Analysis of the singular function boundary integral method for a biharmonic problem with one boundary singularity
Copyright policy )Analysis of the singular function boundary integral method for a biharmonic problem with one boundary singularity
AbstractIn this article, we analyze the singular function boundary integral method (SFBIM) for a two‐dimensional biharmonic problem with one boundary singularity, as a model for the Newtonian stick‐slip flow problem. In the SFBIM, the leading terms of the local asymptotic solution expansion near the singular point are used to approximate the solution, and the Dirichlet boundary conditions are weakly enforced by means of Lagrange multiplier functions. By means of Green's theorem, the resulting discretized equations are posed and solved on the boundary of the domain, away from the point where the singularity arises. We analyze the convergence of the method and prove that the coefficients in the local asymptotic expansion, also referred to as stress intensity factors, are approximated at an exponential rate as the number of the employed expansion terms is increased. Our theoretical results are illustrated through a numerical experiment. © 2011 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq, 2011
- University of Cyprus Cyprus
Lagrange multipliers, Asymptotic analysis, Stress intensity, Discretized equations, Leading terms, Singular function boundary integral methods, boundary approximation methods, Boundary singularities, stress intensity factors, Slip forming, Numerical experiments, Boundary conditions, Dirichlet boundary condition, Approximation theory, Lagrange, Theoretical result, Exponential rates, Multiplier functions, Local asymptotic, Flow problems, Singular points, biharmonic problem, Newtonians, Green's theorem
Lagrange multipliers, Asymptotic analysis, Stress intensity, Discretized equations, Leading terms, Singular function boundary integral methods, boundary approximation methods, Boundary singularities, stress intensity factors, Slip forming, Numerical experiments, Boundary conditions, Dirichlet boundary condition, Approximation theory, Lagrange, Theoretical result, Exponential rates, Multiplier functions, Local asymptotic, Flow problems, Singular points, biharmonic problem, Newtonians, Green's theorem
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