Your search keyword '"Sarı, Murat' showing total 6 results

1. A stability preserved time-integration method for nonlinear advection-diffusion models

Author

Tunc, Huseyin and Sari, Murat

Subjects

Mathematics - Numerical Analysis, 65L05, 65L06, 34K28

Abstract

A new implicit-explicit local differential transform method (IELDTM) is derived here for time integration of the nonlinear advection-diffusion processes represented by (2+1)-dimensional Burgers equation. The IELDTM is adaptively constructed as stability preserved and high order time integrator for spatially discretized Burgers equation. For spatial discretization of the model equation, the Chebyshev spectral collocation method (ChCM) is utilized. A robust stability analysis and global error analysis of the IELDTM are presented with respect to the direction parameter \theta. With the help of the global error analysis, adaptivity equations are derived to minimize the computational costs of the algorithms. The produced method is shown to eliminate the accuracy disadvantage of the classical \theta-method and the stability disadvantages of the existing DTM-based methods. Two examples of the Burgers equation in one and two dimensions have been solved via the ChCM-IELDTM hybridization, and the produced results are compared with the literature. The present time integrator has been proven to produce more accurate numerical results than the MATLAB solvers, ode45 and ode15s., Comment: 17 pages, 4 figures and 2 tables

Published

2021

2. A spatial local method for solving 2D and 3D advection-diffusion equations

Author

Tunc, Huseyin and Sari, Murat

Subjects

Mathematics - Numerical Analysis, 65N35, 65N12

Abstract

In this study, an implicit-explicit local differential transform method (IELDTM) based on Taylor series representations is produced for solving 2D and 3D advection-diffusion equations. The parabolic advection-diffusion equations are reduced to the nonhomogeneous elliptic system of partial differential equations with the utilization of the Chebyshev spectral collocation approach in temporal variable. The IELDTM is constructed over 2D and 3D meshes using continuity equations of the neighbour representations with either explicit or implicit forms in related directions. The IELDTM is proven to have excellent convergence properties by experimentally illustrating both h-refinement and p-refinement outcomes. A distinctive feature of the IELDTM over existing numerical techniques is the optimization of the local spatial degrees of freedom. It has been proven that IELDTM provides more accurate results with far less degrees of freedom than the finite difference, finite element and spectral methods.

Published

2021

3. A New Implicit-Explicit Local Method to Capture Stiff Behavior with COVID-19 Outbreak Application

Author

Tunc, Huseyin and Sari, Murat

Subjects

Mathematics - Numerical Analysis, 65L04, 65L05, 65L06, 65L20

Abstract

In this paper, a new implicit-explicit local method with an arbitrary order is produced for stiff initial value problems. Here, a general method for one-step time integrations has been created, considering a direction free approach for integrations leading to a numerical method with parameter-based stability preservation. Adaptive procedures depending on the problem types for the current method are explained with the help of local error estimates to minimize the computational cost. Priority error analysis of the current method is made, and order conditions are presented in terms of direction parameters. Stability analysis of the method is performed for both scalar equations and systems of differential equations. The currently produced parameter-based method has been proven to provide A-stability, for 0.5<\theta<1, in various orders. The present method has been shown to be a very good option for addressing a wide range of initial value problems through numerical experiments. It can be seen as a significant contribution that the Susceptible-Exposed-Infected-Recovered equation system parameterized for the COVID-19 pandemic has been integrated with the present method and stability properties of the method have been tested on this stiff model and significant results are produced. Some challenging stiff behaviours represented by the nonlinear Duffing equation, Robertson chemical system, and van der Pol equation have also been integrated, and the results revealed that the current algorithm produces much more reliable results than numerical techniques in the literature.

Published

2021

4. Constrained Paracomplex Mechanical Systems

Author

Tekkoyun, Mehmet and Sari, Murat

Subjects

Mathematics - Dynamical Systems, Mathematical Physics, 53C15, 70H03, 70H05

Abstract

In this study, it is introduced paracomplex analogue of Lagrangians and Hamiltonians with constraints in the framework of para-Kaehlerian manifolds. The geometrical and mechanical results on the constrained mechanical system have also been discussed.

Published

2009

5. Bi-Para-Mechanical Systems on Lagrangian Distributions

Author

Tekkoyun, Mehmet and Sari, Murat

Subjects

Mathematical Physics, PACS: 02.04, 03.40.

Abstract

In this work, bi-para-complex analogue of Lagrangian and Hamiltonian systems was introduced on Lagrangian distributions. Yet, the geometric and physical results related to bi-para-dynamical systems were also presented., Comment: 12 pages

Published

2009

6. Symmetric Teleparallel Gravity: Some exact solutions and spinor couplings

Author

Adak, Muzaffer, Sert, Özcan, Kalay, Mestan, and Sarı, Murat

Subjects

General Relativity and Quantum Cosmology

Abstract

In this paper we elaborate on the symmetric teleparallel gravity (STPG) written in a non-Riemannian spacetime with nonzero nonmetricity, but zero torsion and zero curvature. Firstly we give a prescription for obtaining the nonmetricity from the metric in a peculiar gauge. Then we state that under a novel prescription of parallel transportation of a tangent vector in this non-Riemannian geometry the autoparallel curves coincides with those of the Riemannian spacetimes. Subsequently we represent the symmetric teleparallel theory of gravity by the most general quadratic and parity conserving lagrangian with lagrange multipliers for vanishing torsion and curvature. We show that our lagrangian is equivalent to the Einstein-Hilbert lagrangian for certain values of coupling coefficients. Thus we arrive at calculating the field equations via independent variations. Then we obtain in turn conformal, spherically symmetric static, cosmological and pp-wave solutions exactly. Finally we discuss a minimal coupling of a spin-1/2 field to STPG., Comment: Accepted for publication in the International Journal of Modern Physics A

Published

2008