Generalized-strain mesh-free formulation

Last updated October 22, 2020

The generalized-strain mesh-free (GSMF) formulation is a local meshfree method in the field of numerical analysis, completely integration free, working as a weighted-residual weak-form collocation. This method was first presented by Oliveira and Portela (2016),^[1] in order to further improve the computational efficiency of meshfree methods in numerical analysis. Local meshfree methods are derived through a weighted-residual formulation which leads to a local weak form that is the well known work theorem of the theory of structures. In an arbitrary local region, the work theorem establishes an energy relationship between a statically-admissible stress field and an independent kinematically-admissible strain field. Based on the independence of these two fields, this formulation results in a local form of the work theorem that is reduced to regular boundary terms only, integration-free and free of volumetric locking.

Advantages over finite element methods are that GSMF doesn't rely on a grid, and is more precise and faster when solving bi-dimensional problems. When compared to other meshless methods, such as rigid-body displacement mesh-free (RBDMF) formulation, the element-free Galerkin (EFG)^[2] and the meshless local Petrov-Galerkin finite volume method (MLPG FVM);^[3] GSMF proved to be superior not only regarding the computational efficiency, but also regarding the accuracy.^[4]

The moving least squares (MLS) approximation of the elastic field is used on this local meshless formulation.

Formulation

In the local form of the work theorem, equation:

\int _{\Gamma _{Q}}\mathbf {t} ^{T}\mathbf {u} ^{*}d\Gamma +\int _{\Omega _{Q}}\mathbf {b} ^{T}\mathbf {u} ^{*}d\Omega =\int _{\Omega _{Q}}{\boldsymbol {\sigma }}^{T}{\boldsymbol {\varepsilon }}^{*}d\Omega .

The displacement field $\mathbf {u} ^{*}$ , was assumed as a continuous function leading to a regular integrable function that is the kinematically-admissible strain field ${\boldsymbol {\varepsilon }}^{*}$ . However, this continuity assumption on $\mathbf {u} ^{*}$ , enforced in the local form of the work theorem, is not absolutely required but can be relaxed by convenience, provided ${\boldsymbol {\varepsilon }}^{*}$ can be useful as a generalized function, in the sense of the theory of distributions, see Gelfand and Shilov.^[5] Hence, this formulation considers that the displacement field $\mathbf {u} ^{*}$ , is a piecewise continuous function, defined in terms of the Heaviside step function and therefore the corresponding strain field ${\boldsymbol {\varepsilon }}^{*}$ , is a generalized function defined in terms of the Dirac delta function.

For the sake of the simplicity, in dealing with Heaviside and Dirac delta functions in a two-dimensional coordinate space, consider a scalar function $d$ , defined as:

d=\lVert \ \mathbf {x} -\mathbf {x} _{Q}\rVert

which represents the absolute-value function of the distance between a field point $\mathbf {x}$ and a particular reference point $\mathbf {x} _{Q}$ , in the local domain $\Omega _{Q}\cup \Gamma _{Q}$ assigned to the field node $Q$ . Therefore, this definition always assumes $d=d(\mathbf {x} ,\mathbf {x} _{Q})\geq 0$ , as a positive or null value, in this case whenever $\mathbf {x}$ and $\mathbf {x} _{Q}$ are coincident points.

For a scalar coordinate $d\supset d(\mathbf {x} ,\mathbf {x} _{Q})$ , the Heaviside step function can be defined as

H(d)=1\,\,\,\,\,\,if\,\,\,\,\,d\leq 0\,\,\,\,\,\,(d=0\,\,\,for\,\,\,\mathbf {x} \equiv \mathbf {x} _{Q})

H(d)=0\,\,\,\,\,\,if\,\,\,\,\,d>0\,\,\,\,\,\,(\mathbf {x} \neq \mathbf {x} _{Q})

in which the discontinuity is assumed at $\mathbf {x} _{Q}$ and consequently, the Dirac delta function is defined with the following properties

\delta (d)=H'(d)=\infty \,\,\,\,\,\,if\,\,\,\,\,d=0\,\,\,that\,\,is\,\,\,\mathbf {x} \equiv \mathbf {x} _{Q}

\delta (d)=H'(d)=0\,\,\,\,\,\,if\,\,\,\,\,d\neq 0\,\,\,(d>0\,\,\,for\,\,\,\mathbf {x} \neq \mathbf {x} _{Q})

and

\int \limits _{-\infty }^{+\infty }\delta (d)\,dd=1

in which $H'(d)$ represents the distributional derivative of $H(d)$ . Note that the derivative of $H(d)$ , with respect to the coordinate $x_{i}$ , can be defined as

H(d)_{,i}=H'(d)\,\,d_{,i}=\delta (d)\,\,d_{,i}=\delta (d)\,\,n_{i}

Since the result of this equation is not affected by any particular value of the constant $n_{i}$ , this constant will be conveniently redefined later on.

