Finite element analysis on implicitly defined domains: An accurate representation based on arbitrary parametric surfaces

Moumnassi, Mohammed; Belouettar, Salim; Béchet, Éric; Bordas, Stéphane; Quoirin, Didier; Potier‐Ferry, Michel

doi:10.1016/j.cma.2010.10.002

Cited by 86 publications

(71 citation statements)

References 67 publications

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“…The geometry in the design mesh are set as design variables. The lower bound is [45,15,15,15], and the upper bound is [70,70,70,70]. The monitoring points are chosen on GH.…”

Section: Connecting Rodmentioning

confidence: 99%

“…However, due to the separation of the geometry and the analysis mesh, the capture of the geometry boundary for domain integration is not a trivial task. Moës [44] proposed an XFEM-based method for complex microstructures, which was generalized by Moumnassi et al [45] to treat arbitrary CAD geometries implicitly, including corners and sharp edges. Isogeometric analysis A recent trend in shape optimization is isogeometric analysis (IGA) [46], which integrates the geometry and analysis representations.…”

Section: Introductionmentioning

confidence: 99%

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Implementation of regularized isogeometric boundary element methods for gradient‐based shape optimization in two‐dimensional linear elasticity

Lian

Kerfriden

Bordas

2016

Numerical Meth Engineering

114

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SUMMARYThe present work addresses shape sensitivity analysis and optimization in two-dimensional elasticity with a regularised isogeometric boundary element method (IGABEM). NURBS are used both for the geometry and the basis functions to discretize the regularised boundary integral equations. With the advantage of tight integration of design and analysis, the application of IGABEM in shape optimziation reduces the mesh generation/regeneration burden greatly. The work is distinct from the previous literatures in IGABEM shape optimization mainly in two aspects: 1) the structural and sensitivity analysis takes advantage of the regularized form of the boundary integral equations, eliminating completely the need of evaluating strongly singular integrals and jump terms and their shape derivatives, which were the main implementation difficulty in IGABEM, and 2) although based on the same CAD model, the mesh for structural and shape sensitivity analysis is separated from the geometrical design mesh, thus achieving a balance between less design variables for efficiency and refined mesh for accuracy. This technique was initially used in isogeometric finite element method and was incorporated into the present IGABEM implementation.

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“…The geometry in the design mesh are set as design variables. The lower bound is [45,15,15,15], and the upper bound is [70,70,70,70]. The monitoring points are chosen on GH.…”

Section: Connecting Rodmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Implementation of regularized isogeometric boundary element methods for gradient‐based shape optimization in two‐dimensional linear elasticity

Lian

Kerfriden

Bordas

2016

Numerical Meth Engineering

114

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show abstract

“…The level set method was originally devised for tracking a moving interface [32], and became a key ingredient of XFEM to implicitly describe complicated geometrical interfaces of microstructures without tracking them explicitly, such as cracks [33], holes and inclusions [20,34], dislocations [35] and biofilms [23,24], as well as fluid-structure interfaces [36].…”

Section: Level Set Description Of the Interfacesmentioning

confidence: 99%

A hybrid smoothed extended finite element/level set method for modeling equilibrium shapes of nano-inhomogeneities

Zhao

Bordas

2013

Comput Mech

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Interfacial energy plays an important role in equilibrium morphologies of nanosized microstructures of solid materials due to the high interface-to-volume ratio, and can no longer be neglected as it does in conventional mechanics analysis. The present work develops an effective numerical approach by means of a hybrid smoothed extended finite element/level set method to model nanoscale inhomogeneities with interfacial energy effect, in which the finite element mesh can be completely independent of the interface geometry. The Gurtin-Murdoch surface elasticity model is used to account for the interface stress effect and the Wachspress interpolants are used for the first time to construct the shape functions in the smoothed extended finite element method. Selected numerical results are presented to study the accuracy and efficiency of the proposed method as well as the equilibrium shapes of misfit particles in elastic solids. The presented results compare very well with those obtained from theoretical solutions and experimental observations, and the computational efficiency of the method is shown to be superior to that of its most advanced competitor.Keywords: Smoothed extended finite element method; Level set method; Wachspress shape function; Interface excess energy; Equilibrium shape. IntroductionRecent advances in nanotechnology exacerbate the need for computational tools that are capable of capturing the effects of interfaces, which play an important role in nanostructured materials due to a characteristically high interface-to-volume ratio. Although atomic level computational tools such as molecular dynamic (MD) and first principle calculations are able to simulate interface effects, these methods are computationally intensive, thus their applications are usually limited to nano-scale samples and nano-second time durations. Many engineering problems, however, occur at much larger spatial and temporal scales. For example, simulating the formation and morphological evolution of precipitates in superalloys involves length scales ranging from several nanometers to tens of micrometers, and the physical processes last up to hours in time. In these cases, it is necessary to use a continuum level model that can capture the interfacial effects of particles at different length and time scales.

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“…Integration: As the mesh does not conform to the geometry of the domain it is necessary to use special procedures to evaluate integrals. Different approaches have been considered in the bibliography to ensure that the integration in each element is only extended to the exact part of the volume (area in 2D), see for example references [3,4,5,6]. In general terms the solution to this problem consists of using two different meshes, one for interpolation and another for integration.…”

Section: Introductionmentioning

confidence: 99%

Stabilized method of imposing Dirichlet boundary conditions using a recovered stress field

Tur

Albelda

Marco

et al. 2015

Computer Methods in Applied Mechanics and Engineering

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-mail: manuel.tur@mcm.upv.es,jalbelda@mcm.upv.es,onmaral@upvnet.upv.es,jjrodena@mcm.upv.es Abstract This paper proposes a new formulation to impose Dirichlet boundary conditions on immersed boundary Cartesian Finite Element meshes. The method uses a recovered stress field calculated by Superconvergent Patch Recovery to stabilize the Lagrange multiplier formulation of the problem. The optimal convergence of the method and the convergence of the proposed iterative procedure are demonstrated. The proposed method is also suitable for problems with non-linear material behavior. Some numerical examples are included to confirm the theoretical results.

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Finite element analysis on implicitly defined domains: An accurate representation based on arbitrary parametric surfaces

Cited by 86 publications

References 67 publications

Implementation of regularized isogeometric boundary element methods for gradient‐based shape optimization in two‐dimensional linear elasticity

Implementation of regularized isogeometric boundary element methods for gradient‐based shape optimization in two‐dimensional linear elasticity

A hybrid smoothed extended finite element/level set method for modeling equilibrium shapes of nano-inhomogeneities

Stabilized method of imposing Dirichlet boundary conditions using a recovered stress field

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