Jan Novák scite author profile

a b s t r a c tIn this short note, we present a new technique to accelerate the convergence of a FFT-based solver for numerical homogenization of complex periodic media proposed by Moulinec and Suquet [1]. The approach proceeds from discretization of the governing integral equation by the trigonometric collocation method due to Vainikko [2], to give a linear system which can be efficiently solved by conjugate gradient methods. Computational experiments confirm robustness of the algorithm with respect to its internal parameters and demonstrate significant increase of the convergence rate for problems with high-contrast coefficients at a low overhead per iteration.

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Compressing random microstructures via stochastic Wang tilings

Novák

Kučerová²,

Zeman³

2012

Phys. Rev. E

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This Rapid Communication presents a stochastic Wang tiling-based technique to compress or reconstruct disordered microstructures on the basis of given spatial statistics. Unlike the existing approaches based on a single unit cell, it utilizes a finite set of tiles assembled by a stochastic tiling algorithm, thereby allowing to accurately reproduce long-range orientation orders in a computationally efficient manner. Although the basic features of the method are demonstrated for a two-dimensional particulate suspension, the present framework is fully extensible to generic multidimensional media.

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Aperiodic compression and reconstruction of real-world material systems based on Wang tiles

2014

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The paper presents a concept to compress and synthesize complex material morphologies that is based on Wang tilings. Specifically, a microstructure is stored in a set of Wang tiles and its reconstruction is performed by means of a stochastic tiling algorithm. A substantial part of the study is devoted to the setup of optimal parameters of the automatic tile design by means of parametric studies with statistical descriptors at heart. The performance of the method is demonstrated on four two-dimensional two-phase target systems, monodisperse media with hard and soft disks, sandstone, and high porosity metallic foam.

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On the Cartesian Product of Two Compact Spaces

Novák

1953

Fund. Math.

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A jigsaw puzzle framework for homogenization of high porosity foams

Doškář¹,

Novák²

2016

Computers & Structures

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An approach to homogenization of high porosity metallic foams is explored. The emphasis is on the Alporas R foam and its representation by means of two-dimensional wire-frame models. The guaranteed upper and lower bounds on the effective stiffness coefficients are derived by the first-order homogenization with the uniform and minimal kinematic boundary conditions at heart. This is combined with the method of Wang tilings to generate sufficiently large material samples along with their finite element discretization. The obtained results are compared to experimental and numerical data available in literature and the suitability of the two-dimensional setting itself is discussed.

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Jan Novák

Accelerating a FFT-based solver for numerical homogenization of periodic media by conjugate gradients

Compressing random microstructures via stochastic Wang tilings

Aperiodic compression and reconstruction of real-world material systems based on Wang tiles

On the Cartesian Product of Two Compact Spaces

A jigsaw puzzle framework for homogenization of high porosity foams

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