University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Application of a new method for nonlinear partial differential equations of fractional order arising in fluid mechanics 1 12 17835 10.22034/cmde.2024.60583.2594 EN Oleg Kazakov Bryansk State University of Engineering and Technology, Russia. Nurgali Uteuliyev M. Auezov South Kazakhstan University, Shymkent, Kazakhstan. Diana Denisova Russian State Social University, Moscow, Russia. Liya Shangaraeva Kazan Federal University, Kazan, Russia. Galina Vukovich Kuban State University, Krasnodar, Russia. Journal Article 2024 02 14 In this work, we established some exact solutions for the (2+1)-dimensional Zakharov-Kuznetsov, KdV, and K(2,2) equations which are considered based on the improved Exp-function method, by utilizing Maple software. We use the fractional derivatives with fractional complex transform. We obtained new periodic solitary wave solutions. The obtained solutions include three classes of soliton wave solutions in terms of hyperbolic function, trigonometric function, and rational function solutions. The obtained solutions and the exact solutions are shown graphically, highlighting the effects of non-linearity. Many other such types of nonlinear equations arising in fluid dynamics and nonlinear phenomena. https://cmde.tabrizu.ac.ir/article_17835_6af156c8300885a324e27e8594312b84.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Solving initial value problems using multilayer perceptron artificial neural networks 13 24 17842 10.22034/cmde.2024.58774.2486 EN Fatemeh Ahmadkhanpour Department of Mathematics, Faculty of Science, Tabriz Branch, Islamic Azad University, Tabriz, Iran. Hossein Kheiri Department of Applied Mathematics, Faculty of Mathematics, Statistics and Computer Science, University of Tabriz, Tabriz, Iran. Nima Azarmir Department of Mathematics, Faculty of Science, Tabriz Branch, Islamic Azad University, Tabriz, Iran. Farzin Modarres Khiyabani Department of Mathematics, Faculty of Science, Tabriz Branch, Islamic Azad University, Tabriz, Iran. Journal Article 2023 10 09 This research introduces a novel approach using artificial neural networks (ANNs) to tackle ordinary differential equations (ODEs) through an innovative technique called enhanced back-propagation (EBP). The ANNs adopted in this study, particularly multilayer perceptron neural networks (MLPNNs), are equipped with tunable parameters such as weights and biases. The utilization of MLPNNs with universal approximation capabilities proves to be advantageous for ODE problem solving. By leveraging the enhanced back-propagation algorithm, the network is fine-tuned to minimize errors during unsupervised learning sessions. To showcase the effectiveness of this method, a diverse set of initial value problems for ODEs are solved and the results are compared against analytical solutions and conventional techniques, demonstrating the superior performance of the proposed approach. https://cmde.tabrizu.ac.ir/article_17842_61fa42faf3c112abf54773ebc25c2e6a.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 A Green’s function-based computationally efficient approach for solving a kind of nonlocal BVPs 25 40 17831 10.22034/cmde.2024.58138.2452 EN Jyoti - Department of Mathematics, JUIT Solan, Waknaghat–173234, Himachal Pradesh, India. Mandeep Singh Department of Mathematics, JUIT Solan, Waknaghat–173234, Himachal Pradesh, India. Journal Article 2023 08 25 This study attempts to find approximate numerical solutions for a kind of second-order nonlinear differential problem subject to some Dirichlet and mixed-type nonlocal (specifically three-point) boundary conditions, appearing in various realistic physical phenomena, such as bridge design, control theory, thermal explosion, thermostat model, and the theory of elastic stability. The proposed approach offers an efficient and rapid solution for addressing the inherent complexity of nonlinear differential problems with nonlocal boundary conditions. Picard’s iterative technique and quasilinearization method are the basis for the proposed coupled iterative methodology. In order to convert nonlinear boundary value problems to linearized form, the quasilinearization approach (with convergence controller parameters) is implemented. Making use of Picard’s iteration method with the assistance of Green’s function, an equivalent integral representation for the linearized problems is derived. Discussion is also had over the proposed method’s convergence analysis. In order to determine its efficiency and effectiveness, the coupled iterative technique is tested on some numerical examples. Results are also compared with the existing techniques and documented (in terms of absolute errors) to validate the accuracy and precision of the proposed iterative technique. https://cmde.tabrizu.ac.ir/article_17831_df99345810e53c144deebe052ca10aa2.