Your search keyword '"Moin-ud-Din Junjua"' showing total 26 results

1. Machine learning- a new paradigm in nanoparticle-mediated drug delivery to cancerous tissues through the human cardiovascular system enhanced by magnetic field

Author

Yasmeen Akhtar, Shabbir Ahmad, Fareeha Khalid, Moin-ud-Din Junjua, Yashar Aryanfar, Ahmed S. Hendy, Mehdi Tlija, and Ahmed T. Soliman

Subjects

Machine learning, Drug delivery, Magnetic field, Cancer tissues, Cardiovascular system, Medicine, Science

Abstract

Abstract Nanoparticle-mediated drug delivery offers a promising approach to targeted cancer therapy, leveraging the ability of nanoparticles to deliver therapeutic agents directly to cancerous tissues with minimal impact on surrounding healthy cells. The presence of these nanoparticles is governed by a concentration equation, which accounts for the diffusion, convection, and reaction of the nanoparticles with the blood components. It is well-known that whenever a disease or infection occurs in a human, in 80% of cases a rise in the concentration of hydrogen peroxide in the blood occurs. This is the reason why blood is assumed to contain hydrogen peroxide (in the present study), which is a biomarker of oxidative stress and inflammation. This study explores the integration of machine learning (ML) techniques into the optimization of drug delivery processes within the human cardiovascular system, focusing on the enhancement of these processes through the application of magnetic fields. By employing ML algorithms, we analyze and predict the behavior of nanoparticles as they navigate the complex fluid dynamics of the cardiovascular system, particularly under the influence of an external magnetic field. The predictive power of ML models enables the precise control of nanoparticle trajectories, optimizing their accumulation in cancerous tissues and improving the efficacy of the drug delivery system. The findings of this study demonstrate that ML-enhanced magnetic targeting can significantly enhance the precision and effectiveness of nanoparticle-mediated drug delivery, offering a new paradigm in cancer treatment strategies. This approach has the potential to revolutionize the field by providing personalized and highly efficient therapeutic solutions for cancer patients.

Published

2024

2. Magnetized and quadratic convection based thermal transport in ternary radiative bio-nanofluid via intelligent neural networks: Two hidden layers mechanism

Author

Assad Ayub, Adil Darvesh, Syed Zahir Hussain Shah, Moin-ud-Din Junjua, Elizaldo Domingues dos Santos, Shabbir Ahmad, Ahmed S. Hendy, and Adham E. Ragab

Subjects

Thermal scrutiny, Blood fluid, Ternary nanoparticles, Magnetized environment, Intelligent neural network, Physics, QC1-999

Abstract

Significance: The thermal analysis of nanofluid in a vertical cylinder (artery) in a magnetized environment holds significant implications in physiological and thermal regulation networks. This research is significant in biomedical engineering with applications like medical diagnostics and treatment strategies. Motive: This study investigates the thermal behavior of a magnetized blood-based ternary Carreau nanofluid flowing through a vertically bounded artery with quadratic convection. Velocity and heat transfer analysis is conducted within the artery, utilizing thermal radiation and quadratic convection in a magnetized setting. The base fluid consists of blood, augmented with three nanoparticles: CuO, Al2O3, and TiO2. The investigation centers on examining the properties of blood nanofluid, arterial geometry, and thermal dynamics. Methodology: The physical model generates a set of partial differential equations (PDEs) and similarities mechanism is utilized to fetch its non dimensional form in terms of ordinary differential equations (ODEs). Furthermore, numerical outcomes are obtained with Matlab function bvp4c and obtained data set is trained through robust scheme Levenberg-Marquardt neural network (LMNN) procedure to predict the solution. Findings: Velocity of blood is reduced with increased values of wiessenberg number, magnetic parameter and mixed convection parameter and velocity increases for Second-order convection parameter. Temperature profile decreases with curvature parameter, mixed convection parameter and permeability parameter.

