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MERICAN Journal of Public Diplomacy and International Studies
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- Bridging Theory and Computation Turganbaeva Ramiza Tolibaevna, Qa’llibekov U’mitbek O’serbay Uli
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MERICAN Journal of Public Diplomacy and International Studies
www. grnjournal.us AMERICAN Journal of Public Diplomacy and International Studies Volume 01, Issue 06, 2023 ISSN (E): 2993-2157 Numerical Methods in Mathematics and Informatics: Bridging Theory and Computation Turganbaeva Ramiza Tolibaevna, Qa’llibekov U’mitbek O’serbay Uli, Abatbaev Rasulbek Nietbay Uli, Mnajatdinov Atabek Rafatdin Uli A student of the Faculty of Mathematics of KSU Abstract: Numerical methods play a pivotal role in the fields of mathematics and informatics by providing powerful tools for solving complex mathematical problems that are often intractable through analytical methods alone. This article explores the fundamental concepts, applications, and advancements in numerical methods, highlighting their significance in both theoretical research and practical computational tasks. We delve into various numerical techniques, their underlying principles, and their applications across different branches of mathematics and informatics. Keywords: Numerical methods, mathematics, informatics, root finding, optimization, numerical integration, numerical differentiation, differential equations, linear algebra, machine learning, simulation, modeling. Numerical methods encompass a wide range of techniques used to approximate solutions to mathematical problems, where analytical solutions may be elusive or computationally expensive. These methods bridge the gap between mathematical theory and computational implementation, enabling researchers and practitioners to tackle problems that arise in diverse fields such as physics, engineering, economics, and computer science. Numerical methods for root finding, such as the Newton-Raphson method and the bisection method, play a crucial role in finding solutions to equations that cannot be solved explicitly. Optimization techniques like gradient descent and simulated annealing are fundamental tools for finding optimal solutions in a wide range of applications. Numerical integration techniques, including the trapezoidal rule and Simpson's rule, enable the approximation of definite integrals. These methods are essential for computing areas, volumes, and probabilities in various mathematical and scientific contexts. Similarly, numerical differentiation methods help estimate derivatives of functions, which are vital in fields like physics and engineering. [1.82] Numerical methods offer robust solutions to ordinary and partial differential equations. Techniques like Euler's method and the finite difference method provide approximations to differential equations that describe real-world phenomena, from fluid dynamics to population growth. In linear algebra, numerical methods are indispensable for solving large systems of linear equations and eigenvalue problems. Methods like Gaussian elimination and iterative techniques such as the Jacobi method and Gauss-Seidel method underpin simulations and modeling in engineering and physics. Numerical methods are at the core of machine learning algorithms, facilitating the optimization of model parameters through techniques like stochastic |