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 A method of lines for solving the nonlinear time- and space-fractional Schrödinger equation via stable Gaussian radial basis function interpolation 41 60 17837 10.22034/cmde.2024.54090.2265 EN Behnam Sepehrian Department of Mathematics, Faculty of Science, Arak University, Arak 38156-8-8349, Iran. Zahra Shamohammadi Department of Mathematics, Faculty of Science, Arak University, Arak 38156-8-8349, Iran. Journal Article 2022 11 10 The stable Gaussian radial basis function (RBF) interpolation is applied to solve the time and space-fractional Schrödinger equation (TSFSE) in one and two-dimensional cases. In this regard, the fractional derivatives of stable Gaussian radial basis function interpolants are obtained. By a method of lines, the computations of the TSFSE are converted to a coupled system of Caputo fractional ODEs. To solve the resulting system of ODEs, a high-order finite difference method is proposed, and the computations are reduced to a coupled system of nonlinear algebraic equations, in each time step. Numerical illustrations are performed to certify the ability and accuracy of the new method. Some comparisons are made with the results in other literature. https://cmde.tabrizu.ac.ir/article_17837_4112c325443b27cb357d50d8dc06385a.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Unveiling traveling waves and solitons of dirac integrable system via homogenous balance and singular manifolds methods 61 72 17861 10.22034/cmde.2024.59080.2509 EN Samah M. Mabrouk Department of Physics and Engineering Mathematics, Faculty of Engineering, Zagazig University, Egypt. Ahmed S. Rashed 1. Department of Physics and Engineering Mathematics, Faculty of Engineering, Zagazig University, Egypt. 2. Basic Science Department, Faculty of Engineering, Delta University for Science and Technology, Gamasa, 11152, Egypt. Rasha Saleh Department of Physics and Engineering Mathematics, Faculty of Engineering, Zagazig University, Egypt. Journal Article 2023 11 05 This study utilizes two robust methodologies to examine the precise solutions of the Dirac integrable system. The Homogeneous Balance Method (HB) is initially employed to generate an accurate solution. The system of equations for the quasi-solution is solved, where all the equations are of the same nature. The quasi-solution of the traveling wave results in the solitary wave solution of the system. The singular manifold method (SMM) is utilized following the Lie reduction of the Dirac system in order to search for the traveling wave solutions of the system. Both approaches demonstrate the existence of traveling wave solutions inside the system. The precise solutions of the Dirac system are shown in three-dimensional graphs. We have created solutions to the examined problem, including bright solutions, periodic soliton solutions, and complicated solutions. https://cmde.tabrizu.ac.ir/article_17861_be3f86bfbef4d1a7e9406e7540d0b4d1.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 q-Exponential fixed point theorem for mixed monotone operator with q-fractional problem 73 94 17850 10.22034/cmde.2024.58902.2496 EN Masoumeh Gholami Bahnamiri University of Mazandaran, Babolsar, Iran. Abdolali Namaty University of Mazandaran, Babolsar, Iran. Journal Article 2023 10 20 In this work, we examine the existence and uniqueness(EU) of q-Exponential positive solution (q-EPS) of the hybrid q-fractional boundary value problem (q-FBVP).<br />We prove the q-Exponential fixed point theorem (q-EFPT) with a new set $\rho_{h,e_{1}}$ in the Banach space E to check the EU of q-EPS of the q-FBVP. In the long run, an exemplum is given to show the correctness of our results.  https://cmde.tabrizu.ac.ir/article_17850_a2e9fbd5429602806314b85647ed0816.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 On an efficient method for the fractional nonlinear Newell-Whithead-Segel equations 95 106 17833 10.22034/cmde.2024.58461.2472 EN Emre Aydin Department of Mathematics, University of Ondokuz Mayis, Samsun, Turkey. Inci Cilingir Sungu Department of Mathematics, University of Ondokuz Mayis, Samsun, Turkey. Journal Article 2023 09 16 In this study, the time-fractional Newell-Whitehead-Segel (NWS) equation and its different nonlinearity cases are investigated. Schemes obtained by the Newtonian linearization method are used to numerically solve different cases of the time-fractional Newell-Whitehead-Segel (NWS) equation. Stability and convergence conditions of the Newtonian linearization method have been determined for the related equation. The numerical results obtained as a result of the appropriate stability criteria are compared with the help of tables and graphs with exact solutions for different fractional values.  