional Glucose–Insulin regulatory dynamical system

Khushbu Agrawal; Ranbir Kumar; Sunil Kumar; Samir Hadid; Shaher Momani

doi:10.1016/j.chaos.2022.112632

Bernoulli wavelet method for non-linear fractional Glucose–Insulin regulatory dynamical system

Khushbu Agrawal
, Ranbir Kumar
, Sunil Kumar
, Samir Hadid
, Shaher Momani

Nonlinear Dynamic Research Centre (NDRC)

National Institute of Technology Jamshedpur
Maharani Janki Kunwar College
King Saud University
Chandigarh University
Ajman University
University of Jordan

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

In this paper, we propose a model that explains the glucose–insulin regulatory system (GIRS). The literature has demonstrated that fractional-order analysis can uncover new aspects of complex systems that were not previously explored. As a result of our studies, the GIRS is stable in its non-linear fractional-order form. Each numerical investigation is derived in order to demonstrate the effectiveness and applicability of fractional order analysis, including the Toufik–Atangana method and the Bernoulli wavelet operational matrix method (BWOMM). An unregulated glucose–insulin system causes a wide variety of biological disorders. These studies may permit a deeper understanding of the regulatory system.

Original language	English
Article number	112632
Journal	Chaos, Solitons and Fractals
Volume	164
DOIs	https://doi.org/10.1016/j.chaos.2022.112632
State	Published - Nov 2022

Keywords

Bernoulli wavelet method
Caputo fractional derivative
Dynamical behavior
Fractional order model
Laplace transformation
Operational matrix
Stability analysis
Toufik–Atangana method

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10.1016/j.chaos.2022.112632

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title = "Bernoulli wavelet method for non-linear fractional Glucose–Insulin regulatory dynamical system",

abstract = "In this paper, we propose a model that explains the glucose–insulin regulatory system (GIRS). The literature has demonstrated that fractional-order analysis can uncover new aspects of complex systems that were not previously explored. As a result of our studies, the GIRS is stable in its non-linear fractional-order form. Each numerical investigation is derived in order to demonstrate the effectiveness and applicability of fractional order analysis, including the Toufik–Atangana method and the Bernoulli wavelet operational matrix method (BWOMM). An unregulated glucose–insulin system causes a wide variety of biological disorders. These studies may permit a deeper understanding of the regulatory system.",

keywords = "Bernoulli wavelet method, Caputo fractional derivative, Dynamical behavior, Fractional order model, Laplace transformation, Operational matrix, Stability analysis, Toufik–Atangana method",

author = "Khushbu Agrawal and Ranbir Kumar and Sunil Kumar and Samir Hadid and Shaher Momani",

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doi = "10.1016/j.chaos.2022.112632",

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TY - JOUR

T1 - Bernoulli wavelet method for non-linear fractional Glucose–Insulin regulatory dynamical system

AU - Agrawal, Khushbu

AU - Kumar, Ranbir

AU - Kumar, Sunil

AU - Hadid, Samir

AU - Momani, Shaher

PY - 2022/11

Y1 - 2022/11

N2 - In this paper, we propose a model that explains the glucose–insulin regulatory system (GIRS). The literature has demonstrated that fractional-order analysis can uncover new aspects of complex systems that were not previously explored. As a result of our studies, the GIRS is stable in its non-linear fractional-order form. Each numerical investigation is derived in order to demonstrate the effectiveness and applicability of fractional order analysis, including the Toufik–Atangana method and the Bernoulli wavelet operational matrix method (BWOMM). An unregulated glucose–insulin system causes a wide variety of biological disorders. These studies may permit a deeper understanding of the regulatory system.

AB - In this paper, we propose a model that explains the glucose–insulin regulatory system (GIRS). The literature has demonstrated that fractional-order analysis can uncover new aspects of complex systems that were not previously explored. As a result of our studies, the GIRS is stable in its non-linear fractional-order form. Each numerical investigation is derived in order to demonstrate the effectiveness and applicability of fractional order analysis, including the Toufik–Atangana method and the Bernoulli wavelet operational matrix method (BWOMM). An unregulated glucose–insulin system causes a wide variety of biological disorders. These studies may permit a deeper understanding of the regulatory system.

KW - Bernoulli wavelet method

KW - Caputo fractional derivative

KW - Dynamical behavior

KW - Fractional order model

KW - Laplace transformation

KW - Operational matrix

KW - Stability analysis

KW - Toufik–Atangana method

UR - https://www.scopus.com/pages/publications/85138156401

U2 - 10.1016/j.chaos.2022.112632

DO - 10.1016/j.chaos.2022.112632

M3 - Article

AN - SCOPUS:85138156401

SN - 0960-0779

VL - 164

JO - Chaos, Solitons and Fractals

JF - Chaos, Solitons and Fractals

M1 - 112632

ER -

Bernoulli wavelet method for non-linear fractional Glucose–Insulin regulatory dynamical system

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Keywords

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