Published

2024

3. Optical soliton solutions of nonlinear differential Boussinesq water wave equation via two analytical techniques

Author

Waseem Razzaq, Asim Zafar, Abdullah Nazir, Moin-ud-Din Junjua, Fuad A. Awwad, and Emad A.A. Ismail

Subjects

Modified (G′/G2)- expansion method, F-expansion method, Boussinesq water wave equation, Exact solutions, Optical soliton solutions, Physics, QC1-999

Abstract

In this article, we examine the optical soliton solutions of the 4th-order nonlinear Boussinesq water wave equation using the modified (G′/G2)− expansion and F-expansion methods. We utilize the similarity transformation to transform the partial differential form of the equation into an ordinary differential form. These techniques present a variety of solutions, including bright, dark, singular, dark-periodic, and singular-periodic soliton solutions. We plot the derived solutions in several profiles, such as 2D, 3D, and contour, to illustrate their physical appearance. The determined findings might be useful and have an enormous effect on the research of nonlinear phenomena in a variety of physical areas of science, like shallow water waves, acoustics, fluid dynamics, laser optics, communication systems, and heat transfer. The achieved results demonstrate the validity, applicability, and effectiveness of the presented method. We plot and validate the found solutions using the computational program MATHEMATICA.

Published

2024

4. A Robust and Optimal Iterative Algorithm Employing a Weight Function for Solving Nonlinear Equations with Dynamics and Applications

Author

Shahid Abdullah, Neha Choubey, Suresh Dara, Moin-ud-Din Junjua, and Tawseef Abdullah

Subjects

iterative method, optimal algorithm, weight function approach, order of convergence, basins of attraction, Mathematics, QA1-939

Abstract

This study introduces a novel, iterative algorithm that achieves fourth-order convergence for solving nonlinear equations. Satisfying the Kung–Traub conjecture, the proposed technique achieves an optimal order of four with an efficiency index (I) of 1.587, requiring three function evaluations. An analysis of convergence is presented to show the optimal fourth-order convergence. To verify the theoretical results, in-depth numerical comparisons are presented for both real and complex domains. The proposed algorithm is specifically examined on a variety of polynomial functions, and it is shown by the efficient and accurate results that it outperforms many existing algorithms in terms of speed and accuracy. The study not only explores the proposed method’s convergence properties, computational efficiency, and stability but also introduces a novel perspective by considering the count of black points as an indicator of a method’s divergence. By analyzing the mean number of iterations necessary for methods to converge within a cycle and measuring CPU time in seconds, this research provides a holistic assessment of both the efficiency and speed of iterative methods. Notably, the analysis of basins of attraction illustrates that our proposed method has larger sets of initial points that yield convergence.

Published

2024

5. Analysis of Truncated M-Fractional Mathematical and Physical (2+1)-Dimensional Nonlinear Kadomtsev–Petviashvili-Modified Equal-Width Model

Author

Mohammed Ahmed Alomair and Moin-ud-Din Junjua

Subjects

nonlinear Kadomtsev–Petviashvili-modified equal-width equation, fractional derivative, analytical methods, exact wave solitons, Thermodynamics, QC310.15-319, Mathematics, QA1-939, Analysis, QA299.6-433

Abstract

This study focuses on the mathematical and physical analysis of a truncated M-fractional (2+1)-dimensional nonlinear Kadomtsev–Petviashvili-modified equal-width model. The distinct types of the exact wave solitons of an important real-world equation called the truncated M-fractional (2+1)-dimensional nonlinear Kadomtsev–Petviashvili-modified equal-width (KP-mEW) model are achieved. This model is used to explain ocean waves, matter-wave pulses, waves in ferromagnetic media, and long-wavelength water waves. The diverse patterns of waves on the oceans are yielded by the Kadomtsev–Petviashvili-modified equal-width (KP-mEW) equation. We obtain kink-, bright-, and periodic-type soliton solutions by using the expa function and modified extended tanh function methods. The solutions are more valuable than the existing results due to the use of a truncated M-fractional derivative. These solutions may be useful in different areas of science and engineering. The methods applied are simple and useful.