https://cmde.tabrizu.ac.ir/article_17833_a69d81293f13f4a6d5eb4b3b148abb5d.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 An efficient high-order compact finite difference scheme for Lane-Emden-type equations 107 122 17844 10.22034/cmde.2023.56275.2351 EN Reza Doostaki Department of Applied Mathematics, Faculty of Mathematics and Computer, Shahid Bahonar University of Kerman, Kerman, Iran. Mohammad Mehdi Hosseini Department of Applied Mathematics, Faculty of Mathematics and Computer, Shahid Bahonar University of Kerman, Kerman, Iran. Abbas Salemi Department of Applied Mathematics, Faculty of Mathematics and Computer, Shahid Bahonar University of Kerman, Kerman, Iran. Journal Article 2023 04 21 In this paper, an efficient high-order compact finite difference (HOCFD) scheme is introduced for solving generalized Lane-Emden equations. For nonlinear types, it is shown that a combined quasilinearization and HOCFD scheme gives excellent results, while a few quasilinear iterations are needed. Then the proposed method is developed for solving the system of linear and nonlinear Lane-Emden equations. Some numerical examples are provided, and the obtained results of the proposed method are then compared with previous well-established methods. The numerical experiments show the accuracy and efficiency of the proposed method. https://cmde.tabrizu.ac.ir/article_17844_0acb38ca5be8fdd7bfff9ef5a8232ee8.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Analysis of the effect of isolation on the transmission dynamics of COVID-19: a mathematical modelling approach (R1) 123 141 17830 10.22034/cmde.2024.58127.2451 EN Abayomi Ayotunde Ayoade Department of Mathematics, University of Lagos, Lagos, Lagos State, Nigeria. Oluwatayo Micheal Ogunmiloro Department of Mathematics, Ekiti State University, Ado-Ekiti, Ekiti State, Nigeria. 0000-0002-0800-3690 Taiye Oyedepo Department of Applied Sciences, Federal College of Dental Technology and Therapy, Enugu, Enugu State, Nigeria. Journal Article 2023 08 24 COVID-19 was declared a pandemic on March 11, 2020, after the global cases and mortalities in more than 100 countries surpassed 100 000 and 3 000, respectively. Because of the role of isolation in disease spread and transmission, a system of differential equations were developed to analyse the effect of isolation on the dynamics of COVID-19. The validity of the model was confirmed by establishing the positivity and boundedness of its solutions. Equilibria analysis was conducted, and both zero and nonzero equilibria were obtained. The effective and basic reproductive ratios were also derived and used to analyze the stability of the equilibria. The disease-free equilibrium is stable both locally and globally if the reproduction number is less than one; otherwise, it is the disease-endemic equilibrium that is stable locally and globally. A numerical simulation was carried out to justify the theoretical results and to visualise the effects of various parameters on the dynamics of the disease. Results from the simulations indicated that COVID-19 incidence and prevalence depended majorly on the effective contact rate and per capita probability of detecting infection at the asymptomatic stage, respectively. The policy implication of the result is that disease surveillance and adequate testing are important to combat pandemics. https://cmde.tabrizu.ac.ir/article_17830_b62cf23a95e51b6ac13b21cadc646ff0.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Comparison of feature-based algorithms for large-scale satellite image matching 142 156 17841 10.22034/cmde.2024.58672.2483 EN Fatemeh Naserizadeh Faculty of Electrical and Computer Engineering, Malek Ashtar University of Technology, Tehran, Iran. Ali Jafari Faculty of Electrical and Computer Engineering, Malek Ashtar University of Technology, Tehran, Iran. Journal Article 2023 10 01 Using different algorithms to extract, describe, and match features requires knowing their capabilities and weaknesses in various applications. Therefore, it is a basic need to evaluate algorithms and understand their performance and characteristics in various applications. In this article, classical local feature extraction and description algorithms for large-scale satellite image matching are discussed. Eight algorithms, SIFT, SURF, MINEIGEN, MSER, HARRIS, FAST, BRISK, and KAZE, have been implemented, and the results of their evaluation and comparison have been presented on two types of satellite images. In previous studies, comparisons have been made between local feature algorithms for satellite image matching. However, the difference between the comparison of algorithms in this article and the previous comparisons is in the type of images used, which both reference and query images are large-scale, and the query image covers a small part of the reference image. The experiments were conducted in three criteria: time, repeatability, and accuracy. The results showed that the fastest algorithm was Surf, and in terms of repeatability and accuracy, Surf and Kaze got the first rank, respectively. https://cmde.tabrizu.ac.ir/article_17841_9200c0becda613a7a7ef2e5b0a140426.