Consider that $d_{l}$ , $d_{j}$ and $d_{k}$ represent the distance function $d$ , for corresponding collocation points $\mathbf {x} _{l}$ , $\mathbf {x} _{j}$ and $\mathbf {x} _{k}$ . The displacement field $\mathbf {u} ^{*}(\mathbf {x} )$ , can be conveniently defined as

\mathbf {u} ^{*}(\mathbf {x} )={\Bigg [}{\frac {L_{i}}{n_{i}}}\,\sum _{l=1}^{n_{i}}H(d_{l})+{\frac {L_{t}}{n_{t}}}\,\sum _{j=1}^{n_{t}}H(d_{j})+{\frac {S}{n_{\Omega }}}\,\sum _{k=1}^{n_{\Omega }}H(d_{k}){\Bigg ]}\mathbf {e}

in which $\mathbf {e} =[1\,\,\,\,1]^{T}$ represents the metric of the orthogonal directions and $n_{i}$ , $n_{t}$ and $n_{\Omega }$ represent the number of collocation points, respectively on the local interior boundary $\Gamma _{Qi}=\Gamma _{Q}-\Gamma _{Qt}-\Gamma _{Qu}$ with length $L_{i}$ , on the local static boundary $\Gamma _{Qt}$ with length $L_{t}$ and in the local domain $\Omega _{Q}$ with area $S$ . This assumed displacement field $\mathbf {u} ^{*}(\mathbf {x} )$ , a discrete rigid-body unit displacement defined at collocation points. The strain field ${\boldsymbol {\varepsilon }}^{*}(\mathbf {x} )$ , is given by

{\boldsymbol {\varepsilon }}^{*}(\mathbf {x} )=\mathbf {L} \,\mathbf {u} ^{*}(\mathbf {x} )={\Bigg [}{\frac {L_{i}}{n_{i}}}\,\sum _{l=1}^{n_{i}}\mathbf {L} \,H(d_{l})+{\frac {L_{t}}{n_{t}}}\,\sum _{j=1}^{n_{t}}\mathbf {L} \,H(d_{j})+{\frac {S}{n_{\Omega }}}\,\sum _{k=1}^{n_{\Omega }}\mathbf {L} \,H(d_{k}){\Bigg ]}\mathbf {e} ={\Bigg [}{\frac {L_{i}}{n_{i}}}\,\sum _{l=1}^{n_{i}}\,\delta (d_{l})\,\mathbf {n} ^{T}\,+{\frac {L_{t}}{n_{t}}}\,\sum _{j=1}^{n_{t}}\,\delta (d_{j})\,\mathbf {n} ^{T}\,+{\frac {S}{n_{\Omega }}}\,\sum _{k=1}^{n_{\Omega }}\,\delta (d_{k})\,\mathbf {n} ^{T}{\Bigg ]}\mathbf {e}

Having defined the displacement and the strain components of the kinematically-admissible field, the local work theorem can be written as

{\frac {L_{i}}{n_{i}}}\sum _{l=1}^{n_{i}}\,\int \limits _{\Gamma _{Q}-\Gamma _{Qt}}\!\!\!\!\!\!\mathbf {t} ^{T}H(d_{l})\mathbf {e} \,d\Gamma +{\frac {L_{t}}{n_{t}}}\sum _{j=1}^{n_{t}}\,\int \limits _{\Gamma _{Qt}}\!{\overline {\mathbf {t} }}^{T}H(d_{j})\mathbf {e} \,d\Gamma +{\frac {S}{n_{\Omega }}}\sum _{k=1}^{n_{\Omega }}\,\int \limits _{\Omega _{Q}}\mathbf {b} ^{T}H(d_{k})\mathbf {e} \,d\Omega ={\frac {S}{n_{\Omega }}}\sum _{k=1}^{n_{\Omega }}\,\int \limits _{\Omega _{Q}}{\boldsymbol {\sigma }}^{T}\delta (d_{k})\,\mathbf {n} ^{T}\mathbf {e} \,d\Omega .