Published

2024

6. Kink, Dark, Bright, and Singular Optical Solitons to the Space–Time Nonlinear Fractional (41)-Dimensional Davey–Stewartson–Kadomtsev–Petviashvili Model+

Author

Abdulaziz Khalid Alsharidi and Moin-ud-Din Junjua

Subjects

Davey–Stewartson–Kadomtsev–Petviashvili model, truncated M-fractional derivative, unified technique, modified extended tanh-expansion function technique, exact solitons, Thermodynamics, QC310.15-319, Mathematics, QA1-939, Analysis, QA299.6-433

Abstract

The new types of exact solitons of the space–time fractional nonlinear (4+1)-dimensional Davey–Stewartson–Kadomtsev–Petviashvili (DSKP) model are achieved by applying the unified technique and modified extended tanh-expansion function technique. A novel definition of the fractional derivative known as the truncated M-fractional derivative is also used. This model describes both the non-elastic and elastic interactions between internal waves. This model is used to represent intricate nonlinear phenomena like shallow-water waves, plasma physics, and others. The obtained results are in the form of kink, singular, bright, periodic, and dark solitons. The observed results are verified and represented by 2D and 3D graphs. The observed results are not present in the literature due to the use of fractional derivatives. The impact of the truncated M-fractional derivative on the observed results is also represented by graphs. Hence, our observed results are fruitful for the future study of these models. The applied techniques are simple, fruitful, and reliable in solving the other models in applied mathematics.

Published

2024

7. Impressive Exact Solitons to the Space-Time Fractional Mathematical Physics Model via an Effective Method

Author

Abdulaziz Khalid Alsharidi and Moin-ud-Din Junjua

Subjects

fractional modified mixed-KdV equation, modified extended direct algebraic method, exact soliton solutions, Thermodynamics, QC310.15-319, Mathematics, QA1-939, Analysis, QA299.6-433

Abstract

A new class of truncated M-fractional exact soliton solutions for a mathematical physics model known as a truncated M-fractional (1+1)-dimensional nonlinear modified mixed-KdV model are achieved. We obtain these solutions by using a modified extended direct algebraic method. The obtained results consist of trigonometric, hyperbolic trigonometric and mixed functions. We also discuss the effect of fractional order derivative. To validate our results, we utilized the Mathematica software. Additionally, we depict some of the obtained kink, periodic, singular, and kink-singular wave solitons, using two and three dimensional graphs. The obtained results are useful in the fields of fluid dynamics, nonlinear optics, ocean engineering and others. Furthermore, these employed techniques are not only straightforward, but also highly effective when used to solve non-linear fractional partial differential equations (FPDEs).

Published

2024

8. A Study of Some New Hermite–Hadamard Inequalities via Specific Convex Functions with Applications

Author

Moin-ud-Din Junjua, Ather Qayyum, Arslan Munir, Hüseyin Budak, Muhammad Mohsen Saleem, and Siti Suzlin Supadi

Subjects

exponential convex function, fractional integrals, Hölder’s inequality, power-mean inequality, Mathematics, QA1-939

Abstract

Convexity plays a crucial role in the development of fractional integral inequalities. Many fractional integral inequalities are derived based on convexity properties and techniques. These inequalities have several applications in different fields such as optimization, mathematical modeling and signal processing. The main goal of this article is to establish a novel and generalized identity for the Caputo–Fabrizio fractional operator. With the help of this specific developed identity, we derive new fractional integral inequalities via exponential convex functions. Furthermore, we give an application to some special means.

Published

2024

9. New exact solitary wave solutions for fractional model

Author

Ayyaz Ali, Zafar Ullah, Irfan Waheed, Moin-ud-Din Junjua, Muhammad Mohsen Saleem, Gulnaz Atta, Maimoona Karim, and Ather Qayyum

Subjects

reaction-diffusion equation, exact solutions, (−φ(η))-expansion technique, exp caputo's derivative, Mathematics, QA1-939

Abstract

This manuscript involves the new exact solitary wave solutions of fractional reaction-diffusion model using the exp (− φ(η))-expansion method. The spatial model of fractional form is applied in modeling super-diffusive systems in the field of engineering, biology, physics (neutron diffusion theory), ecology, finance, and chemistry. The findings of miscellaneous studies showed that presented method is efficient for exploring new exact solutions to solve the complexities arising in mathematical physics and applied sciences. The new solutions which are obtained in the form of the rational, exponential, hyperbolic and trigonometric functions have a wide range in physics and engineering fields. Several results would be obtained under various parameters which shows good agreement with the previous published results of different papers. The proposed method can be extended to solve further problems arising in the engineering fields. My main contribution is programming and comparisons.

