Finite element recovery techniques for local quantities of linear problems using fundamental solutions

Bathe

2005

Computers & Structures

220

161

In this paper we review the basic concepts to obtain a posteriori error estimates for the finite element solution of an elliptic linear model problem. We give the basic ideas to establish global error estimates for the energy norm as well as goal-oriented error estimates. While we show how these error estimation techniques are employed for our simple model problem, the emphasis of the paper is on assessing whether these procedures are ready for use in practical linear finite element analysis. We conclude that the actually practical error estimation techniques do not provide mathematically proven bounds on the error and need to be used with care. The more accurate estimation procedures also do not provide proven bounds that, in general, can be computed efficiently. We also briefly comment upon the state of error estimations in nonlinear and transient analyses and when mixed methods are used.

Section: The Greenõs Function Decomposition Methodsmentioning

confidence: 99%

Section: The Greenõs Function Decomposition Methodsmentioning

confidence: 99%

A posteriori error estimation techniques in practical finite element analysis

Bathe

2005

Computers & Structures

220

161

“…where the notationG ij 1;h ðy; xÞ indicates a similar decomposition as in (38), see [18] for details.…”

Section: A New Strategy For Computing the Dual Solutionmentioning

confidence: 99%

Pointwise error estimation and adaptivity for the finite element method using fundamental solutions

Hartmann

2005

Comput Mech

Self Cite

In this paper, we present a goal-oriented a posteriori error estimation technique for the pointwise error of finite element approximations using fundamental solutions. The approach is based on an integral representation of the pointwise quantity of interest using the corresponding Green's function, which is decomposed into an unknown regular part and a fundamental solution. Since only the regular part must be approximated with finite elements, very accurate results are obtained. The approach also allows the derivation of error bounds for the pointwise quantity, which are expressed in terms of the primal problem and the regular part problem. The presented technique is applied to linear elastic test problems in two-dimensions, but it can be applied to any linear problem for which fundamental solutions exist.

“…and F h (.) indicates that we are using the approximated geometry defined by (21) to compute the bilinear and linear forms. We denote with h the 3D approximate geometry, which in general is different from the actual reference domain .…”

Section: Finite Element Discretizationmentioning

confidence: 99%

“…A posteriori error estimation procedures have become an important tool for assessing the reliability and accuracy of finite element computations [7,17]. These techniques have been extended to the so-called goal-oriented error estimations where the error is estimated in some output data of engineering interest [7][8][9][18][19][20][21][22][23][24]. The essential tool for estimating the error in such a quantity of interest is the influence function which filters out the necessary information for an accurate error estimate.…”

Section: Goal-oriented Error Estimationmentioning

confidence: 99%

Influence functions and goal‐oriented error estimation for finite element analysis of shell structures

Numerical Meth Engineering

Bathe

2005

SUMMARYIn this paper, we first present a consistent procedure to establish influence functions for the finite element analysis of shell structures, where the influence function can be for any linear quantity of engineering interest. We then design some goal-oriented error measures that take into account the cancellation effect of errors over the domain to overcome the issue of over-estimation. These error measures include the error due to the approximation in the geometry of the shell structure. In the calculation of the influence functions we also consider the asymptotic behaviour of shells as the thickness approaches zero. Although our procedures are general and can be applied to any shell formulation, we focus on MITC finite element shell discretizations. In our numerical results, influence functions are shown for some shell test problems, and the proposed goal-oriented error estimation procedure shows good effectivity indices.