Niu Xiang-jun. The Generalized Galerkin’s Equations of the Finite Element, the Boundary Variational Equations and the Boundary Integral Equations[J]. Applied Mathematics and Mechanics, 1983, 4(2): 247-254.
Citation:
Niu Xiang-jun. The Generalized Galerkin’s Equations of the Finite Element, the Boundary Variational Equations and the Boundary Integral Equations[J]. Applied Mathematics and Mechanics, 1983, 4(2): 247-254.
Niu Xiang-jun. The Generalized Galerkin’s Equations of the Finite Element, the Boundary Variational Equations and the Boundary Integral Equations[J]. Applied Mathematics and Mechanics, 1983, 4(2): 247-254.
Citation:
Niu Xiang-jun. The Generalized Galerkin’s Equations of the Finite Element, the Boundary Variational Equations and the Boundary Integral Equations[J]. Applied Mathematics and Mechanics, 1983, 4(2): 247-254.
Based on [1], we have further applied the variational principle of the variable boundary to investigate the discretization analysis of the solid system and derived the generalized Ga-lerkin's equations of the finite element, the boundary variational equations and the boundary integral equations.These e-quations indicate that the unknown functions of the solid system must satisfy the conditions in the element Sa or on theboundaries Γa.These equations are applied to establishing the discretization equations in order to obtain the numerical solution of the unknown functions. At a time these equations can be used as the basis for the simplified calculation in various corresponding cases.In this paper, the results of boundary integral equations show that the calculation Γa of integration is not accurate along the surface of interior element Sa by J-integral suggested by Rice [2].
Rice,J.R.,A path independent integral and the approximate analysis of strain concentration by notches and crack,Journal of Applied Mechanics,35,2 June(1968).
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