Published

2022

10. Extension of King’s Iterative Scheme by Means of Memory for Nonlinear Equations

Author

Saima Akram, Maira Khalid, Moin-ud-Din Junjua, Shazia Altaf, and Sunil Kumar

Subjects

nonlinear equation, multipoint iterative methods, convergence order, with-memory method, efficiency index, polynomiography, Mathematics, QA1-939

Abstract

We developed a new family of optimal eighth-order derivative-free iterative methods for finding simple roots of nonlinear equations based on King’s scheme and Lagrange interpolation. By incorporating four self-accelerating parameters and a weight function in a single variable, we extend the proposed family to an efficient iterative scheme with memory. Without performing additional functional evaluations, the order of convergence is boosted from 8 to 15.51560, and the efficiency index is raised from 1.6817 to 1.9847. To compare the performance of the proposed and existing schemes, some real-world problems are selected, such as the eigenvalue problem, continuous stirred-tank reactor problem, and energy distribution for Planck’s radiation. The stability and regions of convergence of the proposed iterative schemes are investigated through graphical tools, such as 2D symmetric basins of attractions for the case of memory-based schemes and 3D stereographic projections in the case of schemes without memory. The stability analysis demonstrates that our newly developed schemes have wider symmetric regions of convergence than the existing schemes in their respective domains.

Published

2023

11. A novel analytical technique to obtain the solitary solutions for nonlinear evolution equation of fractional order

Author

Abdul Ghaffar, Ayyaz Ali, Sarfaraz Ahmed, Saima Akram, Moin-ud-Din Junjua, Dumitru Baleanu, and Kottakkaran Sooppy Nisar

Subjects

Simplified modified Camassa–Holm (SMCH) equation, Fractional calculus, Caputo’s derivative of fractional order, Solitary wave solutions, Extended rational exp ( ( ψ ′ ψ ) ( η ) ) $\exp ((\frac{\psi '}{\psi })(\eta ))$ -expansion method, Mathematics, QA1-939

Abstract

Abstract We investigate some solitary wave results of time fractional evolution equations. By employing the extended rational exp ( ( − ψ ′ ψ ) ( η ) ) $\exp ( (-\frac{{\psi }^{\prime }}{\psi }) ( \eta ) )$ -expansion method, a few different results including kink, singular-kink, multiple soliton, and periodic wave solutions are formally generated. It is worth mentioning that the solutions obtained are more general with more parameters. The exact solutions are constructed in the form of exponential, trigonometric, rational, and hyperbolic functions. With the choice of proper values of parameters, graphs to some of the obtained solutions are drawn. On comparing some special cases, our solutions are in good agreement with the results published previously and the remaining are new.

Published

2020

12. A Family of Optimal Eighth Order Iteration Functions for Multiple Roots and Its Dynamics

Author

Saima Akram, Faiza Akram, Moin-ud-Din Junjua, Misbah Arshad, and Tariq Afzal

Subjects

Mathematics, QA1-939

Abstract

In this manuscript, we present a new general family of optimal iterative methods for finding multiple roots of nonlinear equations with known multiplicity using weight functions. An extensive convergence analysis is presented to verify the optimal eighth order convergence of the new family. Some special cases of the family are also presented which require only three functions and one derivative evaluation at each iteration to reach optimal eighth order convergence. A variety of numerical test functions along with some real-world problems such as beam designing model and Van der Waals’ equation of state are presented to ensure that the newly developed family efficiently competes with the other existing methods. The dynamical analysis of the proposed methods is also presented to validate the theoretical results by using graphical tools, termed as the basins of attraction.

