Reprint

Numerical Analysis and Computational Mathematics

Edited by
March 2022
204 pages
  • ISBN978-3-0365-3258-5 (Hardback)
  • ISBN978-3-0365-3259-2 (PDF)

This book is a reprint of the Special Issue Numerical Analysis and Computational Mathematics that was published in

Computer Science & Mathematics
Physical Sciences
Summary

Mathematical modeling is an active area of applied mathematics. At its beginning, engineers were the main practitioners of this area of mathematics, developing mathematical models to solve engineering problems in natural sciences.However, analysis methods and models in social sciences are similar to those of nature sciences, including engineering, with the only difference being that instead of using principles of the nature, one uses principles or theories from experts of such social sciences.Models based on ordinary or partial differential equations describe a wide variety of phenomena such as sound, heat, diffusion, electrostatics, electrodynamics, fluid dynamics, elasticity, or quantum mechanics, for example. Further, stochastic models have recently received increasing attention. Obviously, some of these types of complex problems also require a deep analysis of the tools utilized to solve these situations.In this collection, we will attempt to integrate models, methods, and also applications, not only in the scope of traditional natural sciences, but also opening the scope to education and other social sciences. Theory and data-driven models, even in a synergy that gives rise to producing fertile, multidisciplinary, and hybrid models, can be considered.

Format
  • Hardback
License
© by the authors
Keywords
variable-order fractional calculus; Bernoulli polynomials; optimal control-affine problems; operational matrix of fractional integration; pseudomonotone bifunction; Lipschitz-type conditions; equilibrium problem; variational inequalities; equilibrium problem; variational inequalities; strongly pseudomonotone bifunction; Lipschitz-type conditions; kinetic theory; complex systems; stability; parameters; differential equations; equilibrium problem; pseudomonotone bifunction; Lipschitz-type conditions; strong convergence theorems; variational inequality problems; fixed-point problem; repair rate; mathematical modeling; availability; probability; maintenance; homotopy analysis method; uncertainty; interval analysis; simulation; stochastic; susceptible; infected; recovered; entrepreneurship; clustering; longitudinal analysis; nonlinear least squares problem; differential-difference method; divided differences; radius of convergence; residual; error estimates; tensor sum; singular value; shift-and-invert Lanczos method; preconditioned conjugate gradient method; coding theory; engineering; GeoGebra; mathematica; Python; SageMath; WolframAlpha