TY  - EJOU
AU  - Han, Z. D.  
AU  - Atluri, S. N.  

TI  - On the (Meshless Local Petrov-Galerkin) MLPG-Eshelby Method in Computational Finite Deformation Solid Mechanics - Part II
T2  - Computer Modeling in Engineering \& Sciences

PY  - 2014
VL  - 97
IS  - 3
SN  - 1526-1506

AB  - This paper presents a new method for the computational mechanics of large strain deformations of solids, as a fundamental departure from the currently popular finite element methods (FEM). The currently widely popular primal FEM: (1) uses element-based interpolations for displacements as the trial functions, and element-based interpolations of displacement-like quantities as the test functions; (2) uses the same type and class of trial & test functions, leading to a Galerkin approach; (3) uses the trial and test functions which are most often continuous at the inter-element boundaries; (4) leads to sparsely populated symmetric tangent stiffness matrices; (5) computes piecewise-linear predictor solutions based on the global weak-forms of the Newtonian Momentum Balance Laws for a Lagrangean Stress tensor, such as the symmetric Second Piola-Kirchhoff Stress tensor <b>S </b> [≡ <i>J</i><b>F<sup>−1</sup>·σ·F</b><sup><i>−t</i></sup>, where <b>σ</b> is the Cauchy Stress tensor and <b>F</b> the deformation gradient] in the initial or any other known reference configuration; and (6) computes a corrector solution, using Newton-Raphson or other Jacobian-inversion-free iterations, based on the global weak-forms of the Newtonian Momentum Balance Laws for the symmetric Cauchy Stress tensor <b>σ</b> in the current configuration. In a radical departure, the present approach blends the Energy-Conservation Laws of Noether and Eshelby, and the Meshless Local Petrov Galerkin (MLPG) Methods of Atluri, and is designated herein as the MLPG-Eshelby Method. In the MLPG-Eshelby Method, we: (1) use meshless node-based functions δ<b>X</b>, for configurational changes of the undeformed configuration, as the trial functions; (2) meshless node-based functions δ<b>x</b>, for configurational changes of the deformed configuration, as the test functions; (3) the trial functions δ<b>X</b> and the test functions δ<b>x</b> are necessarily different and belong to different classes of functions, thus naturally leading to a Petrov-Galerkin approach; (4) leads to sparsely populated unsymmetric tangent stiffness matrices; (5) the trial functions δ<b>X</b>, as well as the test functions δ<b>x</b>, may either be continuous or be discontinuous in their respective configurations; (6) generate piecewise-linear predictor solutions based on the local weak-forms of the Noether/Eshelby Energy Conservation Laws for the Lagrangean unsymmetric Eshelby Stress tensor <b>T</b> in the undeformed configuration [<b>T</b> = <b>WI − P·F</b>; where <b>P</b> = <i>J</i><b>F<sup>-1</sup>·σ</b> is the first Piola-Kirchhoff Stress tensor, and <i>W</i> is the stress-work density per unit initial volume of the solid] and (7) generate corrector solutions, based on Newton-Raphson or Jacobian-inversion-free iterations, using the local weak-forms of the Noether/Eshelby Energy Conservation Laws in the current configuration, for a newly introduced Eulerean symmetric Stress tensor <b>S<sup style="margin-left:-6px">˜ </sup></b>[which is the counter part of <b>T</b>] in the current configuration [<b>S<sup style="margin-left:-6px">˜ </sup></b> = (<i>W/J</i>)<b>I − σ</b>, often called by chemists as the Chemical Potential Tensor]. It is shown in the present paper that the present MLPG-Eshelby Method, based on the meshless local weak-forms of the Noether/Eshelby Energy Conservation Laws, converges much faster and leads to much better accuracies than the currently popular FEM based on the global weak-forms of the Newtonian Momentum Balance Laws. The present paper is limited to hyperelasticity, while large strains of inelastic solids will be considered in our forthcoming papers.
KW  - 

DO  - 10.3970/cmes.2014.097.199