Published

2021

13. Some (p, q)-Estimates of Hermite-Hadamard-Type Inequalities for Coordinated Convex and Quasi- Convex Functions

Author

Humaira Kalsoom, Muhammad Amer, Moin-ud-Din Junjua, Sabir Hussain, and Gullnaz Shahzadi

Subjects

Hermite-Hadamard inequality, (p, q)-calculus of functions of two variables, partial derivatives in (p, q)-calculus of the functions of two variables, multiple integrals in (p, q)-calculus of the functions of two variables, Hölder’s inequality in (p, q)-calculus of the functions of two variables, coordinated convexity, coordinated quasi-convexity inequality, Mathematics, QA1-939

Abstract

In this paper, we present the preliminaries of ( p , q ) -calculus for functions of two variables. Furthermore, we prove some new Hermite-Hadamard integral-type inequalities for convex functions on coordinates over [ a , b ] × [ c , d ] by using the ( p , q ) -calculus of the functions of two variables. Furthermore, we establish an identity for the right-hand side of the Hermite-Hadamard-type inequalities on coordinates that is proven by using the ( p , q ) -calculus of the functions of two variables. Finally, we use the new identity to prove some trapezoidal-type inequalities with the assumptions of convexity and quasi-convexity on coordinates of the absolute values of the partial derivatives defined in the ( p , q ) -calculus of the functions of two variables.

Published

2019

14. Optimal Derivative-Free Root Finding Methods Based on Inverse Interpolation

Author

Moin-ud-Din Junjua, Fiza Zafar, and Nusrat Yasmin

Subjects

nonlinear equations, simple roots, inverse interpolation, optimal iterative methods, higher order of convergence, Mathematics, QA1-939

Abstract

Finding a simple root for a nonlinear equation f ( x ) = 0 , f : I ⊆ R → R has always been of much interest due to its wide applications in many fields of science and engineering. Newton’s method is usually applied to solve this kind of problems. In this paper, for such problems, we present a family of optimal derivative-free root finding methods of arbitrary high order based on inverse interpolation and modify it by using a transformation of first order derivative. Convergence analysis of the modified methods confirms that the optimal order of convergence is preserved according to the Kung-Traub conjecture. To examine the effectiveness and significance of the newly developed methods numerically, several nonlinear equations including the van der Waals equation are tested.

Published

2019

15. A New Jarratt-Type Fourth-Order Method for Solving System of Nonlinear Equations and Applications

Author

Moin-ud-Din Junjua, Saima Akram, Nusrat Yasmin, and Fiza Zafar

Subjects

Mathematics, QA1-939

Abstract

Solving systems of nonlinear equations plays a major role in engineering problems. We present a new family of optimal fourth-order Jarratt-type methods for solving nonlinear equations and extend these methods to solve system of nonlinear equations. Convergence analysis is given for both cases to show that the order of the new methods is four. Cost of computations, numerical tests, and basins of attraction are presented which illustrate the new methods as better alternates to previous methods. We also give an application of the proposed methods to well-known Burger's equation.

Published

2015

16. A General Class of Derivative Free Optimal Root Finding Methods Based on Rational Interpolation

Author

Fiza Zafar, Nusrat Yasmin, Saima Akram, and Moin-ud-Din Junjua

Subjects

Technology, Medicine, Science

Abstract

We construct a new general class of derivative free n-point iterative methods of optimal order of convergence 2n-1 using rational interpolant. The special cases of this class are obtained. These methods do not need Newton’s iterate in the …first step of their iterative schemes. Numerical computations are presented to show that the new methods are efficient and can be seen as better alternates.

