Search

Your search keyword '"Salehi, Rezvan"' showing total 37 results
Start Over Author "Salehi, Rezvan" Publication Year Range Last 50 years
37 results on '"Salehi, Rezvan"'

1. Designing of knowledge-based potentials via B-spline basis functions for native proteins detection

Author

Mirzabeigi, Elmira, Mortezazadeh, Saeed, Salehi, Rezvan, and Naderi-Manesh, Hossein

Subjects
Mathematics - Optimization and Control, Quantitative Biology - Quantitative Methods
Abstract

Knowledge-based potentials were developed to investigate the differentiation of native structures from their decoy sets. This work presents the construction of two different distance-dependent potential energy functions based on two fundamental assumptions using mathematical modeling. Here, a model was developed using basic mathematical methods, and the carbon-alpha form is the simplest form of protein representation. We aimed to reduce computational volume and distinguish the native structure from the decoy structures. For this purpose, according to Anfinsens dogma, we assumed that the energy of each model structure should be more favorable than the corresponding native type. In the second one, we thought that the energy difference between the native and decoy structures changes linearly with the root-mean-square deviation of structures. These knowledge-based potentials are expressed by the B-spline basis functions of the pairwise distances between Ca-Ca of inter-residues. The potential function parameters in the above two approaches were optimized using the linear programming algorithm on a massive collection of Titan-HRD and tested on the remainder. We found that the potential functions produced by Anfinsens dogma detect native structures more accurately than those developed by the root-mean-square deviation. Both linear programming knowledge-based potentials (LPKP) successfully detect the native structures from an ensemble of decoys. However, the LPKP of the first approach can correctly identify 130 native structures out of 150 tested cases with an average rank of 1.67. While the second approach LPKP detects 124 native structures from their decoys. We concluded that linear programming is promising for generating knowledge-based potential functions. All the training and testing sets used for this work are available online and downloaded from http://titan.princeton.edu/HRDecoys.

Published
2023

21. The approximate solution of one dimensional stochastic evolution equations by meshless methods.

Author

Jalili, Mahdi and Salehi, Rezvan

Subjects
MESHFREE methods, ITERATIVE methods (Mathematics), RADIAL basis functions, STANDARD deviations, STOCHASTIC analysis, HILBERT space, PARTIAL differential equations
Abstract

In this article, we develop an iterative scheme based on the meshless methods to simulate the solution of one dimensional stochastic evolution equations using radial basis function (RBF) interpolation under the concept of Gaussian random field simulation. We use regularized Kansa collocation to approximate the mean solution at space and the time component is discretized by the global o-weighted method. Karhunen-loève expansion is employed for simulating the Gaussian random field. Statistical tools for numerical analysis are standard deviation, absolute error, and root mean square. In this work, we solve two major problems for showing the convergence, and stability of the presented method on two problems. The first problem is the semilinear stochastic evolution problem, and the second one is stochastic advection-diffusion model with different control values. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

22. Numerical and theoretical study of weak Galerkin finite element solutions of Turing patterns in reaction–diffusion systems.

Author

Khaled‐Abad, Leila Jafarian and Salehi, Rezvan

Subjects
*PARTIAL differential equations, *FINITE element method, *DIFFERENTIAL operators, *EULER method, *NUMERICAL analysis
Abstract

In this paper, we introduce numerical schemes and their analysis based on weak Galerkin finite element framework for solving 2‐D reaction–diffusion systems. Weak Galerkin finite element method (WGFEM) for partial differential equations relies on the concept of weak functions and weak gradients, in which differential operators are approximated by weak forms through the Green's theorem. This method allows the use of totally discontinuous functions in the approximation space. In the current work, the WGFEM solves reaction–diffusion systems to find unknown concentrations (u, v) in element interiors and boundaries in the weak Galerkin finite element space WG(P0, P0, RT0). The WGFEM is used to approximate the spatial variables and the time discretization is made by the backward Euler method. For reaction–diffusion systems, stability analysis and error bounds for semi‐discrete and fully discrete schemes are proved. Accuracy and efficiency of the proposed method successfully tested on several numerical examples and obtained results satisfy the well‐known result that for small values of diffusion coefficient, the steady state solution converges to equilibrium point. Acquired numerical results asserted the efficiency of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

25. Two Implicit Meshless Finite Point Schemes for the Two-Dimensional Distributed-Order Fractional Equation.

Author

Salehi, Rezvan

Subjects
COLLOCATION methods, EQUATIONS, LEAST squares, CAPUTO fractional derivatives, MESHFREE methods
Abstract

In this paper, the distributed-order time fractional sub-diffusion equation on the bounded domains is studied by using the finite-point-type meshless method. The finite point method is a point collocation based method which is truly meshless and computationally efficient. To construct the shape functions of the finite point method, the moving least square reproducing kernel approximation is employed. Two implicit discretisation of order O ⁢ (τ) {O(\tau)} and O ⁢ (τ 1 + 1 2 ⁢ σ ) {O(\tau^{1+\frac{1}{2}\sigma})} are derived, respectively. Stability and L 2 {L^{2}} norm convergence of the obtained difference schemes are proved. Numerical examples are provided to confirm the theoretical results. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

26. Weak Galerkin finite element method for an inhomogeneous Brusselator model with cross-diffusion.

Author

Khaled-Abad, Leila Jafarian and Salehi, Rezvan

Subjects
GALERKIN methods, FINITE element method, CONJUGATE gradient methods, DIFFUSION, SPACE
Abstract

A new weak Galerkin finite element method is applied for time dependent Brusselator reaction-diffusion systems by using discrete weak gradient operators over discontinuous weak functions. In this work, we consider the lowest order weak Galerkin finite element space (P0, P0, RT0). Discrete weak gradients are defined in Raviart-Thomas space. Thus we employ this approximate space on triangular mesh for solving unknown concentrations (u, v) in Brusselator reaction-diffusion systems. Based on a weak varitional form, semi-discrete and fully-discrete weak Galerkin finite element scheme are obtained. In addition, the paper presents some numerical results to illustrate the power of proposed method. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

36. A moving least square reproducing polynomial meshless method.

Author

Salehi, Rezvan and Dehghan, Mehdi

Subjects
*LEAST squares, *POLYNOMIALS, *MESHFREE methods, *BOUNDARY value problems, *PROBLEM solving, *GENERALIZATION
Abstract

Abstract: Interest in meshless methods has grown rapidly in recent years in solving boundary value problems (BVPs) arising in science and engineering. In this paper, we present the moving least square radial reproducing polynomial (MLSRRP) meshless method as a generalization of the moving least square reproducing kernel particle method (MLSRKPM). The proposed method is established upon the extension of the MLSRKPM basis by using the radial basis functions. Some important properties of the shape functions are discussed. An interpolation error estimate is given to assess the convergence rate of the approximation. Also, for some class of time-dependent partial differential equations, the error estimate is acquired. The efficiency of the present method is examined by several test problems. The studied method is applied to the parabolic two-dimensional transient heat conduction equation and the hyperbolic two-dimensional sine-Gordon equation which are discretized by the aid of the meshless local Petrov–Galerkin (MLPG) method. [Copyright &y& Elsevier]

Published
2013
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results