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Finite-difference method for Hygrothermoelastic boundary value problem 157 168 17865 10.22034/cmde.2024.58002.2442 EN Praveen Ailawalia Department of Mathematics, University institute of Sciences, Chandigarh University, , Mohali, Punjab, India. Vikas Sharma 1. I K Gujral Punjab Technical University, Kapurthala, Punjab, India. 2. Chandigarh Group of Institutions, Department of Applied Sciences, Landran, Mohali,Punjab , India. Joginder Singh Chandigarh Group of Institutions, Department of Applied Sciences, Landran, Mohali,Punjab , India. Journal Article 2023 08 15 A two-dimensional coupled hygrothermoelastic medium boundary problem using Finite difference method is discussed in the present work. Explicit and Implicit finite difference schemes for this problem are formed. The solutions of these schemes are carried out using numerical methods of finite difference. These solutions are compared of and analyzed and exciting similarities were found as result. https://cmde.tabrizu.ac.ir/article_17865_98af9e1bf424bb2aa42d506537b7f5a1.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Convergence analysis for piecewise Lagrange interpolation method of fractal fractional model of tumor-immune interaction with two different kernels 169 182 17926 10.22034/cmde.2024.58991.2501 EN Saede Shafipour Faculty of Sciences, Yasouj University, Yasouj, Iran. Roghayeh Katani Faculty of Sciences, Yasouj University, Yasouj, Iran. Journal Article 2023 10 26 Ahmad et al. (see [1]) presented a piecewise Lagrange interpolation method for solving tumor-immune interaction models with fractal fractional operators using a power law and exponential kernel. We suggest a convergence analysis for this method and we obtain the order of convergence. Of course, there are some mistakes in this numerical method that were corrected. Furthermore, Numerical illustrations are demonstrated to show the effectiveness of the corrected numerical method. https://cmde.tabrizu.ac.ir/article_17926_a6c9c28dab935039e1852198a1a1eecf.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 On unique solutions of integral equations by progressive contractions 183 189 17869 10.22034/cmde.2024.59214.2516 EN John R. Graef Department of Mathematics, University of Tennessee at Chattanooga, Chattanooga, TN 37403, USA. Osman Tunc Department of Computer Programming, Baskale Vocational School, Van Yuzuncu Yil University, 65080, Campus, Van, Turkey. Cemil Tunc Department of Mathematics, Faculty of Sciences, Van Yuzuncu Yil University, 65080, Van, Turkey. 0000-0003-2909-8753 Journal Article 2023 11 13  The authors consider Hammerstein-type integral equations for the purpose of obtaining new results on the uniqueness of solutions on an infinite interval. The approach used in the proofs is based on the technique called progressive contractions due to T. A. Burton. Here the authors apply the Burton’s method to a general Hammerstein type integral equation that also yields the existence of solutions. In most of the existing literature, investigators prove uniqueness of solutions of integral equations by applying some type of fixed point theorem which can be tedious and challenging, often patching together solutions on short intervals after making complicated translations. In this article, using the progressive contractions throughout three simple short steps, each of the three steps is an elementary contraction mapping on a short interval, we improve the technique due to T. A. Burton for a general Hammerstein type integral equation and obtain the uniqueness of solutions on an infinite interval. These are advantages of the used method to prove the uniqueness of solutions. https://cmde.tabrizu.ac.ir/article_17869_75718a962420b122884cb876c42aa04e.