Abstract
Nowadays, the use of computers is becoming very important in various fields of mathematics and engineering sciences. Many complex statistics can be sorted out easily with the help of different computer programs in seconds, especially in computational and applied Mathematics. With the help of different computer tools and languages, a variety of iterative algorithms can be operated in computers for solving different nonlinear problems. The most important factor of an iterative algorithm is its efficiency that relies upon the convergence rate and computational cost per iteration. Taking these facts into account, this article aims to design a new iterative algorithm that is derivative-free and performs better. We construct this algorithm by applying the forward- and finite-difference schemes on Golbabai–Javidi’s method which yields us an efficient and derivative-free algorithm whose computational cost is low as per iteration. We also study the convergence criterion of the designed algorithm and prove its quartic-order convergence. To analyze it numerically, we consider nine different types of numerical test examples and solve them for demonstrating its accuracy, validity, and applicability. The considered problems also involve some real-life applications of civil and chemical engineering. The obtained numerical results of the test examples show that the newly designed algorithm is working better against the other similar algorithms in the literature. For the graphical analysis, we consider some different degrees’ complex polynomials and draw the polynomiographs of the designed quartic-order algorithm and compare it with the other similar existing methods with the help of a computer program. The graphical results reveal the better convergence speed and the other graphical characteristics of the designed algorithm over the other comparable ones.
Highlights
Nowadays, the use of computers is becoming very important in various fields of mathematics and engineering sciences
With the help of different computer tools and languages, a variety of iterative algorithms can be operated in computers for solving different nonlinear problems. e most important factor of an iterative algorithm is its efficiency that relies upon the convergence rate and computational cost per iteration
The mathematicians employed the excessive use of computers in different fields of mathematics. e most important among them is the polynomial’s root finding which has played a significant role in applied and computational mathematics and covers many other fields of modern sciences. ere exist several problems in engineering which arise in the form of nonlinear equations
Summary
The use of computers is becoming very important in various fields of mathematics and engineering sciences. E most important factor of an iterative algorithm is its efficiency that relies upon the convergence rate and computational cost per iteration Taking these facts into account, this article aims to design a new iterative algorithm that is derivative-free and performs better. We study the convergence criterion of the designed algorithm and prove its quartic-order convergence To analyze it numerically, we consider nine different types of numerical test examples and solve them for demonstrating its accuracy, validity, and applicability. We consider some different degrees’ complex polynomials and draw the polynomiographs of the designed quartic-order algorithm and compare it with the other similar existing methods with the help of a computer program. Which is quartic-order algorithm for root finding of scalar nonlinear equations known as Zhanlav’s method (ZM)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