Published

2015

17. A new two‐point scheme for multiple roots of nonlinear equations

Author

Moin-ud-Din Junjua, Ramandeep Behl, Fiza Zafar, and Ali Saleh Alshomrani

Subjects

Nonlinear system, symbols.namesake, Van der Waals equation, Iterative method, General Mathematics, Scheme (mathematics), General Engineering, symbols, Applied mathematics, Point (geometry), Mathematics

Published

2020

18. A Family of Optimal Eighth Order Iteration Functions for Multiple Roots and Its Dynamics

Author

Moin-ud-Din Junjua, Misbah Arshad, Saima Akram, Faiza Akram, and Tariq Afzal

Subjects

Equation of state, Article Subject, Iterative method, General Mathematics, Multiplicity (mathematics), 010103 numerical & computational mathematics, 02 engineering and technology, 01 natural sciences, Nonlinear system, Dynamics (music), Convergence (routing), QA1-939, 0202 electrical engineering, electronic engineering, information engineering, Order (group theory), Applied mathematics, 020201 artificial intelligence & image processing, 0101 mathematics, Variety (universal algebra), Mathematics

Abstract

In this manuscript, we present a new general family of optimal iterative methods for finding multiple roots of nonlinear equations with known multiplicity using weight functions. An extensive convergence analysis is presented to verify the optimal eighth order convergence of the new family. Some special cases of the family are also presented which require only three functions and one derivative evaluation at each iteration to reach optimal eighth order convergence. A variety of numerical test functions along with some real-world problems such as beam designing model and Van der Waals’ equation of state are presented to ensure that the newly developed family efficiently competes with the other existing methods. The dynamical analysis of the proposed methods is also presented to validate the theoretical results by using graphical tools, termed as the basins of attraction.

Published

2021

19. A novel analytical technique to obtain the solitary solutions for nonlinear evolution equation of fractional order

Author

Saima Akram, Dumitru Baleanu, Abdul Ghaffar, Moin-ud-Din Junjua, Sarfaraz Ahmed, Ayyaz Ali, and Kottakkaran Sooppy Nisar

Subjects

Algebra and Number Theory, Partial differential equation, 010308 nuclear & particles physics, lcsh:Mathematics, Applied Mathematics, Mathematical analysis, Hyperbolic function, Fractional calculus, Order (ring theory), Caputo’s derivative of fractional order, lcsh:QA1-939, 01 natural sciences, Prime (order theory), 010305 fluids & plasmas, Exponential function, Ordinary differential equation, Simplified modified Camassa–Holm (SMCH) equation, Extended rational exp ( ( ψ ′ ψ ) ( η ) ) $\exp ((\frac{\psi '}{\psi })(\eta ))$ -expansion method, 0103 physical sciences, Soliton, Trigonometry, Analysis, Solitary wave solutions, Mathematics

Abstract

We investigate some solitary wave results of time fractional evolution equations. By employing the extended rational $\exp ( (-\frac{{\psi }^{\prime }}{\psi }) ( \eta ) )$exp((−ψ′ψ)(η))-expansion method, a few different results including kink, singular-kink, multiple soliton, and periodic wave solutions are formally generated. It is worth mentioning that the solutions obtained are more general with more parameters. The exact solutions are constructed in the form of exponential, trigonometric, rational, and hyperbolic functions. With the choice of proper values of parameters, graphs to some of the obtained solutions are drawn. On comparing some special cases, our solutions are in good agreement with the results published previously and the remaining are new.

Published

2020

20. Optimal eighth-order iterative methods for approximating multiple zeros of nonlinear functions

Author

Fiza Zafar, Moin-ud-Din Junjua, Alicia Cordero, and Juan R. Torregrosa

Subjects

Algebra and Number Theory, Multiple zeros, Optimality, Iterative method, Applied Mathematics, 010102 general mathematics, Nonlinear equations, Residual, 01 natural sciences, 010101 applied mathematics, Computational Mathematics, Nonlinear system, Rate of convergence, Order of convergence, Applied mathematics, Geometry and Topology, 0101 mathematics, Multiple roots, MATEMATICA APLICADA, Analysis, Mathematics