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Kernel density estimation applications in vessel extraction for MRA images 190 200 18296 10.22034/cmde.2024.60922.2605 EN Tohid Bahrami Department of Statistics, Faculty of Mathematics, Statistics and Computer Science, University of Tabriz, Iran. Hossein Jabbari Khamnei Department of Statistics, Faculty of Mathematics, Statistics and Computer Science, University of Tabriz, Iran. Golam Kibria Department of Mathematics and Statistics, Florida International University, FIU, Miami, USA. Journal Article 2024 03 16 Vascular-related diseases have become increasingly significant as public health concerns. The analysis of blood vessels plays an important role in detecting and treating diseases. Extraction of vessels is a very important technique in vascular analysis. Magnetic Resonance Angiography (MRA) is a medical imaging technique used to visualize the blood vessels and vascular system in three-dimensional images. These images provide detailed information about the size and shape of the vessels, any narrowing or stenosis, as well as blood supply and circulation in the body. Tracing vessels from medical images is an essential step in the diagnosis and treatment of vascular-related diseases. Many different techniques and algorithms have been proposed for vessel extraction. In this paper, we present a vessel extraction method based on the Kernel density estimation (KDE). Numerical experiments on real 2D MRA images demonstrate that the presented method is very efficient. The effectiveness of the proposed method has been proven through comparative analysis with validated existing methods. https://cmde.tabrizu.ac.ir/article_18296_009f002a3e1a36a38744e1ee09c8edfa.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 The use of technological intelligence model in solving terrorism dynamics: a case study of Nigeria 201 213 17843 10.22034/cmde.2024.58503.2474 EN Adamu Gambo Department of Mathematics, Nigerian Army University Biu, Nigeria. Ahmed Kawu Dotia Department of Mathematics Nigerian Army University Biu, Nigeria. Mohammed Olanrewaju Ibrahim Department of Mathematics University of Ilorin, Nigeria. Lawani Abisola Olusola Department of Mathematics Tai Solarin University of Education Ijebu- Ode, Nigeria. Journal Article 2023 09 18 Nigeria is one of the most populated countries in West Africa and is in seventh position globally. The issue of terrorism has become a common problem in Nigeria, and the government has been applying local strategies to address the situation but has yet to produce good results. The challenges necessitate the effort in this paper to develop a new deterministic model to curb terrorism and insurgency through technology intelligence in Nigeria. This analysis indicates that Unmanned Aerial Vehicles (UAV) and the transmission rate per capita are the most sensitive parameters. Also pictured from the graphs in Figures 2, 3, and 4 were drones used to reduce the number of informants of both the terrorist and kidnapper individuals in Nigeria. Finally, this paper recommended the model adopted for controlling terrorism in Nigeria. https://cmde.tabrizu.ac.ir/article_17843_0a3d986d26f5a43431c3d859a31b8301.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Designing an efficient algorithm for fractional partial integro-differential viscoelastic equations with weakly singular kernel 214 232 17816 10.22034/cmde.2024.57935.2436 EN Haniye Dehestani Department of Mathematics, Faculty of Mathematical Sciences, Alzahra University, Tehran, Iran. Yadollah Ordokhani Department of Mathematics, Faculty of Mathematical Sciences, Alzahra University, Tehran, Iran. Journal Article 2023 08 10 In this paper, the discretization method is developed by means of Mott-fractional Mott functions (MFM-Fs) for solving fractional partial integro-differential viscoelastic equations with weakly singular kernels. By taking into account the Riemann-Liouville fractional integral operator and operational matrix of integration, we convert the proposed problem to fractional partial integral equations with weakly singular kernels. It is necessary to mention that the operational matrices of integration are obtained with new numerical algorithms. These changes effectively affect the solution process and increase the accuracy of the proposed method. Besides, we investigate the error analysis of the approach. Finally, several examples are solved by applying the discretization method by combining MFM-Fs and the gained results are compared with the methods available in the literature. https://cmde.tabrizu.ac.ir/article_17816_236a1d3692bc1d1d87e00d2502eacfaa.