Upper and lower bounds for natural frequencies: A property of the smoothed finite element methods

Zhang, Zhi‐Qian; Liu, G. R.

doi:10.1002/nme.2889

Cited by 26 publications

(8 citation statements)

References 48 publications

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“…Some special stabilization techniques have been developed for NS-PIM models to solve dynamic problems [24,25]. We will not discuss this matter in detail in this book, and interested reader may refer to [24,25].…”

Section: )mentioning

confidence: 99%

“…It has been a dream of many to find a general systematical way to obtain an upper bound of the exact solution for practical problems, so that we can then bound the solution from both sides and our numerical solution can be properly "certified". It has been discovered [4,15,25,28,30] recently that the NS-PIM and the NS-RPIM with sufficient softening effects can provide an upper bound solution in energy norm for such problems. The theory on the softening effects and upper bounds has been presented in Chapter 5.…”

Section: Introductionmentioning

confidence: 99%

“…25 Comparison of convergence rates and accuracy of the numerical results in displacement norm obtained using linear FEM and two NS-RPIM models for the rectangular cantilever problem.…”

mentioning

confidence: 99%

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Node-based Smoothed Point Interpolation Method (NS-PIM)

Liu¹,

Zhang²

2013

Smoothed Point Interpolation Methods

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With the theory given in Chapters 2-5, we are now ready to present a particular S-PIM method: the node-based smoothed point interpolation method or NS-PIM. Because the NS-PIM is the first to be introduced, we shall present it as in detail as possible.The NS-PIM was originally proposed by Liu and Zhang et al. [1][2][3][4] using the generalized gradient smoothing technique [3] and the PIM shape functions [5-13] created using only a small number of local nodes in meshfree settings. The NS-PIM is a typical method created using generalized smoothed Galerkin (GS-Galerkin) weak form based on the normed G space theory that allows the use of discontinuous displacement functions. This chapter formulates the NS-PIM for mechanics problems for 2D and 3D solids. We focus first on 2D cases, because it is much easier to describe and comprehend. We will then extend the formulations to 3D cases by simply highlighting the major differences.The PIM shape function used in the NS-PIM was created using the T-schemes with nodes that can come from more than one cell, and hence are discontinuous in general. The NS-PIM was termed as linearly conforming point interpolation method (or LC-PIM) [1, 2, 4], because it is at least linearly conforming despite the use of discontinuous PIM shape functions. It was later termed as NS-PIM because the smoothing operation is node based. The name of NS-PIM is more convenient for distinguishing from other S-PIM models, many of which are also linearly conforming but use different types of smoothing domains for different properties and features. The NS-PIM was found possessing the following important features.

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Section: )mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Node-based Smoothed Point Interpolation Method (NS-PIM)

Liu¹,

Zhang²

2013

Smoothed Point Interpolation Methods

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“…Even when a unconditionally stable time-integration schemed is used to solve transient dynamic problems [17], unphysical numerical responses can appear. An α-FEM combining NS-FEM and standard FEM proposed in [28] can be used to stabilize NS-FEM by introducing the stiffening effects from the standard FEM stiffness matrix with a small α [26]. In this work, a stabilization procedure for NS-FEM is proposed based on the scheme in [29], by means of adding to the smoothed potential energy functional of NS-FEM a stabilization term which contains the square of the residual of the equilibrium equation.…”

Section: Introductionmentioning

confidence: 99%

“…Those tests were conducted regular size models where the overhead computational time is trivial. LC-PIM, SFEM, ES-FEM and NS-FEM have been successfully used to analyze linear and nonlinear solids [4][5][6][12][13][14][15][16][17][18]21,22], linear and nonlinear plates and shell structures [7,9,10,[23][24][25], free and forced vibration problems [17,26], piezoelectric structures [24], and so on.…”

Section: Introductionmentioning

confidence: 99%

Temporal stabilization of the node-based smoothed finite element method and solution bound of linear elastostatics and vibration problems

Zhang

Liu

2009

Comput Mech

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A stabilization procedure for curing temporal instability of node-based smoothed finite element method (NS-FEM) is proposed for dynamic problems using linear triangular element. A stabilization term is added into the smoothed potential energy functional of the original NS-FEM, consisting of squared-residual of equilibrium equation. A gradient smoothing operation on second order derivatives is applied to relax the requirement of shape function, so that the squared-residual can be evaluated using linear elements. Numerical examples demonstrate that stabilization parameter can "tune" NS-FEM from being "overly soft" to "overly stiff", so that eigenvalue solutions can be stabilized. Numerical tests provide an empirical value range of stabilization parameter, within which the stabilized NS-FEM can still produce upper bound solutions in strain energy to the exact solution of force-driven elastostatics problems, as well as lower bound natural frequencies for free vibration problems.

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A coupled immersed boundary‐lattice Boltzmann method with smoothed point interpolation method for fluid‐structure interaction problems

Wang

Cai

Zhang

et al. 2018

Numerical Methods in Fluids

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Summary The immersed boundary‐lattice Boltzmann method has been verified to be an effective tool for fluid‐structure interaction simulation associated with thin and flexible bodies. The newly developed smoothed point interpolation method (S‐PIM) can handle the largely deformable solids owing to its softened model stiffness and insensitivity to mesh distortion. In this work, a novel coupled method has been proposed by combining the immersed boundary‐lattice Boltzmann method with the S‐PIM for fluid‐structure interaction problems with large‐displacement solids. The proposed method preserves the simplicity of the lattice Boltzmann method for fluid solvers, utilizes the S‐PIM to establish the realistic constitutive laws for nonlinear solids, and avoids mesh regeneration based on the frame of the immersed boundary method. Both two‐ and three‐dimensional numerical examples have been carried out to validate the accuracy, convergence, and stability of the proposed method in consideration of comparative results with referenced solutions.

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Upper and lower bounds for natural frequencies: A property of the smoothed finite element methods

Cited by 26 publications

References 48 publications

Node-based Smoothed Point Interpolation Method (NS-PIM)

Node-based Smoothed Point Interpolation Method (NS-PIM)

Temporal stabilization of the node-based smoothed finite element method and solution bound of linear elastostatics and vibration problems

A coupled immersed boundary‐lattice Boltzmann method with smoothed point interpolation method for fluid‐structure interaction problems

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