Subdivision surfaces: a new paradigm for thin-shell finite-element analysis

Cirak, Fehmi; Ortiz, Michael; Schröder, Peter

doi:10.1002/(sici)1097-0207(20000430)47:12<2039::aid-nme872>3.0.co;2-1

Cited by 575 publications

(524 citation statements)

References 35 publications

(77 reference statements)

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“…For approximation of the deformation, subdivision surfaces based on Loop's scheme are used. This technique originates from the ÿeld of computational geometry and has recently been applied to thin shell analysis (Cirak et al, 2000;Cirak and Ortiz, 2001). In this method, a control mesh of triangular elements with only translational degrees-of-freedom is used to construct a smooth (H 2 ) surface.…”

Section: Numerical Simulations Of Carbon Nanotubesmentioning

confidence: 99%

An atomistic-based finite deformation membrane for single layer crystalline films

Arroyo

Belytschko

2002

Journal of the Mechanics and Physics of Solids

314

241

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A general methodology to develop hyper-elastic membrane models applicable to crystalline ÿlms one-atom thick is presented. In this method, an extension of the Born rule based on the exponential map is proposed. The exponential map accounts for the fact that the lattice vectors of the crystal lie along the chords of the curved membrane, and consequently a tangent map like the standard Born rule is inadequate. In order to obtain practical methods, the exponential map is locally approximated. The e ectiveness of our approach is demonstrated by numerical studies of carbon nanotubes. Deformed conÿgurations as well as equilibrium energies of atomistic simulations are compared with those provided by the continuum membrane resulting from this method discretized by ÿnite elements.

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Section: Numerical Simulations Of Carbon Nanotubesmentioning

confidence: 99%

An atomistic-based finite deformation membrane for single layer crystalline films

Arroyo

Belytschko

2002

Journal of the Mechanics and Physics of Solids

314

241

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“…Wavelet decomposition techniques are naturally hierarchical and multiresolutional, and provide a mathematical framework on which to form adaptive basis methods for finite-element elasticity. In fact, these methods are strongly tied to new subdivision methods for representing the dynamics of thin shells [5]. Note that the model reduction problem for traditional dynamic thin-shell models is more complicated than that for three-dimensional elasticity, due to the underlying geometry of the configuration space and the way essential boundary conditions are treated.…”

Section: Basis Selectionmentioning

confidence: 99%

“…Note that the model reduction problem for traditional dynamic thin-shell models is more complicated than that for three-dimensional elasticity, due to the underlying geometry of the configuration space and the way essential boundary conditions are treated. The subdivision thin-shell models are an exception to this rule, because their configuration spaces are Euclidean [5]. We do not give a discussion of error bounds in this work; this is an important but separate issue.…”

Section: Basis Selectionmentioning

confidence: 99%

Structure-preserving model reduction for mechanical systems

Lall¹,

Krysl²,

Marsden³

2003

Physica D: Nonlinear Phenomena

137

112

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This paper focuses on methods of constructing of reduced-order models of mechanical systems which preserve the Lagrangian structure of the original system. These methods may be used in combination with standard spatial decomposition methods, such as the Karhunen-Loève expansion, balancing, and wavelet decompositions. The model reduction procedure is implemented for three-dimensional finite-element models of elasticity, and we show that using the standard Newmark implicit integrator, significant savings are obtained in the computational costs of simulation. In particular simulation of the reduced model scales linearly in the number of degrees of freedom, and parallelizes well.

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“…Kagan et al [7] introduced a B-spline based FE approach that combines the geometrical design and the analysis systems into a common framework. Later, based on the subdivision of surface scheme Cirak et al [8] presented a different paradigm for describing and modelling of the thin shells geometries in the FEA framework. Based on the motivation of combining the long available CAD systems with the simulation approaches, Hughes et al [3] introduced a new numerical method, popularly known as Isogeometric analysis (IGA).…”

Section: Introduction State Of the Art In Igamentioning

confidence: 99%

IGA: A Simplified Introduction and Implementation Details for Finite Element Users

Agrawal

Gautam

2018

J. Inst. Eng. India Ser. C

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Isogeometric analysis (IGA) is a recently introduced technique that employs the Computer Aided Design (CAD) concept of Non-uniform Rational B-splines (NURBS) tool to bridge the substantial bottleneck between the CAD and finite element analysis (FEA) fields. The simplified transition of exact CAD models into the analysis alleviates the issues originating from geometrical discontinuities and thus, significantly reduces the design-toanalysis time in comparison to traditional FEA technique. Since its origination, the research in the field of IGA is accelerating and has been applied to various problems. However, the employment of CAD tools in the area of FEA invokes the need of adapting the existing implementation procedure for the framework of IGA. Also, the usage of IGA requires the in-depth knowledge of both the CAD and FEA fields. This can be overwhelming for a beginner in IGA. Hence, in this paper, a simplified introduction and implementation details for the incorporation of NURBS based IGA technique within the existing FEA code is presented. It is shown that with little modifications, the available standard code structure of FEA can be adapted for IGA. For the clear and concise explanation of these modifications, step-by-step implementation of a benchmark plate with a circular hole under the action of in-plane tension is included.

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Subdivision surfaces: a new paradigm for thin-shell finite-element analysis

Cited by 575 publications

References 35 publications

An atomistic-based finite deformation membrane for single layer crystalline films

An atomistic-based finite deformation membrane for single layer crystalline films

Structure-preserving model reduction for mechanical systems

IGA: A Simplified Introduction and Implementation Details for Finite Element Users

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