Abstract

[EN] It is well known that the optimal iterative methods are of more significance than the non-optimal ones in view of their efficiency and convergence speed. There are only a few number of optimal iterative methods for finding multiple zeros with eighth order of convergence. In this paper, we propose a new family of optimal eighth order convergent iterative methods for multiple roots with known multiplicity. We present an extensive convergence analysis which confirms theoretically eighth-order convergence of the presented scheme. Moreover, we consider several real life problems that contain simple as well as multiple zeros in order to compare our proposed methods with the existing eighth-order iterative schemes. Some dynamical aspects of the presented methods are also discussed. Finally, we conclude on the basis of obtained numerical results that the proposed family of iterative methods perform better than the existing methods in terms of residual error, computational order of convergence and difference between the two consecutive iterations., This research was partially supported by PGC2018-095896-B-C22 (MCIU/AEI/FEDER, UE), Generalitat Valenciana PROMETEO/2016/089 and Schlumberger Foundation-Faculty for Future Program.

Published

2020

21. On the construction of three step derivative free four-parametric methods with accelerated order of convergence

Author

Nusrat Yasmin, Fiza Zafar, Moin-ud-Din Junjua, and Saima Akram

Subjects

010101 applied mathematics, chemistry.chemical_compound, Algebra and Number Theory, chemistry, Rate of convergence, Applied mathematics, Parametric methods, 010103 numerical & computational mathematics, 0101 mathematics, 01 natural sciences, Analysis, Derivative (chemistry), Mathematics

Published

2016

22. Efficient Four-Parametric with-and-without-Memory Iterative Methods Possessing High Efficiency Indices

Author

Fiza Zafar, Alicia Cordero, Juan R. Torregrosa, Nusrat Yasmin, and Moin-ud-Din Junjua

Subjects

Class (set theory), Article Subject, Iterative method, Computer science, lcsh:Mathematics, General Mathematics, General Engineering, Zero (complex analysis), 010103 numerical & computational mathematics, Extension (predicate logic), lcsh:QA1-939, 01 natural sciences, 010101 applied mathematics, Nonlinear system, lcsh:TA1-2040, Simple (abstract algebra), Applied mathematics, 0101 mathematics, lcsh:Engineering (General). Civil engineering (General), MATEMATICA APLICADA, Parametric statistics

Abstract

[EN] We construct a family of derivative-free optimal iterative methods without memory to approximate a simple zero of a nonlinear function. Error analysis demonstrates that the without-memory class has eighth-order convergence and is extendable to with-memory class. The extension of new family to the with-memory one is also presented which attains the convergence order 15.5156 and a very high efficiency index 15.5156(1/4) approximate to 1.9847. Some particular schemes of the with-memory family are also described. Numerical examples and some dynamical aspects of the new schemes are given to support theoretical results., This research was partially supported by Ministerio de Economia y Competitividad under Grant MTM2014-52016-C2-2-P, Generalitat Valenciana PROMETEO/2016/089, and Schlumberger Foundation, Faculty for the Future Program.

Published

2018

23. Some (p,q)-Estimates of Hermite-Hadamard-Type Inequalities for Coordinated Convex and Quasi- Convex Functions

Author

Gullnaz Shahzadi, Sabir Hussain, Moin-ud-Din Junjua, Humaira Kalsoom, and Muhammad Amer

Subjects

General Mathematics, Mathematics::Classical Analysis and ODEs, partial derivatives in (p,q)-calculus of the functions of two variables, 01 natural sciences, Convexity, multiple integrals in (p, q)-calculus of the functions of two variables, Combinatorics, Identity (mathematics), Hölder’s inequality in p,q-calculus of the functions of two variables, Hadamard transform, (p, q)-calculus of functions of two variables, Hermite–Hadamard inequality, Computer Science (miscellaneous), multiple integrals in (p,q)-calculus of the functions of two variables, 0101 mathematics, Engineering (miscellaneous), Mathematics, Hermite polynomials, lcsh:Mathematics, 010102 general mathematics, Regular polygon, coordinated quasi-convexity inequality, lcsh:QA1-939, Hölder’s inequality in (p, q)-calculus of the functions of two variables, 010101 applied mathematics, TheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGES, Hermite-Hadamard inequality, partial derivatives in (p, q)-calculus of the functions of two variables, (p,q)-calculus of functions of two variables, coordinated convexity, Partial derivative, Convex function