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Soliton solutions to the DS and generalized DS system via an analytical method 233 248 17834 10.22034/cmde.2024.60337.2576 EN Ilyos Sultanovich Abdullayev Department of Management and Marketing, Faculty of Social and Economic Sciences, Urgench State University, Urgench, 220100, Uzbekistan. Elvir Munirovich Akhmetshin Department of Economics and Management, Faculty of Economic and Legal Sciences Kazan Federal University, Elabuga Institute of KFU, 423604, Elabuga, Russian Federation, Republic of Tatarstan. Evgeny Efimovich Krasnovskiy Department of Applied Mathematics, Bauman Moscow State Technical University, Russian Federation. Nalbiy Salikhovich Tuguz Department of Higher Mathematics, Kuban State Agrarian University named after I.T. Trubilin, Krasnodar region, 350044, Russian Federation. Galina Mashentseva Department of Economics and Humanities, Faculty of Higher Education Kamyshin Technological Institute (branch of) Volgograd State Technical University, Russian Federation. Journal Article 2024 01 30 In this article, the exact solutions for nonlinear Drinfeld-Sokolov (DS) and generalized Drinfeld-Sokolov (gDS) equations are established. The rational Exp-function method (EFM) is used to construct solitary and soliton solutions of nonlinear evolution equations. This method is developed for searching exact traveling wave solutions of nonlinear partial differential equations. Also, exact solutions with solitons and periodic structures are obtained. The obtained results are not only presented numerically but are also accompanied by insightful physical interpretations, enhancing the understanding of the complex dynamics described by these mathematical models. The utilization of the rational EFM and the broad spectrum of obtained solutions contribute to the depth and significance of this research in the field of nonlinear wave equations. https://cmde.tabrizu.ac.ir/article_17834_5a01fcc5e21ce1ba7ca27896fac84ad4.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Symmetries of the minimal lagrangian hypersurfaces on cylindrically symmetric static space-times 249 257 17851 10.22034/cmde.2024.60285.2572 EN Akram Mohammadpouri Faculty of Mathematics, Statistics and Computer Sciences, University of Tabriz, Tabriz, Iran. Mir Sajjad Hashemi Department of Mathematics, University of Bonab, Bonab, Iran. Sona Samaei Faculty of Mathematics, Statistics and Computer Sciences, University of Tabriz, Tabriz, Iran. Sarkar Salar Anvar Faculty of Mathematics, Statistics and Computer Sciences, University of Tabriz, Tabriz, Iran. Journal Article 2024 01 27 In this work, we study a hypersurface immersed in specific types of cylindrically symmetric static space-times, then we identify the gauge fields of the Lagrangian that minimizes the area beside the Noether symmetries. We show that these symmetries are part of the Killing algebra of cylindrically symmetric static space-times. By using Noether’s theorem, we construct the conserved vector fields for the minimal hypersurface. https://cmde.tabrizu.ac.ir/article_17851_7f6f3fa3f4ebcf47b883c37c13adf6c3.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 On analytical solutions of the ZK equation and related equations by using the generalized ( G′/G )-expansion method 258 270 18510 10.22034/cmde.2024.61348.2635 EN Irina Telezhko Peoples' Friendship University of Russia (RUDN University), Moscow, Russia. Alexey Dengaev Gubkin Russian State University of Oil and Gas, Moscow, Russia. Alfiia Iarkhamova Kazan Federal University, Kazan, Russia. Elena Revyakina Don State Technical University, Rostov-on-Don, Russia. Nadezhda Kolcova Kuban State University, Krasnodar, Russia. Journal Article 2024 04 24 The generalized ( G′/G )-expansion method with the aid of Maple is proposed to seek exact solutions of nonlinear evolution equations. For finding exact solutions are expressed three types of solutions that include hyperbolic function solution, trigonometric function solution, and rational solution. The article studies the Zakharov–Kuznetsov (ZK) equation, the generalized ZK (gZK) equation, and the generalized forms of these equations. Exact solutions with traveling wave solutions of nonlinear evolution equations are obtained. It is shown that the proposed method is direct, effective and can be used for many other nonlinear evolution equations. https://cmde.tabrizu.ac.ir/article_18510_77689d28c5fa1c1c5d0d531da6e82bb2.