Taking into account the properties of the Heaviside step function and Dirac delta function, this equation simply leads to

{\frac {L_{i}}{n_{i}}}\sum _{l=1}^{n_{i}}\,\mathbf {t} _{\mathbf {x} _{l}}=-\,{\frac {L_{t}}{n_{t}}}\sum _{j=1}^{n_{t}}\,{\overline {\mathbf {t} }}_{\mathbf {x} _{j}}-\,{\frac {S}{n_{\Omega }}}\sum _{k=1}^{n_{\Omega }}\,\mathbf {b} _{\mathbf {x} _{k}}

Discretization of this equations can be carried out with the MLS approximation, for the local domain $\Omega _{Q}$ , in terms of the nodal unknowns ${\hat {\mathbf {u} }}$ , thus leading to the system of linear algebraic equations that can be written as

{\frac {L_{i}}{n_{i}}}\sum _{l=1}^{n_{i}}\,\mathbf {n} _{\mathbf {x} _{l}}\mathbf {D} \mathbf {B} _{\mathbf {x} _{l}}{\hat {\mathbf {u} }}=-\,{\frac {L_{t}}{n_{t}}}\sum _{j=1}^{n_{t}}\,{\overline {\mathbf {t} }}_{\mathbf {x} _{j}}-\,{\frac {S}{n_{\Omega }}}\sum _{k=1}^{n_{\Omega }}\,\mathbf {b} _{\mathbf {x} _{k}}

or simply

\mathbf {K} _{Q}\,{\hat {\mathbf {u} }}=\mathbf {F} _{Q}

This formulation states the equilibrium of tractions and body forces, pointwisely defined at collocation points, obviously, it is the pointwise version of the Euler-Cauchy stress principle. This is the equation used in the Generalized-Strain Mesh-Free (GSMF) formulation which, therefore, is free of integration. Since the work theorem is a weighted-residual weak form, it can be easily seen that this integration-free formulation is nothing else other than a weighted-residual weak-form collocation. The weighted-residual weak-form collocation readily overcomes the well-known difficulties posed by the weighted-residual strong-form collocation,^[6] regarding accuracy and stability of the solution.

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References

↑ Oliveira, T. and A. Portela (2016). "Weak-Form Collocation – a Local Meshless Method in Linear Elasticity". Engineering Analysis with Boundary Elements.
↑ Belytschko, T., Y. Y. Lu, and L. Gu (1994). "Element-free Galerkin methods". International Journal for Numerical Methods in Engineering. 37.2, pp. 229–256.
↑ Atluri, S.N., Z.D. Han, and A.M. Rajendran (2004). "A New Implementation of the Meshless Finite Volume Method Through the MLPG Mixed Approach". CMES: Computer Modeling in Engineering and Sciences. 6, pp. 491–513.
↑ Oliveira, T. and A. Portela (2016). "Comparative study of the weak-form collocation meshless formulation and other meshless methods". Proceedings of the XXXVII Iberian Latin-American Congress on Computational Methods in Engineering. ABMEC, Brazil
↑ Gelfand, I.M., Shilov, G.E. (1964). Generalized Functions. Volume I, Academic Press, New York.
↑ Kansa, E.J.,(1990) "Multiquadrics: A Scattered Data Approximation Scheme with Applications to Computational Fluid Dynamics", Computers and Mathematics with Applications, 19(8-9), 127--145.

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[1] Oliveira, T. and A. Portela (2016). "Weak-Form Collocation – a Local Meshless Method in Linear Elasticity". Engineering Analysis with Boundary Elements.

[2] Belytschko, T., Y. Y. Lu, and L. Gu (1994). "Element-free Galerkin methods". International Journal for Numerical Methods in Engineering. 37.2, pp. 229–256.

[3] Atluri, S.N., Z.D. Han, and A.M. Rajendran (2004). "A New Implementation of the Meshless Finite Volume Method Through the MLPG Mixed Approach". CMES: Computer Modeling in Engineering and Sciences. 6, pp. 491–513.

[4] Oliveira, T. and A. Portela (2016). "Comparative study of the weak-form collocation meshless formulation and other meshless methods". Proceedings of the XXXVII Iberian Latin-American Congress on Computational Methods in Engineering. ABMEC, Brazil

[5] Gelfand, I.M., Shilov, G.E. (1964). Generalized Functions. Volume I, Academic Press, New York.

[6] Kansa, E.J.,(1990) "Multiquadrics: A Scattered Data Approximation Scheme with Applications to Computational Fluid Dynamics", Computers and Mathematics with Applications, 19(8-9), 127--145.

Generalized-strain mesh-free formulation

Contents

Formulation

See also

Related Research Articles

References