Abstract

In this paper, we present the preliminaries of ( p , q ) -calculus for functions of two variables. Furthermore, we prove some new Hermite-Hadamard integral-type inequalities for convex functions on coordinates over [ a , b ] &times, [ c , d ] by using the ( p , q ) -calculus of the functions of two variables. Furthermore, we establish an identity for the right-hand side of the Hermite-Hadamard-type inequalities on coordinates that is proven by using the ( p , q ) -calculus of the functions of two variables. Finally, we use the new identity to prove some trapezoidal-type inequalities with the assumptions of convexity and quasi-convexity on coordinates of the absolute values of the partial derivatives defined in the ( p , q ) -calculus of the functions of two variables.

Published

2019

24. An Optimal Eighth-Order Scheme for Multiple Zeros of Univariate Functions

Author

Ali Saleh Alshormani, Ramandeep Behl, Nusrat Yasmin, Fiza Zafar, and Moin-ud-Din Junjua

Subjects

Multiple zeros, Iterative method, Univariate, Multiplicity (mathematics), 010103 numerical & computational mathematics, 02 engineering and technology, Residual, 01 natural sciences, Computational Mathematics, Nonlinear system, Rate of convergence, 0202 electrical engineering, electronic engineering, information engineering, Computer Science (miscellaneous), Applied mathematics, 020201 artificial intelligence & image processing, 0101 mathematics, Mathematics

Abstract

We construct an optimal eighth-order scheme which will work for multiple zeros with multiplicity [Formula: see text], for the first time. Earlier, the maximum convergence order of multi-point iterative schemes was six for multiple zeros in the available literature. So, the main contribution of this study is to present a new higher-order and as well as optimal scheme for multiple zeros for the first time. In addition, we present an extensive convergence analysis with the main theorem which confirms theoretically eighth-order convergence of the proposed scheme. Moreover, we consider several real life problems which contain simple as well as multiple zeros in order to compare with the existing robust iterative schemes. Finally, we conclude on the basis of obtained numerical results that our iterative methods perform far better than the existing methods in terms of residual error, computational order of convergence and difference between the two consecutive iterations.

Published

2019

25. A New Jarratt-Type Fourth-Order Method for Solving System of Nonlinear Equations and Applications

Author

Fiza Zafar, Saima Akram, Moin-ud-Din Junjua, and Nusrat Yasmin

Subjects

Mathematical optimization, Article Subject, Applied Mathematics, Computation, lcsh:Mathematics, Relaxation (iterative method), lcsh:QA1-939, L-stability, Nonlinear system, Multigrid method, Simultaneous equations, Convergence (routing), Applied mathematics, Equation solving, Mathematics

Abstract

Solving systems of nonlinear equations plays a major role in engineering problems. We present a new family of optimal fourth-order Jarratt-type methods for solving nonlinear equations and extend these methods to solve system of nonlinear equations. Convergence analysis is given for both cases to show that the order of the new methods is four. Cost of computations, numerical tests, and basins of attraction are presented which illustrate the new methods as better alternates to previous methods. We also give an application of the proposed methods to well-known Burger's equation.

Published

2015

26. A general class of derivative free optimal root finding methods based on rational interpolation

Author

Fiza Zafar, Nusrat Yasmin, Saima Akram, and Moin-ud-Din Junjua

Subjects

Class (set theory), Article Subject, Iterative method, Computer science, lcsh:T, Computation, lcsh:R, lcsh:Medicine, General Medicine, Derivative, lcsh:Technology, General Biochemistry, Genetics and Molecular Biology, Rate of convergence, Applied mathematics, lcsh:Q, lcsh:Science, Algorithm, Root-finding algorithm, General Environmental Science, Interpolation, Research Article

Abstract

We construct a new general class of derivative freen-point iterative methods of optimal order of convergence2n-1using rational interpolant. The special cases of this class are obtained. These methods do not need Newton’s iterate in the…first step of their iterative schemes. Numerical computations are presented to show that the new methods are efficient and can be seen as better alternates.

Published

2014