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Extended hyperbolic function method for the model having cubic-quintic-septimal nonlinearity in weak nonlocal media 271 281 17774 10.22034/cmde.2024.57337.2396 EN Hamood Ur Rehman Department of Mathematics, University of Okara, Okara, Pakistan. Ifrah Iqbal Department of Mathematics, University of Okara, Okara, Pakistan. Mostafa Eslami Department of Applied Mathematics, Faculty of Mathematical Sciences, University of Mazandaran, Babolsar, Iran. Mohammad Mirzazadeh Department of Engineering Sciences, Faculty of Technology and Engineering, East of Guilan, University of Guilan, Rudsar-Vajargah, Iran. Sajjad A. Jedi Abduridha Department of Mathematics, Faculty of Basic Education, University of Kufa, Najaf, Iraq. Mir Sajjad Hashemi Department of Mathematics, Basic Science Faculty, University of Bonab, Bonab, Iran. Journal Article 2023 07 01 Optical solitons are self-trapped light beams that maintain their shape and transverse dimension during propagation. This paper investigates the propagation of solitons in an optical material with a weak nonlocal media, modeled by a cubic-quintic-septimal nonlinearity. The dynamics of solitons in optical waveguides are described by the cubic nonlinear Schrödinger equation and its extensions. This equation model applies to both the spatial propagation of beams and the temporal propagation of pulses in a medium exhibiting cubic nonlinearity. The novelty of the paper lies in the application of the extended hyperbolic function method to derive soliton solutions in optical materials with weak nonlocal media in the form of the periodic, bright, kink, and singular type solitons. The obtained solutions provide explicit expressions for the behavior of optical waves in media. These results shed light on the dynamics of nonlinear waves in optical materials and contribute to a better understanding of soliton propagation. The findings contribute to a more comprehensive understanding of the role of nonlocal nonlinearity and time constants in soliton solutions. Our findings provide a better understanding of the dynamics of the nonlinear waves in optical media and have many application for the field of optical communication and signal processing. The role of nonlocal nonlinearity and time constant on soliton solutions is also discussed with the help of graphs. https://cmde.tabrizu.ac.ir/article_17774_1d187f9cec7badf966d0dd6736a8f92c.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Solving a class of Volterra integral equations with M-derivative 282 293 17862 10.22034/cmde.2024.58936.2498 EN Mousa Ilie Department of Mathematics, Rasht Branch, Islamic Azad University, Rasht, Iran. Ali Khoshkenar Department of Mathematics, Rasht Branch, Islamic Azad University, Rasht, Iran. Asadollah Torabi Giklou Department of Basic Sciences, Parsabad Moghan Branch, Islamic Azad University, Parsabad Moghan, Iran. Journal Article 2023 10 22 In this current article, the well-known Neumann method for solving the time M-fractional Volterra integral equations of the second kind is developed. In the several theorems, existence and uniqueness of the solution and convergence of the proposed approach are also studied. The Neumann method for this class of the time M-fractional Volterra integral equations has been called the M-fractional Neumann method (MFNM). The results obtained demonstrate the efficiency of the proposed method for the time M-fractional Volterra integral equations. Several illustrative numerical examples have presented the ability and adequacy of the MFNM for a class of fractional integral equations. https://cmde.tabrizu.ac.ir/article_17862_aad451342ae0219f12bba7f57c49c045.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Hopf bifurcation and Turing instability in a cross-diffusion prey-predator system with group defense behavior 294 306 17870 10.22034/cmde.2024.59327.2522 EN Yaghoub Jalilian Department of Mathematics, Razi University, Kermanshah, Iran. Marzieh Farshid Department of Mathematics, Razi University, Kermanshah, Iran. Journal Article 2023 11 23 This paper is concerned with a cross-diffusion prey-predator system in which the prey species is equipped with the group defense ability under the Neumann boundary conditions. The tendency of the predator to pursue the prey is expressed in the cross-diffusion coefficient, which can be positive, zero, or negative. We first select the environmental protection of the prey population as a bifurcation parameter. Next, we discuss the Turing instability and the Hopf bifurcation analysis on the proposed cross-diffusion system. We show that the system without cross-diffusion is stable at the constant positive stationary solution but it becomes unstable when the cross-diffusion appears in the system. Furthermore, the stability of bifurcating periodic solutions and the direction of Hopf bifurcation are examined.  https://cmde.tabrizu.ac.ir/article_17870_551de847f6fb7509a9e6200b96643b6f.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 A unified Explicit form for difference formulas for fractional and classical derivatives and applications 307 326 17827 10.22034/cmde.2023.58229.2459 EN Wickramaarachchilage Anura Gunarathna Department of Physical Sciences, College of Applied Sciences, Rajarata University, Sri Lanka. Haniffa Mohamed Nasir FracDiff Research Group, Department of Mathematics, P. O. Box: 36, Sultan Qaboos University, Al-Khoud 123, Muscat, Sultanate of Oman. Wasantha Bandara Daundasekera Department of Mathematics, University of Peradeniya, Peradeniya, Sri Lanka. Journal Article 2023 09 01 A unified explicit form for difference formulas to approximate fractional and classical derivatives is presented. The formula gives finite difference approximations for any classical derivative with a desired order of accuracy at any nodal point in computational domain. It also gives Gr¨unwald type approximations for fractional derivatives with arbitrary order of approximation at any nodal point. Thus, this explicit form unifies approximations of both types of derivatives. Moreover, for classical derivatives, it also provides various finite difference formulas such as forward, backward, central, staggered, compact, non-compact, etc. Efficient computations of the coefficients of the difference formulas are also presented leading to automating the solution process of differential equations with a given higher order accuracy. Some basic applications are presented to demonstrate the usefulness of this unified formulation. https://cmde.tabrizu.ac.ir/article_17827_33b7e96a367c8b5904eae8e2bcae11c8.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 A Hierarchical method to solve one machine multicriteria sequencing problem 327 338 18294 10.22034/cmde.2024.61553.2667 EN Adawiya A. Mahmood Al-Nuaimi Department of Mathematics, College of Science, University of Diyala, Iraq. Journal Article 2024 05 07 The problem of minimizing a function of three criteria maximum‎ ‎earliness‎, ‎total of square completion times‎, ‎and total lateness in a ‎hierarchical (lexicographical) method is proposed in this article‎. On one machine‎, ‎n independent tasks (jobs) must planned‎. ‎It is‎ ‎always available starting at time zero and can only do the mono task‎ (job) at a time period‎. ‎Processing for the task (job) $j (j=1,2,...,nj)$‎ ‎is necessary meantime the allotted positive implementation time‎ ‎$p_{tj}$‎. ‎For the problem of three criteria maximization earliness‎, a total of square completion times‎, ‎and total lateness in a hierarchy‎ ‎instance‎, ‎the access of limitation that which is the desired sequence‎ is held out‎. ‎The Generalized Least Deviation Method (GLDM) and a robust‎ ‎technique for analyzing historical data to project future trends are‎ analyzed‎. https://cmde.tabrizu.ac.ir/article_18294_f2c99886e4ead7e445f40c6f46bce31f.pdf

University of Tabriz Computational Methods for Differential Equations 2345-3982 13 1 2024 11 01 Alternating direction implicit method for approximation solution of the HCIR model, including transaction costs in a Jump-Diffusion model 339 356 17845 10.22034/cmde.2024.58794.2490 EN Elham Mashayekhi Faculty of Mathematics, Statistics and Computer Science, Semnan University, Semnan, Iran. Javad Damirchi Faculty of Mathematics, Statistics and Computer Science, Semnan University, Semnan, Iran. Ahmad Reza Yazdanian Faculty of Financial Sciences, Kharazmi University, Tehran, Iran. Journal Article 2023 10 14 The standard model, which determines option pricing, is the well-known Black-Scholes formula. Heston in addition to Cox-Ingersoll-Ross which is called CIR, respectively, implemented the models of stochastic volatility and interest rate to the standard option pricing model. The cost of transaction, which the Black-Scholes method overlooked, is another crucial consideration that must be made when trading a service or production. It is acknowledged that by employing the log-normal stock diffusion hypothesis with constant volatility, the Black-Scholes model for option pricing departs from reality. The standard log-normal stock price distribution used in the Black-Scholes model is insufficient to account for the leaps that regularly emerge in the discontinuous swings of stock prices. A jump-diffusion model, which combines a jump process and a diffusion process is a type of mixed model in the Black-Scholes model belief. Merton developed a jump model as a modification of jump models to better describe purchasing and selling behavior. In this study, the Heston-Cox-Ingersoll-Ross (HCIR) model with transaction costs is solved using the alternating direction implicit (ADI) approach and the Monte Carlo simulation assuming the underlying asset adheres to the jump-diffusion case, then the outcomes are compared to the analytical solution. In addition, the consistency of the numerical method is proven for the model. https://cmde.tabrizu.ac.ir/article_17845_195cdfca238f8ef226d67323a793da82.pdf